diff --git a/spiders/cordis_spider.py b/spiders/cordis_spider.py index 68a0a8a..101df7d 100644 --- a/spiders/cordis_spider.py +++ b/spiders/cordis_spider.py @@ -17,7 +17,7 @@ class CordisSpider(scrapy.Spider): def parse(self, response): # Misconfiguration to check - eu in response.xpath not needed #for eu in response.xpath('//*[@id="container-pack"]'): - if response.xpath('//*[@id="ica:content"][contains(.,"water") and contains(.,"drinking water")]'): + if response.xpath('//*[@id="ica:content"][contains(.,"water") or contains(.,"drinking") or contains(.,"nitrates")]'): item = CordisItem() item['Meta'] = response.xpath('/html/head/meta[23]').extract() item['Project_ACR'] = response.xpath('//*[@id="dynamiccontent"]/div[1]/h1/text()').extract() diff --git a/spiders/cordis_spider.pyc b/spiders/cordis_spider.pyc index faa26df..be8001f 100644 Binary files a/spiders/cordis_spider.pyc and b/spiders/cordis_spider.pyc differ diff --git a/spiders/dataset-textgenrnn.xml b/spiders/dataset-textgenrnn.xml new file mode 100644 index 0000000..44abe06 --- /dev/null +++ b/spiders/dataset-textgenrnn.xml @@ -0,0 +1,508 @@ + + +Over 1 billion people suffer from the effects of water scarcity with the vast majority being poor residents of developing countries. Desalting seawater is an excellent potential solution but traditional reverse osmosis (R/O) desalination systems require a connection to a strong electrical grid. However, because developing countries typically lack sufficient electrical grid capacity and cannot afford the capital or time required to build and deploy traditional R/O systems, RML is proposing an innovative solution to this problem - the world’s first wave-driven desalination system (called Wave2O™) that can be deployed quickly, operate completely “off-grid” and supply large quantities of fresh water at competitive cost. +This project aims to develop and commercialise VERNE: A non-destructive testing (NDT) system that has the potential to revolutionise underwater inspection of tubular structures by achieving far greater inspection speed and precision compared to existing systems. As the majority of offshore Oil and Gas extraction assets have already exceeded their design lifetime, the need for decommissioning and/or substituting these assets becomes increasingly pressing. However, associated costs are enormous and it will cost nearly €20 billion over the next 10 years to remove around 80 platforms and their associated infrastructure. As asset owners strive to prolong asset lifetime while and minimise risk of catastrophic accidents, the greatest challenge is the inspection and maintenance of subsea structures like jacket foundations and pipelines. In underwater environments the high pressure, seawater and marine life (biofouling) obstruct maintenance operations and accelerate structure degradation. Subsea inspections are currently performed using Remotely Operated Vehicles carrying a payload of cameras, sensors and other equipment. VERNE will dramatically improve on their performance by combining ultrasound and acoustic testing that enable (i) the rapid scanning and defect mapping in a 100m radius around the inspection point and (ii) detailed and precise characterisation once defects are identified. VERNE’s technologies enable inspection of both external and internal surface of structures (e.g. pipelines) without the need to remove anti-corrosion coatings and/or biofouling. As such, VERNE will lead to significant cost savings for asset owners while providing a key competitive advantage to subsea service providers. As such, project partners Dacon and Nardoni anticipate a cumulative turnover of €31.468 million and profits of €19.3 million by Year 5 with a breakeven over the total budget in Year 2 and a ROI rate of 13:1 on EC’s grant. +UTB Envirotec Zrt, is one of the Central European market leaders in engineering services for wastewater and organic waste treatment. In the past few years, we have developed a technology for sustainable valorisation of sewage sludge. The treatment of this sludge represents one of the biggest problems for small and medium sized wastewater treatment plants (WWTP) in Europe. In our process, called reNEW, the sewage sludge is biologically transformed into volatile fatty acids (VFA) and valuable nutrients (NPK), which are recovered. These products represent important market value: VFA as raw material for eco labelled cleaning agents, and NPK as fertilizer. With the aim of exploitation of the reNEW technology, we formed a spin-off company, Renew Technologies Ltd (RNT) in the UK. Our final aim is to roll-out the technology and widely implement it all over Europe, enabling the growth of our companies. We aim to realise the reNEW project in cooperation of the two companies: RNT being the technology owner and responsible for commercial exploitation, while UTB being the technology provider (design, building and implementation of plants). This initiative has received funding in the Horizon 2020 SME Instrument Phase 1, project number: 728932, duration: 01/07/2016-31/12/2016. We have successfully completed the feasibility study. We verified the technological feasibility as well as the economic viability of the project and further improved our business concept. We demonstrated the efficiency and economic value of the two products, VFA and NPK, respectively and made a scale-up design of our pilot operating currently at our premises (TRL=6). We have improved the proposal and discussed it with our clients, technical partners, and the Enterprise Europe Network (EEN). These discussions and the results of the feasibility assessment have reassured us regarding its merit. +In 2016, over 1.2 billion people in the world (16% of the global population) still did not have access to electricity. As the majority of these people are located in remote and rural areas of the world, where conventional power grid extensions are not possible, off-grid energy solutions are required for providing electricity to these areas. Even though such solutions exist today, the options available are painfully limited and costly, whether it be the polluting diesel generators or the solar panels, intermittent energy source requiring complex parks of batteries for energy storage. +The OC-Tech project devises an innovative catamaran-vessel able to: [A] recover hydrocarbon spills, [B] deal with algal blooms and jellyfish infestations; [C] collect flotsam and jetsam. The main benefits of OC-Tech are: [1] Polyvalence: collecting all pollution episodes and has also a large deck for transporting personnel (12 p.) and loads (1.500kg/m2); [2] Multi-Purpose (Cleaning+Working vessel). OC-Tech goes beyond its core cleaning activity (recurring only purpose at other cleaning assets) and can carry up to 12 people thus operating as a conveyor for other operations: ship chandlers; beacons, buoys, barriers carrier; off-shore assistance; Fire protection assistance, cleaning+repair of other ships; Prospecting, diving platform, works; port services and multi-site cleaning work (docks, beaches, boats, bridges). As a relevant feature within multipurpose character, it has a velocity cleaning activities at 4 knots at Force 6 (Beaufort scale) at open sea, ports, inshore and rivers; [3] Maneuverability: four propulsion units. 2 main propulsion units at the rear of each hull and auxiliary thruster units located in each of the bows. The bow units allow generating and controlling a water flow between the two hulls, even while stationary, offering advanced collection possibilities; [4] Efficiency: collection+bagging system facilitates clean-up of 15 tons/hour of hydrocarbon spills (separation rate of 70-80%; no emulsion creation, which avoids additional effort for splitting water and hydrocarbon); [5] Easy Operation: Our proprietary OC-Tech collecting system avoids the need to go back to the port to upload the recovered hydrocarbon leading to savings in fuel and [man·hours] (≈55%); [6] Easy Transportation: OC-Tech foresees future modular design/construction/re-assembly to be conveyed by road/sea/air, leading to faster action than other options; [7] Profitability: OC-Tech will deliver cumulated revenue of €21.55M and cumulated profit of €10.365M by 2023. +Mastitis is one of the most widespread and costly diseases in the dairy industry, inflicting serious damages on a global scale.In herds without an effective mastitis control program, 40 % of cows are infected every 6 months. Treatment of mastitis costs ca. €185 per cow per year. Antibiotic treatment is currently the only solution for treating bacterial mastitis. The antibiotic treatment causes very large losses in milk production and degradation of milk quality, and creates bacteria that are resistant to antibiotics. For many years, scientists all over the world tried to find a non-antibiotic treatment against mastitis. We have developed a highly innovative technology that heals mastitis without resorting to antibiotics. Based on the energetic signature of mastitis pathogens received from the farm computer, our system processes the cows’ drinking water using radio emissions. Infected cows that drink the treated water are healed from mastitis without the need for antibiotics. A working prototype of the system was tested at a 300-cows dairy farm, successfully healing 39 out of the 49 sick cows. Apart from the healing effect, the new treatment facilitates compliance with major EU health regulations. The project will study the requirements for large scale production and delivery of the technology to the dairy industry. It will boost the EU business in milk production and create large environmental, economic and social benefits. Market drivers and a 5-year growth potential will be analysed and a commercialisation strategy will be devised, along with an IPR protection strategy, analysis of competing technologies and planning of promotional and partnership activities. This will enable us to redesign the technology for serial production and scale up for a successful market entry. +In irrigation water cannot be decoupled from energy. Raising water from rivers and canals and distribute it to the crops requires pumping of large volumes of water with a sizeable amount of pressure, which is generated by means of electric energy or by fuel-driven pumps. This turns into a substantial increase of energy consumption and capital expenditure, which has become a real concern for farmers and their communities. Besides, sharp increases in energy tariffs almost doubled the energy bills that irrigators have to pay, which accounts for up to 40% of the total irrigation costs for farmers’ communities. In a context exacerbated by the ongoing climate change, European farmers are striving to reduce their water footprint by means of water saving irrigation technologies while optimising their energy costs for pumping, with the aim to ensure long- term economic and environmental sustainability. To address this global need, aQysta has designed the HyPump, an innovative spiral pump which converts the energy from the flow of existing irrigation canals to pressure for pumping water, delivering pressurized water directly to the agriculture plots without requiring any fuel nor electricity to be operated. This Phase 2 is focussed on the industrialisation and field tests of the HyPump, which will allow farmers obtaining up to 75% savings on the overall costs for modernizing infrastructures and running an irrigation system with respect to competing electric or fuel-driven solutions, and up to 37% savings with respect to solar pumps. Through the Cost Benefit Analysis run during Phase 1, annual net savings have been estimated in the range of 5k€-8k€ per hectare with respect to electric pumping. Besides, a payback time in the range of 2,5-4 years has been estimated when switching from an electric or fuel- operated system to the HyPump, obtained with zero environmental footprint with respect to fuel or energy powered pumps. +Biofouling, i.e. the formation of deposits of biomolecules or even bacteria in the surface of the medical device, is the main cause of the loss of the devices performance. LipoCoat’s patented nano-coatings make use of lipid bilayers to prevent biofouling of medical devices when placed into contact with bodily fluids in- or outside of the body. Our natural and bio-inspired coating makes use of molecules found in every cell, making it extremely biocompatible. The neutral LipoCoat molecules can efficiently attract water thus preventing any interaction with proteins and cells. Furthermore, LipoCoat can stably apply these layers using our proprietary LipoCoat FAST manufacturing process. +The CO2EXIDE project aims at the development of a combined electrochemical-chemical technology for the simultaneous “200%” conversion of CO2 to ethylene at the cathode, water oxidation to hydrogen peroxide at the anode and a subsequent chemical conversion of both intermediates to ethylene oxide and oligo-/polyethylene glycol in a cascade, boosting this technology from TRL4 to TRL6. The CO2EXIDE technology combines a modular nature for the feasibility of a decentralised application, a high energy and material efficieny/yield and the substitution of fossil based production of ethylene oxide. The CO2EXIDE technology will be combinable with renewables and allows for the direct creation of products, which can be integrated into the existing supply chain. The reactions will be operated at low temperatures and pressures and forecast significant improvements in energy and resource efficiency combined with an enormous reduction of GHG emissions. All improvements will be quantitated using Life Cycle Assessment. +Livestock farming is putting a significant pressure over the environment. Globally, the livestock sector uses 70% of the arable land and emits 15% of all human-induced greenhouse gas (GHG) emissions. If an alternative to the current meat production systems is not found, the situation would only worsen given the fact that meat demand is expected to increase globally by 73% by 2050. +The use of solar energy for photoelectrochemically splitting water into H2 and O2 has been widely investigated for producing sustainable H2 fuel. However, no commercialisation of this technology has emerged. Currently the main obstacles to commercialisation are: low solar-to-hydrogen efficiency, expensive electrode materials, fast degradation of prototypes, and energy losses in separating H2 from O2 and water vapour in the output stream. The FotoH2 consortium has identified a new scientific direction for achieving cost-effective solar-driven H2 production, and it has the capability of large-scale prototyping and field testing the proposed technology. FotoH2 introduces anion-exchange polymer membrane and porous hydrophobic backing concepts in a tandem photoelectrochemical cell, and a novel way to stabilise the photoelectrodes based on a surface phase transformation. This approach allows the use of cost-effective metal oxide electrodes with optimal bandgaps and a simple flow-cell design without corrosive electrolytes. +The project aims at a holistic new design strategy, coordinated pilot lines and business model for the prototyping, fabrication and commercialization of polymer-based microfluidic systems. It stems from the recognition that a microfluidic chip is a key part of a microfluidic MEMS, but only a part. Many limitations to fast prototyping, industrialization and ultimate performances lie not in the chip itself, but in the world-to-chip connections and integration of multiple external components. We shall address in a single strategy the streamlined construction of whole microfluidic systems, starting from existing pilot lines in injection moulding, 3D printing and instrument construction. This will specific innovations. First, the resolution of 3D printing will be increased by a factor at least 10, down to 1~3µm, with a throughput 10 to 100x higher than that of current high resolution 3D printing machines, to support the flexible production of chips with complex 3D architectures. New soft, bio, environment-friendly and/or active materials will be integrated in the production chain using a technology patented by the partners. Large-scale markets requiring mass production at the lowest cost will be addressed by a fully integrated pilot line, streamlining injection moulding of raw chips, reagents and components integration, sealing and quality control. Inter-compatibility between 3D printing and injection moulding, regarding architectures and materials, will be developed to accelerate the prototype to product value chain. After development and upscaling, the technology will be demonstrated and qualified in operational environment by end-users with lab-on-chip applications in health (cancer diagnosis, organ-on chip) and environment (water control). Partners jointly have the production lines onto which the project’s innovation will be readily integrated, helping microfluidics to become a major component of the 4th industrial revolution. +Near 58 billion paper cups are used globally per year. This involves the consumption of one million tonnes of virgin paper, cutting down 32 million trees, the consumption of 100 billion litres of water, the generation of 25,000 tonnes of waste (solely in the UK), and the emission of greenhouses gases equivalent to half a million cars. Paper cups are often lined or coated with plastic such as polyethylene (PE) or oil- based waxes to prevent the liquid from leaking out or soaking through the paper. These paper cups are almost impossible to recycle because of the difficulties of separating the paper from waterproof oil-based liners. This means paper cups end up going to landfill or, at best, are incinerated to generate energy. The heavy environmental impact of paper cups is extremely unsustainable, with each one generating a carbon footprint of 0.11kg of CO2. +Since 1947 Kabola develops, manufactures and sells heating systems for vehicles (boats and wheeled vehicles – truck, vans, etc.) and other applications. Kabola has a broad portfolio of diesel, heating oil and biodiesel boilers adapted to the requirements of its customers. Kabola is well known for its classic red cube heaters HR, Compact 7 and B series. In the last years, the increasing pressure for more efficient and greener heating systems encouraged Kabola to develop the new Kabola Blue Ecoline (KB Eco) series. The KB Eco is the outcome of the implementation of the innovative Kabola Blue technology (The Kabola Blue technology allows diesel to burn a blue flame at around 1.500 ºC compared to the 800 ºC of the yellow flame in conventional systems) into the successful HR series. In comparison with its competitors, KB Eco is much more efficient (94% constant over time vs. a degradable 70-90%) and it does not produce soot (both certified by TÜV), it has the best low emission values (NOx, CO, etc) granted with the eco-label “Blauer Engel” (Blue Angel) and require very low maintenance since there is no soot production. KB Eco is sold now with power outputs from 7 kW to 38 kW. The current KB Eco series is highly efficient and clean, however there are still needs not covered in the market that guarantee the profitability of an improved KB Ecoline version (KB Plus) that will include: a new ultra compact model for vehicles with high restrictions in terms of space such as trucks or vans, higher efficiency in all models reaching an outstanding 106% efficiency thanks to a new design and technology, a new range of higher output power models for large boats, availability of clean water a valuable resource in ships, electrical heating and other improvements. Highly efficient and non pollutant heating systems for vehicles represent a huge business opportunity. Proof of that is the 700 units of the KB Eco sold in the last 2 years. KB Plus will boost the current sales of the KB Eco. +The OxTube is the smartest device when it comes to dissolving oxygen and other gases into water or liquids. +Leaks in large diameter pipes is one of the most important problems in the water supply chain, since they account for more than 50% of total water loss that amounts to 6.58 billion EUR annually. +The aim of the SINUSLIGHT project is to develop a business plan for the continued development and commercialisation of a hand-held medical device, based on laser spectroscopy, to be used within health-care to aid in diagnosing sinus related problems, e.g. sinusitis. The device provides information on the open/air filled sinus cavity size, the oxygen concentration in the cavity and thereby the ventilation status of the sinus. The improved diagnosing possibilities provided by the device can provide an objective test and improve the care and reduce the unnecessary prescribing of antibiotics. The technology has already been clinically evaluated in a research study of 40 sinus cases with good success in correlation with the golden standard CT. +HDBAT aims to develop and commercialize the next generation of high-energy (HE) and high-power (HP) Li-ion pouch cells for large e-Mobility and automated guided vehicle (AGV) +Beet and cane sugar’s reputation is plummeting among EU28 citizens. Consequently, the Food&Drink industry is seeking for alternative sweeteners to enhance their products’ palatability while meeting consumers’ demands of healthier and natural products. In this context, fruit concentrates arise as a reliable sugar substitute since they are a natural sweetener perceived as healthier. This segment is expected to grow globally at a CAGR (Compound Annual Growth Rate) of 5.5% to reach an estimated global value of around 38,500 M€ by 2022 . +Steel sheet piling (SSP) is the dominant solution in the deep foundation industry (followed by precast concrete sheet piles). It presents relatively high mechanical performance and consists a light (in comparison with concrete) and affordable solution. However, SSP faces significant corrosion issues and has a maximum life expectancy of 50 years. Moreover, the interlocking system between the adjacent pile elements has minimum insulation and as such, permeability issues may arise. Finally, piling is taking place through vibration, which can cause structural disturbance in the nearby construction and noise levels of up to 90db(A) +SUNTHERM has developed a Worlds first 25 kWh thermal storage compact battery, based on salt hydrate dissolved in mineral oil that enables up to 25 hours of heat displacement (patent pending). SUNTHERM’s game-changer integrated heating system for households - SmartHeat - consists of: +Amapex SL (Amapex) is a Spanish SME founded in 2006 by biologist Joaquim Canadell. We are experts in the application of biotechnology to industrial wastewater treatments. We have our own research lab, where we have conducted extensive research in finding specific strains of bacteria that can decompose the hazardous products present in heavily contaminated industrial waters (such as heavy metals, phosphates, ammonium, chlorinated cyclic compounds, suspended solids and fats). We are proud of saying we are a team of senior friends, close to our 60s, who after developing our careers in different industries have initiated this adventure, “returning” to our origins: bacterial biology. +The company FLEXBIO Technologie GmbH will technologically finalise and commercialise the FLEXBIO process in form of a biological wastewater treatment plant for organically contaminated wastewater, e.g. from the food and beverage industry. In this process, which was developed in cooperation with the HAWK university in Germany, organic contaminants in the wastewater are converted into biogas under anaerobic conditions in a fixed-bed reactor. An optional second treatment step, a trickling filter, can moreover remove nitrogen compounds and further increase the treatment efficiency of the plant. Compared to the aerobic activated sludge process, which currently is the most important process for the treatment of organically contaminated wastewater, the FLEXBIO process has several important advantages: at a comparable treatment efficiency (more than 97 %), the FLEXBIO process requires much less energy (heating or aeration not necessary), produces much less sludge to be disposed of, is much more flexible to variations in the wastewater, can be installed in a compact and mobile container and produces biogas for the generation of heat or electricity. The FLEXBIO process offers an environmentally friendly solution for the decentralised treatment of wastewater especially for SMEs, clearly improving their economic performance. +Nanostructured surfaces that engineer the interaction between an object and its surroundings are a subject of scientific and manufacturing importance. Nature routinely creates nanostructured surfaces with fascinating properties, such as antireflective moth eyes, self-cleaning lotus leaves, colourful butterfly wings, and water harvesting desert beetles. Well defined nanostructured surfaces have huge commercial potential due to product enhancement: reduced reflectivity in photonic devices and solar panels, antiglare plastic parts for the automotive industry, hydrophobic self-cleaning surfaces for smart packaging, antireflective and smudge-free smartphone displays, and biofouling resistant marine and water treatment systems. Unfortunately, the lack of cost-effective, scalable, nanopatterning methods is a major hurdle for the commercial exploitation of nanopatterned surfaces. SUN-PILOT will address this challenge by developing a novel and cost effective platform for up-scaling sub-wavelength nanostructures fabrication techniques that can be applied to curved surfaces such as optical lenses, and the mass production of metal moulds for injection moulding of plastic parts. The expected impact of SUN-PILOT for the Optics Industry is a disruptive technology that will boost the performance/cost ratio of photonic devices by piloting mass fabrication of scratch and wear resistant nanopatterned antireflective optical surfaces. Significant enhancement will be achieved in the efficiency of optical components and systems incorporating these devices, such as laser systems, electronic displays, security cameras and medical devices. The Automotive Industry will benefit from a novel method to produce functional surfaces at lower cost and lighter weight than existing lamination methods. This proposal brings together scientists and engineers to span innovation, business development and the product cycle from suppliers to end users and will ensure a leadership role of for Europe. +European agriculture is facing numerous challenges such as population growth, climate change, resource shortages or increased competition. Besides, the area of land available for agriculture is declining, rural areas become depopulated and farming population is aging. Today’s challenge is to produce “more with less”. +Copernicus has boosted the availability of Earth Observation data both in terms of quality as well as quantity. This has, on the one hand, unleashed new opportunities for intermediate business users (IBUs), who provide services to an inherently diverse group of end users. On the other hand, however, the handling of big data volumes, the integration of data streams from different sources, and the generation of high-quality information from the novel sensors of the Sentinels pose significant technical and scientific challenges to many IBUs. The lacking expert skills often hinder the user uptake of Copernicus products and services and eventually impede economic growth of the sector. +CO2 capture process represents typically about 70% of the total cost of the CCS chain. Power plants that capture CO2 today use an old technology whereby flue gases are bubbled through organic amines in water, where the CO2 binds to amines. The liquid is then heated to 120-150ºC to release the gas, after which the liquids are reused. The entire process is expensive and inefficient: it consumes about 30 percent of the power generated. +The goal of PANtHEOn is to develop the agricultural equivalent of an industrial Supervisory Control And Data Acquisition (SCADA) system to be used for the precision farming of large orchards of hazelnut (Corylus avellana L.). By taking advantage of the technological advancements in the fields of robotics, remote sensing and big-data management, our objective is to design an integrated system where a relatively limited number of heterogeneous unmanned robotics components (including terrestrial and aerial robots) move within the orchards to collect data and perform some of the most common farming operations. The information will be stored in a central operative unit that will integrate the data coming from the different robotic units to perform automatic feedback actions (e.g. to regulate the irrigation system) and to support the decisions of agronomists and farmers. +The SWAMP project develops IoT based methods and approaches for smart water management in precision irrigation domain, and pilots them in Italy, Spain, and Brazil (2). +More than a billion people currently live in water-scarce regions, and as many as 3.5 billion could experience water scarcity by 2025. Forecasts estimate that water demand in 2040 will exceed supply by 50%. Seawater amounts to 97% of all water contained on Earth and can, fortunately, be converted into fresh water by desalination. Desalination processes are still expensive, energy intensive and commonly pose great negative impacts on ecosystems. Presently, no current state-of-the-art solutions suggest sustainable technologies to the Earth’s ecosystem. The Reverse Osmosis (RO) membrane segment, which is the largest of the membrane market, was valuated at €1.1 billion in 2015 and is projected to grow by 43% over the 8-year period from 2014 to 2021, reaching a €2.5 billion revenue by 2021. Part of the RO market is dominated by brackish water reverse osmosis membranes (BWRO). Brackish water is water that has higher salinity than fresh water (more than 0.05%) and lower than seawater (less than 3%). Aquaporin A/S has acknowledged this huge business opportunity and has developed a ground-breaking biomimetic technology to separate and purify water from other compounds based on nature’s own principles: Aquaporin water channel proteins. This technology will potentially disrupt the current RO technology, making it more energy and water efficient as well as more sustainable and cost-effective. Since we have a commercial Aquaporin Inside™ RO membrane already tested and validated at low pressure conditions (house hold, 7 bar), our main goal within this project will be to optimise and up-scale this to work at brackish water conditions (15 bar) in both flat sheet and spiral wound module formats. Aquaporin Inside™ Brackish Water RO membranes will boost our growth and consolidate a worldwide reference for us, thereby drastically differentiate us from competitors, and will open the possibility to also get into the seawater desalination market in the near future. +European agriculture is facing important challenges in the coming decades linked to our changing climate. Periods of droughts and floods will further increase which threaten production and require a smart usage of our vulnerable water resources. Climate change also stimulates crop disease, which causes farmers to use more pesticides and in turn endangers water quality and impacts people's health and the environment. Satellite Remote Sensing has a crucial role to play in tackling these challenges. At VanderSat we have developed a method to provide accurate high-resolution images of soil moisture, at any place on Earth 24/7 a year. Soil moisture is a key indicator for the physical status of a plant, and has a strong predictive value with respect to crop yield and weather conditions including flooding and droughts. By combining microwave data obtained from different satellites – including the ones in the Copernicus Sentinel constellation – we are revealing a revolutionary data set that can be used to retrieve key information about the water availability for crops at field level. This data is crucial for improving the accuracy of Agricultural (Ag.) models that are the backbone of modern agribusiness. Through the WATER4AGRI project we want to lift the technology to TRL9 by: (1) scaling VanderSat soil moisture for implementation in Ag. models and, (2) demonstrating the effectiveness of VanderSat in the two most widespread Ag. models. With VanderSat our customers will be able to accurately predict crop yield, pesticide requirements, droughts and flooding and, most important, reduce climate related risks for their businesses. VanderSat is creating business opportunities that were unimaginable before, like reducing crop risks through smart re-insurance strategies and integrated pest management. In doing this VanderSat impacts agribusiness in the most important dimension: improving yield and the overall profit or loss of the operation. +Fabric softeners are the most popular laundry care products after detergents. They keep clothes soft, enhance nice smells while preventing musty odours, extend the life of clothes, reduce the formation of wrinkles and improve endurance ability of clothes against stains. +As reported by the European Environment Agency, 70million people in Europe are living in water stressed areas. In the Mediterranean region that figure rises to 53%. Water shortages affect almost every country in Europe and the problem is getting worse. Water consumption per person is increasing significantly; by 55% in the last 25 years. +Legionnaires’ disease is a serious form of pneumonia caused by bacterium Legionella pneumophila, with a case-fatality ratio on the order of 10-15%. L. pneumophila proliferates in aquatic habitats, especially in potable water, air conditioning, hot and cold water systems, cooling towers, evaporative condensers, spa/natural pools. Actually, its detection and monitoring rely on time-consuming protocols (in the order of several days) based on in-vitro selective bacteria culture methods, performed by highly specialized personnel in dedicated laboratories. POSEIDON project targets to change the approach in bacteriological environmental monitoring and in infection risk management by developing a fully automatic and reliable system. Handling of the air/water sample will be designed and integrated in preconditioning system and microfluidic device through which whole bacteria cells will be transported from the sampling module to the sensing plasmonic surface. The complete measure protocol will be integrated and performed according to EU legislation guidelines. Specificity will be ensured by immuno-functionalization of gratings surfaces and enhanced system sensitivity will be granted by the optimization of the optical detection system architecture. Sensors based on Grating Coupled Surface Plasmon Resonance (GC-SPR) in azimuthally rotating configuration have recently proved sensitivity enhancement up to almost two orders of magnitude. Furthermore, the symmetry breaking related to grating rotation allows exploiting the incident polarization, more easily controlled with respect to incidence wavelength and angles interrogation. The prototype will be designed to be integrated in water distribution or HVAC systems in order to demonstrate its feasibility in industrially relevant fields and to open new applications and new market opportunities. POSEIDON project aims to address new solutions in this relevant health and safety societal challenge. +Cloud security is of immediate concern to organisations that must comply with strict confidentiality and integrity policies. More broadly, security has emerged as a commercial imperative for cloud computing across a wide range of markets. The lack of adequate security guarantees is becoming the primary barrier to the broad adoption of cloud computing. +Alchemia-nova GmbH has great expertise in phytotechnologies, phyto-chemistry and biological systems. Its core activity is research and the development of green, nature based solutions. It is looking to increasingly translate research results into commercial products with national and European distribution. To achieve this, improvement in the area of automated data collection, electronic control systems and computation is needed. Unfortunately, the company lacks well trained experts in the area of electronica and proprietary information technology. The specific objective to be achieved by the innovation associate is to equip an indoor ecosystem (VertECO) prototype (TRL 7) with a customised sensor & control unit that generates information about the quality of treated and purified greywater as well as with an internal energy generation system that ensures broad energy autonomy of the sensor & control unit. Tapping his/her expertise, the associate supervises the planning, development and testing of these units and initiates combinations and adaptations accordingly. In this process, the innovation assistant minds the commercial solution to feature simplicity, reliability, smart automation, cost- and energy effectiveness. Eventually, the sensor/control and power supply systems are directed to be an integral part of VertECO and in this sense, the realisation of the features will considerably contribute to the market potential and positioning. +Humanity’s plans to further explore space require the development of bio-regenerative life support systems and in particular plant cultivation. Plants contribute to all major life support functions by producing food and oxygen, reducing carbon dioxide and recycling water and waste. Moreover, fresh crops also have a positive impact on crew psychological well-being. EDEN ISS aims to adapt, integrate and demonstrate plant cultivation technologies and operations procedures for safe food production on-board the International Space Station and for future human space exploration missions. The consortium will demonstrate operational capability of controlled environment agriculture technologies and procedures for safe food production in space. A mobile test facility will be built to provide realistic interfaces analogous to ISS. A one-year demonstration campaign at the Neumayer III Antarctic station will provide extensive testing and validation capability to increase the technology readiness level of key subsystems to 6. Further developing these technologies and operations procedures, including food quality and safety measurements, will also contribute to Europe’s interest in resource efficient crop cultivation, saving energy, countering the climate change and securing the supply of healthy and safe food. The interdisciplinary nature of EDEN ISS combines research in space engineering, horticulture, food science and microbiology. Leading space industries (Thales Alenia Space Italia, Airbus Defense and Space, Telespazio), research organizations (DLR, CNR, AWI), SMEs (Liquifer, Heliospectra, EnginSoft, Aero Sekur) and academia (Wageningen UR, University of Guelph, Limerick Institute of Technology) from six European countries (Germany, Ireland, Italy, Sweden, Austria, the Netherlands) and Canada join forces in a unique consortium to prepare the ground for further innovative research and development in human spaceflight and terrestrial applications. +Company ESDA has developed HeatSel®, the first viable macro-encapsulation solution functioning with phase change materials (PCM) for latent thermal energy storage in heating and cooling systems. Accounting for 50% of the EU's annual energy consumption, heating and cooling is the sector with the biggest energy-saving potential in Europe, and urgently needs to become more sustainable. In the low temperature range (5 to +100°C), most thermal energy amounts are required and then discarded worldwide. PCM are key materials to save these huge energy and – at the same time – CO2 amounts. They can run through a reproducible phase-change at a substance-specific temperature, during which the thermal energy is either stored in very large amounts or returned at a constant temperature. Since decades, an adequate method is being sought to transfer PCM into a user-friendly form. Both existing micro- and macro-encapsulation solutions for PCM storage have until now revealed industrially, technically and economically inappropriate. Sensible heat storage with large water storage tanks has very low energy density and storage capacity. ESDA is specialist in the technical extrusion of blow-moulded parts and has in the past 5 years acquired expert knowledge in PCM and thermal storage technology. HeatSel® is a PCM-filled capsule for use in aqueous systems as a heat transfer medium. Most unique selling points of the solution are: universal applicability with diverse (even older) heat exchangers; high energy efficiency through the re-use of waste energy (4 times more efficient than water heat storage) and boosting of renewable energy such as solar thermal technology. Primary target market is the high-volume heating and cooling market in residential buildings in Europe, secondary market is industrial process heat/cooling. ESDA foresees a large impact for HeatSel® in combination with solar thermal and heat pump systems, with a cumulated turnover of €33.7M and 56 job creations by 2023. +SUPREME aims at optimizing powder metallurgy processes throughout the supply chain. It will focus on a combination of fast-growing industrial production routes and advanced ferrous and non-ferrous metals. By offering more integrated, flexible and sustainable processes for powders manufacturing and metallic parts fabrication, SUPREME enables the reduction of the raw material resources (minerals, metal powder, gas and water) losses while improving energy efficiency, production rate and CO2 emissions, into sustainable processes and towards a circular economy. To achieve this goal, an ambitious cross-sectorial integration and optimization has been designed between several powder metallurgy processes: gas and water atomization as well as ball milling for metal powder production, additive manufacturing and near-net shape technologies for end-parts fabrication. Quality and process control will be developed to monitor KPI, based on eco-innovation approach, to demonstrate the optimization of material and energy use. 4 demonstrators will be proposed at each step of the value chain in real industrial setting and ready for business exploitation at TRL 7: mineral concentration, metal powder manufacturing, metal part manufacturing and end-product that will validate a global optimization of more than 25% on material yield losses, more than 10% on energy efficiency, more than 10% on production rate and beyond 30% of CO2 emissions. SUPREME has gathered an outstanding consortium of 17 partners from 8 countries, represented by 11 companies including 6 SMEs that will ensure a successful implementation towards market applications. 5 applications sectors are targeted: automotive, aeronautics, cutting tools, molding tools and medical. The process key differentiation advantages will bring modularity, flexibility and sustainability to powder metallurgy and will reduce the total cost breakdown of these technologies, boosting their adoption by industry. +Industrial biotechnology is being increasingly considered as a means to lower the dependency on oil-derived raw-materials, increase the use of renewable resources and reduce the use of water, energy and the production of CO2 emissions in the current chemical industry. However, although generally more sustainable and environmentally friendly, bioprocesses are normally not yet economically competitive. SILICO develops rational solutions for the optimization of microbes, targeted at the robust and cost-effective production of target compounds such as bio-fuels, food ingredients, chemical building blocks or biopolymers. +There is a compelling need of encouraging energy efficiency in buildings, enhance green technologies and promote advance thermal energy storage solutions. TESSe2b will enable the optimal use of renewable energy and provide one of the most advantageous solutions for correcting the mismatch that often occurs between the supply and demand of energy in residential buildings. The target of TESSe2b is to design, develop, validate and demonstrate a modular and low cost thermal storage technology based on solar collectors and highly efficient heat pumps for heating, cooling and domestic hot water (DHW) production. The idea is to develop advanced compact integrated PCM TES tanks exploiting RES (solar and geothermal) in an efficient manner coupled with enhanced PCM borehole heat exchangers (BHEs) that will take advantage of the increased underground thermal storage and maximize the efficiency of the ground coupled heat pumps (GCHP). The two TES tanks developed within TESSe2b project will be integrated with different PCM materials; (i) enhanced paraffin PCM, (ii) salt-hydrates PCM, while in both of them a highly efficient heat exchanger will be included. Even if the concept of phase change thermal stores has been demonstrated, TESSe2b project discriminates itself through incorporating; (i) PCM materials innovation, (ii) advanced energy management through self-learning model-based control system, (iii) enhanced PCM BHEs (v) compact modular design of thermal storage tank. Since the lifetime of TESSe2b solution is among the most critical factors determining its acceptability, reliability and success the on the long run, special emphasis will be given in the life-expectancy of the involved components. +The recent 20 years have seen the discovery of new classes of nanoporous materials (NPM). It includes amorphous micro-mesoporous aluminosilicate type materials and more recently Metal-Organic Frameworks (MOF). Despite the great potential of this new class of materials, we cannot recognize industrial success yet at the level of initial expectations and business opportunities. +The SCORES project aims is to develop and demonstrate in the field a building energy system including new compact hybrid storage technologies, that optimizes supply, storage and demand of electricity and heat in residential buildings, increasing self-consumption of local renewable energy in residential buildings at the lowest cost. +Nowadays, the major part of offshore operations is done by divers in dangerous missions. Since their number is limited, the dependency on their work represents a real threat to the offshore industry. The extended use of unmanned underwater vehicles (AUVs/ROVs) could solve this problem but since they are usually tailor-made for a specific task and difficult to operate their deployment is very expensive. +The scope of the project is the optimization of downstream process (DSP) for the production of Biopharmaceuticals. Biopharmaceuticals have been successfully used as efficient therapeutic drugs for many pathophysiological conditions since the first recombinant product, insulin, was approved in 1982. Despite its efficacy, accessibility is still limited due to extremely high costs. In the production chain, capturing and purifying still represents a major bottleneck. Consequently, improvements in this area produce substantial cost reductions and expand patients’ accessibility to highly efficient drugs. Another aim of this action is to cope with the changing manufacturing demands, by lowering its environmental footprint and moving to more sustainable technologies. This proposal’s main objective is to implement a fully integrated manufacturing platform based on continuous chromatography in combination with disposable techniques for all unit operations of the DSP sequence for biosimilar monoclonal antibodies and derivatives thereof. The action encompasses the entire DSP sequence. We will implement alternative technologies for primary separation, such as flocculation or tangential flow filtration. The expected outcome is a reduction in the size and number of downstream unit operations and the elimination of centrifugation. Alternative approaches to the batch process for the capture step, such as continuous chromatography, will be evaluated in order to improve the efficiency and lower the need for expensive resin volume. Additionally precipitation utilization will be evaluated as an approach to replace protein A chromatography as capture step. A disposable continuous chromatography system will be developed together with novel analytical tools and sensors. Since single-use disposable systems can substitute the extensive use of resources (water) and significantly reduce the overall utility needs, the whole DSP sequence will be carried out on disposable technology (PAT). +European Water utilities environment is embedded in a context dealing with global issues such as water scarcity and technical-economic issues such as infrastructure aging. Management of drinking water supply is facing key challenges partly related to traditional water meter, such as managing capital and operational costs; water loss (also known as non-revenue water) due to leaks and other system failures; and water scarcity/conservation. +Critical water infrastructures and high profile (soft) targets are vulnerable to intentional drinking water contamination. Physical access is difficult to control and traditional water quality monitoring solutions are largely inadequate to protect the water distribution process and its consumers. In light of increasing security threats there is a strong need amongst water suppliers and authorities, in Europe and globally, for a contaminant warning system that can be deployed in the distribution network and that provides real-time water quality information and event classification to support rapid decision making and protect the health of citizens. +The project NANO-CATHEDRAL aims at developing, with a nano-metric scale approach, new materials, technologies and procedures for the conservation of deteriorated stones in monumental buildings and cathedrals and high value contemporary architecture, with a particular emphasis on the preservation of the originality and specificity of materials. The objective is providing “key tools” for restoration and conservation: +Our Earth is drying-up. Water is an over-used vital resource worldwide and more than 1billion people still live in water-scarce regions and around 3,5 billion could experience water scarcity by 2025. Fortunately, 97% of all water contained on the Earth is in liquid phase & just few steps from the coast: Seawater. Within this scenario, global desalination capacity in 2015 reached 95 million m3 water per day, distributed among 18,700 plants worldwide. These incredible figures are translated into a global water desalination market already representing over €12 billion/year and CAGR of total cumulative contracted capacity over 9.5% per year. +Gescaser SA specialises in the manufacture and commercialisation of grain temperature monitoring systems for silos and horizontal storage units. Our current remote control systems provide detailed and continuous measurement of grain temperature at different levels in the grain silo. We currently have over 350 installations in 40 different countries worldwide. Thanks to our over 40 years’ experience, we are experts in our field and we know our market very well. We have identified a market opportunity to develop an intelligent multi-parameter monitoring system for cereal conservation in grain silo plants product that offers improved quality control of stored grain. +Blue Farm will enable the fish farming industry to move their production from today’s protected inshore ocean space to harsh weather conditions of the open ocean, through piloting and later commercialising a patented fish cage demonstrated to operate in 10M high waves. Our fish cage is designed and tested to handle 10 meter high waves. Much of the structure is made of concrete that has given low long-term cost in similar oil and gas projects. The fish cage is much larger than traditional fish cages (allowed by larger water resources offshore). This gives economics of scale in operation (e.g. spreading the cost of automation tech). The fish cage provides calm living environment for the fish through a wind- and wave breaker. The openings of the wind and wave breaker are designed by simulation programs run by Egersund Net (world’s largest fish net provider). Also, water quality is better offshore than in inshore environment with dense fish farming activity. This is a feasibility study that will plan marketability and a pilot of this technology. +Nanocomposites are promising for many sectors, as they can make polymers stronger, less water and gas permeable, tune surface properties, add functionalities such as antimicrobial effects. In spite of intensive research activities, significant efforts are still needed to deploy the full potential of nanotechnology in the industry. The main challenge is still obtaining a proper nanostructuring of the nanoparticles, especially when transferring it to industrial scale, further improvements are clearly needed in terms of processing and control. +The overall objective of this project is developing organic electronic building elements on flexible substrates with monolithically integrated barrier foils as substrate. The barrier acts as the inevitable protection against atmospheric gases as water vapor and oxygen, as the most crucial agents for unwanted material degradation processes. This topic is one of the keys for enhancing both the performance of TOLAE components and addresses some of the main technology barriers of TOLAE: lifetime and cost-performance-ratio. +ambliFibre will develop and validate the first intelligent model-based controlled laser-assisted tape winding system for fibre-reinforced thermoplastic (FRP) components. This system will include optical non-contact monitoring and innovative Human-Machine-Interfaces, which are easily manageable for the worker. Based on thermal and optical models embedded into integral process simulation tools combined with novel machine and laser technologies, for the first time a tape winding system will be realised which is able not only to drastically reduce the occurring waste, but also predict potentially arising failure in order to reduce machine downtimes. Statistical reliability and maintenance models for detection of critical elements and definition of their reliability will also prevent sudden machine breakdowns and allow defining the most cost-efficient maintenance schedule. +Remanufacturing is an important component of a resource efficient manufacturing industry. By keeping components and their embodied material in use for longer, significant energy use and emissions to air and water can be avoided. In addition to environmental benefits, remanufacturing provides opportunities for the creation of highly skilled jobs and economic growth. +NANOLEAP project aims at the development of a coordinated network of specialized pilot lines for the production of nanocomposite based products for different civil infrastructure and building applications. +The ReWaCEM project aims at reducing water use, wastewater production, energy use, valuable metal resource recovery and water footprint by between 30-90% in the metal plating, galvanizing and printed circuit board industry. In order to achieve these goals, ReWaCem will adopt two cutting edge membrane technologies suitable for the requirements of closed material cycles approaches and recovery concepts in metal processing industry: Diffusion Dialysis (DD) and Membrane Distillation (MD) as an integrated hybrid process. This combination of existing technologies will be adapted to fit the requirements of 4 pilot demonstration sites in representative industrial applications of the metallurgical industry in order to evaluate the accomplishment of the ReWaCEM goals. Through the evaluation of the demonstration a highly attractive technological solution for low energy wastewater treatment will be available to be entered into the large and growing market of metal processing. This market will profit significantly from the technological outcome of the innovation action, with cost savings and environmental benefits as relevant rewards. In order to maximise impact, the project consortium was selected carefully to represent all relevant stakeholders in the quadrant of end users, scientific partners, associations and decision makers and SMEs. The consortium will establish a dissemination & exploitation board that will create a substantial network of interest groups from agencies, industry, research SMEs and research centres as well as universities. The successful exploitation of the results will lead to a post project up-scaling of the technology and a step by step market introduction. Part of ReWaCEM will be to mobilise all relevant stakeholders into promoting innovative membrane solutions for industrial water and resources management, leading to the effective implementation of European directives and policies while creating market opportunities for European industry and SMEs. +AQUARIUS proposes disruptive improvements in laser based water sensing employing MIR quantum cascade lasers (QCLs). It is motivated by +LIPP GmbH, based in Tannhausen in the south of Germany, is one of the leading tank manufacturers in Europe, having been in existence since the 1950’s. In the past decades, Lipp has patented over 170 different manufacturing, material and tank design technologies and is an innovative highly awarded (Rudolf-Diesel-Medaille) SME. Altogether, over 50,000 tanks and containers have been constructed globally with the internationally marketed and licenced LIPP Double-Seam Technology. +The integration of reaction and downstream processing steps into a single unit is of central importance in order to achieve a new level of process intensification for catalytic driven and eco-friendly reaction systems. This disruptive technology concept has the ability to reduce the total energy consumption of large volume industrial processes by up to 78%. Additionally, emissions can be reduced by up to 90%. +BASE-platform provides an innovative service for satellite derived bathymetric data for a broad range of users through a commercial service platform. Bathymetry is the measure of the water depth similar to underwater topography. BASE-platform has the ambition to establish a commercial service platform for bathymetric data, which is sharpened to user needs and provides most easy access. Its impact is expected to significantly influence the current market, its survey methodologies and the way bathymetric data can be accessed and used. +Product: Amphiro has developed the first energy-autarkic, micro-mechatronic modules that measure, communicate and display hot water consumption in real-time and at the point of use. The modules are powered by water flow, fit to virtually every water outlet and can be retrofitted by end-users or integrated by faucets OEMs. The patented technology helps to monitor personal energy and water use, motivates a sustainable behavior and allows faucet OMEs to add digital features to their products. +Sphagnum peat moss is a valued, recognized, natural, organic reserve that is largely harvested for use as a soil conditioner or amendment in horticulture. It is often referred to as the universal soil conditioner for its benefits to the soil. The decayed and dried sphagnum peat moss is usually referred to as simply peat. As a soil amendment, it is free of weed seeds, pests and pathogens and can absorb up to 20 times its weight in water. The peat bogs from which peat moss is derived are one of the most distinctive kinds of wetlands. Peat bogs are an important environmental resource and create areas of huge biodiversity, keeping more carbon dioxide out of the atmosphere than forests, and helping to prevent flooding. Problem: Naturally formed peat has been harvested for centuries, and European supplies are seriously depleted in England, Holland and Germany, and are in the process of being commercially harvested in areas of Eastern Europe. This harvesting causes serious environmental problems, as the peat cannot be regenerated within our lifetimes. Habitats are destroyed, and the carbon balance is badly affected, as peatlands are major stores of carbon and are vital environmental ‘regulators’. Many peatlands globally, which have been farmed for peat, are now sources of greenhouse gases, owing to degradation and oxidation of the unsaturated peat layer. The UK government are currently working to completely phase out the use of peat based products in UK Horticulture by 2030, but there is presently no viable alternative growing media which offers the same quality as peat. This project is to determine the business opportunity for the commercialisation of a method to grow moss on a large scale, on mats, which will speed up significantly the growing process, enabling the production of a sustainable growing media for horticulture (replacing peat) and creating a valuable cash crop opportunity for farmers. +In the vaccine industry, downstream processing is of extreme importance. Prophylactic vaccines aim at protecting healthy people, so any contaminant has to be discarded with the most drastic measures. Such « negative » approach comes at the expense of the recovery of product : yields are poor, thereby inducing a high product cost. Processes are also complex, since they rely on multiple eliminations rather than on recovery of the unique product of interest. Technically, this is mostly due to the lack of specific capture systems that would allow direct, « positive » separation of the vaccine from its environment.Vaccines know no borders. For developing countries, the pressure on costs is even more acute, and local production is a way to try to reach the 1$ per dose target. In this context, water sustainability is a major issue, as it is a most sensitive ingredient in bioproduction. +The aim of the CSA MEASURE is to provide support and guidance, how to reach the H2020 SPIRE Public Private Partnership goals on reduction in fossil energy intensity, non-renewable, primary raw material intensity and greenhouse gas emissions in the most effective way. MEASURE will deliver a roadmap how to evaluate processes in a standardised, comparative way. Benefiting from the strong support of our cross-sectorial Advisory Board, the impact of the MEASURE roadmap shall outreach the H2020 SPIRE programme towards harmonised standards for sustainability assessment in the entire European process industry. MEASURE will bring together leading European process industries in chemistry, consumer goods, steel, automotive, non-ferrous metals, water and waste with well-known research centres, and academic experts with profound complementing expertise on sustainability assessment with regulators and standardisation bodies. +Industrial Phycology (IPHYC) has developed a wastewater treatment (WWT) process to meet tightening discharge consents for the concentration of nitrogen (N), phosphorus (P) and other materials in wastewater (WW) effluents. These nutrients & materials are linked to adverse environmental events e.g. eutrophication. WWT operators require a sustainable treatment process to remove / recover these materials to meet legislation. +To pave the way forward for IS as a solution for more efficient processing and energy systems for the +POWER is a user-driven project to share knowledge and experience of water related issues in different EU local authorities to create a tool for EU water policy. It addresses four of the eight EIP WATER priorities: +The IoF2020 project is dedicated to accelerate adoption of IoT for securing sufficient, safe and healthy food and to strengthen competitiveness of farming and food chains in Europe. +EcoSolar envisions an integrated value chain to manufacture and implement solar panels in the most ecologic way by maximising resource efficiency, taking into account reuse of materials during production and repurposing solar panel components at end of life stage. EcoSolar will demonstrate that during the lifetime of a solar electricity producing field, individual panels can be monitored, allowing to identify defaulting panels at an early stage, replacing or repairing them and thus to increase the overall energy yield. +In ZAS the topic NMP-13-2014: "Storage of energy produced by decentralised sources" will be addressed in order to improve the performance of rechargeable zinc-air batteries as a promising option for stationary energy storage. +Concept: NanoFASE will deliver an integrated Exposure Assessment Framework, including methods, parameter values, model and guidance that will allow Industry to assess the full diversity of industrial nano-enabled products to a standard acceptable in regulatory registrations. Methods to assess how use phases, waste streams and environmental compartments (air, soil, water biota) act as “reactors” in modifying and transporting ENMs will be developed and used to derive parameter values. Our nanospecific models will be integrated with the existing multi-media fate model SimpleBox4Nano for use in EUSES and also develop into a flexible multi-media model for risk assessment at different scales and complexities. Information on release form, transformation and transport processes for product relevant ENMs will allow grouping into Functional Fate Groups according to their “most probable” fate pathways as a contribution to safe-by-design based on fate. +The overall aim of the project is to develop a new production concept for converting CO2 to white oils and aliphatic high molecular weight waxes. The products are used for wax emulsions and white oils to be used in coatings and sealant materials. The properties of the raw materials will be tested against current fossil based materials. The main raw material for the process is CO2 which is available from processes currently operating at a large industrial site with significant annual CO2 emissions. H2 is obtained as by product from a chlor-alkali plant on the site. Currently H2 is produced in excess and it is used mainly for energy production. Currently at this chemical production site about 2 million tons/a of CO2 is vented to the atmosphere, creating a huge GHG emission reduction potential. The core of this project is a combination of reverse water gas shift (RWGS) coupled with advanced, modular Fischer-Tropsch (FT) technology. The RWGS-step converts CO2 with H2 to carbon monoxide. The following FT-reaction step will be carried out in a novel intensified reactor recently developed and patented by Ineratec. Over 1500 kg of white oils and high-molecular weight wax will be manufactured using a container-sized microstructured reactor system. Techno-economic and environmental assessments will be carried out to demonstrate the potential of the new concept in different locations and integration sites. A business plan will be formulated in the project for a follow-up of a commercial industrial demonstration project. +The objectives of the overall innovation project are the optimization and certification and EU-wide commercialization of a methodology to safely transforming humid organic waste (such as sewage sludge) into green energy (electricity) by combustion while extracting valuable materials from the remainder ash like phosphate. The technological feasibility has already been demonstrated; therefore the project outcome will be a system that is certified, marketable and clearly positive on cost-benefit side. +The proposal is about the development of an innovative floating Tension Leg Platform (TLP) capable of conducting financeable grade wind measurements and environmental parameters measurements for offshore wind parks. +Global land resources are under pressure in the face of growing demand from an exponentially growing population and the impacts of climate change. The numbers demonstrate that we are wasting our natural capital at an accelerating pace. The time to act is now, by initiating large scale land restoration programs involving tree plantings. The ecosystem restoration market is globally estimated at US $300 billion. +As large amounts of energy are used by pumps for lifting and moving water and as energy costs are the second highest cost of a water utility’s operating budget, the proper selection of pumps, motors, and controls is critical to ensure an efficient system and to control costs. +Hose reel irrigation systems are a type of sprinkler irrigation which is best used on irregular-shaped and difficult-to-reach areas. Although it is widely used, it presents some problems related to the high degree of friction between the hose carrying the water, and the ground. This fact implies larger labor force to move the hose, therefore provoking an inefficient use of resources (water and fuel); thus increasing fuel consumption and GHG emissions. This becomes particularly difficult at the time of rainy or muddy grounds by getting the hose stuck on the soil with no possibility to move and with the eventual broken of the hose or even the machine drive system. Moreover, the abrasion produced by the constant friction, deteriorates the hose, reducing its useful life. +Our waste water consists of many dissolved and undissolved substances from industrial, commercial and domestic waste water. This results in a special environmental problem within the sewer: hydrogen sulphide (H2S). +evapEOs® is a new proprietary cold concentration technology developed by EDERNA, a French SME. evapEOs® allows to produce high quality food and biotechnology products using low energy consumption, obtained using low operating temperatures, which represents serious European and global problem. The process has already been validated by several potential industrial users for a broad range of applications (fruit juice concentrates, dairy or plant proteins, coffee and tea extracts, etc.). +Functional drinks are an important aspect of a modern and healthy lifestyle. These drinks include non-traditional ingredients such as herbs, minerals, vitamins, electrolytes or amino acids, and offer definite health related benefits that go beyond general daily nutritional intake. In the last years, functional drinks are becoming more and more popular, showing constantly high growth rates in both the European as well as the global market. +Ordinary ready-mixed concrete is made of sand, cement, water, stone gravel and additives. Albeit aggregate gravel is chosen for its high compressive strength and relatively low cost, its use is associated with different problems. Due to its high density, any construction will require more steel reinforcement to support the weight of the heavy concrete. The different sizes and shapes as well as the inconsistent distribution of the gravel causes air and water voids, causing weak points and is responsible for crack propagation in the concrete structure. Despite technical problems, the usage of gravel is also responsible for significant amounts of quarrying, transportation costs and CO2 emissions. We have innovated and developed a novel process and a system (consisting of the GEM-TECHTM machine and GEM-SOLTM catalyst) that creates a ‘superior foam’, which does not drain off for at least 12 hours, providing sufficient time for the cement to set resulting in high compressive strengths. The geodesic structure that is created by the novel mixing screw action and the ingredients that are mixed systematically in the GEM-TECHTM machine without using any gravel or any admixtures into GEM-TECHTM ready-mixed material provide significant cost savings. The main objectives of the ReMix project is to investigate the feasibility of developing different size machines with different specifications, examine the commercial and technical risks of the process, develop strategies to meet different standard requirements and develop strategies to commerialise our unique product. The overall objective is to develop an advanced ready mixed concrete replacement material, which is at least 45% cheaper, 28% lighter, with high compressive and flexural strengths. Our main goal is to establish GEM-TECH technology as a novel replacement for the existing ready-mixed concrete ageing technology. This is a disruptive technology, which will revolutionise the ready mixed concrete market. +The FAME project aims to develop and demonstrate an innovative system for qualitative food content analysis in liquid food samples, based on the Fourier-Transform Near-Infrared Spectroscopy (FT-NIR) method. The new system will be the first food analyser in any technology that can be used for taking advanced laboratory-type measurements of higher precision and on a wider number of parameters directly in the production line (continuous in-line measurements). Moreover, the instrument makes it possible to do measurements in more than one production location at the same time, as well as operate simultaneously in the production line and in the lab environment. This unique combination, together with the superior precision and versatility of analysis offered by our patented FT-NIR solution will open up new possibilities for food and beverage producers to have a complete control of their production process at any time, thus ensuring the highest standards in food quality and safety as well as reducing costs and increasing their efficiency in production. +Bluemater CEO Nuno Gomes conceived this project inspired by the words of the inventor and author Buckminster Fuller: “Nature has no pollution. This is a word coined in human ignorance regarding the presence of the right chemicals being released in the wrong places…” While high concentrations of compounds such as ammonium, phosphates and sulphates can be deadly for aquatic ecosystems and their inhabitants, they are nutrients for algae and plants. This project harnesses components found in highly concentrated wastewaters to feed microalgae, which grow especially quickly by transforming ammonium and phosphates into proteins and other organic matter. +The alarming rate of biodiversity loss and ecosystem transitions make it clear that new strategies are required to sustain functioning of the coupled ecological-societal system. Existing space data archives and data streams from the ESA Sentinels, offer unprecedented opportunities to provide rapid, high quality indicators necessary for informed management of key ecosystem services. Yet, it remains largely unclear how space and ground-based observations can be optimally integrated to generate products required by end user communities (Secretariat of the Convention on Biological Diversity, 2014). By fusing extensive expertise on optical and radar remote sensing, ground data on ecosystem state and function, “big data” scientists, and active participation of user groups, BACI will advance this integration. BACI will translate space data to new variables (not directly observable from space) that encode ecosystem functional properties and status metrics. This will empower concepts of “essential biodiversity variables”. Advanced machine learning methods will be employed to reveal new and fundamental relationships between space observations and ecosystem status. BACI will incorporate a wide range of original data and downstream data products specifically targeting needs for early-warning systems, including a novel “Biosphere-Atmosphere Change Index”. We will prioritize selected key European and African regions now undergoing massive societal-ecological transformations, offering perspective towards operational assessments. A formal attribution framework will disentangle climate-induced ecosystem changes and socioeconomic/ecological transformation processes. Overall, BACI will advance usage of European space data to monitor relevant vegetation traits, status, and ecosystem functioning. By capitalizing on existing datasets, we will prototype new algorithms to rapidly implement these metrics and thus space-to-ground integration of the new ESA Sentinels. +Industrial symbiosis promotes sharing of physical resources (energy, water, residues and recycled materials, etc.) between different industrial processes, increasing business opportunities and creating new jobs while reducing environmental impacts. Neither self-organization nor the few government co-ordinated mechanisms have delivered mass implementation of Industrial Symbiosis. Given the great potential for triple-bottom line benefits this failure must be understood and addressed. SCALER aims to massively increase the implementation of industrial symbiosis, by developing mechanisms to retain the embedded value of European resources, thus, enabling the circular economy to achieve higher resource efficiency through systemic innovations led by intensified industrial symbiosis initiatives and enhanced by cross-sectorial collaboration and, to support the development of a roadmap to improve the adoption of industrial symbiosis in the European process industry at regional / national / European level. SCALER will use new and advanced practices in identifying value opportunities, use new methods to create a larger market for available resources, and use new methods to measure and manage the implementation and sustaining of new relationships. SCALER brings together qualitative and quantitative tools and methods to support self-organised initiatives on industrial symbiosis and to enhance facilitation processes and coordination actions. The creation of new spaces for interaction, collaboration and cooperation and the engagement of a broader set of stakeholders are crucial elements of the multiplier effect in industrial symbiosis implementation. SCALER provides a comprehensive solution for understanding, assessing and intensifying the potential of industrial symbiosis in Europe. +Oil and gas is continuously leaking from offshore deepwater infrastructure. Up to 1 million tonnes of oil are lost from deepwater drilling leaks each year, with 601 oil and gas releases reported in the North Sea in 2015 alone, up 14.5% on the previous years. Current leak detection technologies suffer from high false positives, high cost, lack of continuous monitoring and safety risks, meaning the majority of leaks are not detected by equipment. To address this major environmental and economic problem, we have developed STREAM, a unique technology which uses subtle changes in the speed of sound to detect contaminants in seawater. We have recently completed a funded project to technically prove our concept at TRL6. +The interest for renewable energies has exponentially risen in the last few years. Several factors have contributed to this growth, highlighting the increase of the energy demand, the political instability of many countries that produce fossil fuels, the high fluctuation of oil prices, the countries’ energy dependence and the concern generated by the environmental impact produced by the traditional sources of energy. This fact has boosted the development of numerous renewable energies and has promoted the establishment of ambitious objectives by the main world organisations, like the one set by the European Commission of covering 20% of the energy demand with renewable energies by 2020. By using current marine energy harnessing technology, it would be possible to provide up to 13% of the global energy, by extracting 2.200 TWh/year. +Materiko is an Italian company specialising in the manufacture of revolutionary artificial high quality textiles. Due to the flexibility, and high-quality afforded by genuine leather, compared to conventional textiles, it has been used for centuries as material in several industries. However, leather is prone to scratching, water damage and UV damage which can limit its uses, particularly in external applications. Furthermore, the way in which leather is produced presents a huge environmental problem. The tanning process for genuine leather uses on average 360 L of water per m2 and over 50 L of that needs to be processing by wastewater treatment plants for chromium waste considered to be hugely toxic by the EU. To alleviate these environmental problems as well as consumer movement towards non-animal origin products a range of artificial leathers have been developed such as PVC and polyurethane (PU) based faux leathers and natural plant based options. PVC and PU based artificial leather have their own environmental problems including similarly high water usage, use of toxic chemicals and poor recyclability. Both plastic based and plant based leather alternatives have durability and quality issues when replicating genuine leather. The need for a high-quality, more durable, weather-proof leather like material which eliminates animal cruelty, water usage and toxic wastage associated with the genuine leather industry is clear and one for which Materiko have developed an innovative solution. Our EcoLeather is a novel material manufactured using an innovative semi-automatic manufacturing technique which produces a water and chemical free leather alternative which improves upon the physical properties of genuine, such as durability, scratch and weather resistance. With the high-end leather goods market worth an estimated €45 bn globally there is a huge demand for a leather alternative with improved physical properties. +The main goal of the proposed project URBANFLUXES (URBan ANthrpogenic heat FLUX from Earth observation Satellites) is to investigate the potential of Earth Observation (EO) to retrieve anthropogenic heat fluxes. The main research question addresses whether EO is able to provide reliable estimates of anthropogenic heat flux spatiotemporal distribution, at local and city scales. URBANFLUXES will investigate the potential of EO to retrieve the anthropogenic heat flux, as a key component in the urban energy budget and by developing a method capable of deriving it from space. The objective is to develop a method that could be used operationally in the near future, when observations with adequate temporal resolution become available. URBANFLUXES EO-based approach will be easily transferable to any urban area and capable of providing anthropogenic heat flux benchmark data for different applications, including climate models to assess the implication of the anthropogenic heat on the Earth system; building energy models to characterize buildings-to-atmosphere/soil/water heat exchange pathways; and decision support systems for urban sustainable planning and mapping of emissions related to energy consumption. URBANFLUXES is therefore expected to prepare the ground for further innovative exploitation of European space data in scientific activities (Earth system modelling and climate change studies in cities) and future and emerging applications (sustainable urban planning) by exploiting the improved data quality, coverage and revisit times of the Copernicus Sentinels data. The Copernicus observations have the potential to reveal novel scientific insights, related to monitoring the anthropogenic heat flux in cities, at both local and regional scales, generating new EO opportunities. The URBANFLUXES products will therefore support both sustainable planning strategies to improve the quality of life in cities and Earth system models to provide more robust climate simulations. +The goals of the UPWARDS project match the topics, challenges and scope of the Compet-8-2014 call. UPWARDS has as its overarching objective the revision and exploitation of data from the European Mars Express (MEx) mission as well as other Martian missions using a synergistic combination of state-of-the-art atmospheric/subsurface models and novel retrieval tools. UPWARDS will 1) address major open science questions which require an integrated understanding of the Mars coupled system from the subsurface to the upper atmosphere; 2) prepare for ExoMars 2016 Trace Gas Orbiter data analysis and exploitation; and 3) deliver enhanced scientific context and datasets for ExoMars 2018 Rover operations and future missions. +The EU faces huge challenges in food security, sustainable agriculture, marine and maritime and inland water management. Blue Growth solutions can play an important role in meeting these challenges and unlock the potential of oceans and inland water for the benefit of European competitiveness. Blue Growth is identified as a key emerging industry to be supported via inter cluster collaboration as well as a key driver for the EU economy. +Sustainability assessment methods are needed to support sustainable technology development and to evaluate the impacts of existing solutions, products and technologies. While there are aspects and indicators that are common to all process industries, sector specific tools are required to address the sector specific features in a fair and transparent way. +Heat4Cool proposes an innovative, efficient and cost-effective solution to optimize the integration of a set of rehabilitation systems in order to meet the net-zero energy standards. The project develops, integrates and demonstrates an easy to install and highly energy efficient solution for building retrofitting that begins from the Heat4Cool advanced decision-making tool (which addresses the building and district characteristics) and leads to the optimal solution combining (1) gas and solar thermally driven adsorption heat pumps, which permits the full integration with existing natural gas boilers to ensure efficient use of current equipment , (2) solar PV assisted DC powered heat pump connected to an advanced modular PCM heat and cold storage system, and (3) energy recovery from sewage water with high performance heat exchangers. +Satellite remote sensing has been evolved into a powerful tool for global monitoring of surface waters. Earth Observations (EO) and remote sensing are widely used for quantifying the physical parameters of reservoirs as well as for retrieving selected water constituents concentrations. +A Bottom hole assembly (BHA) is a series of components that form the lower part of the drill string, extending from the bit to the drill pipe. During oil and gas exploration the BHA can become stuck/jammed due to poor cleaning of the hole and subsequent build-up of cuttings. With direction drilling programmes now exceeding 10km, problems are becoming more common and expensive as oil exploration companies look to access difficult to extract oil reserves from reservoirs which until recently were not commercially viable, particularly in deep water. Methods of disconnecting the BHA need to be activated in highly deviated or horizontal wells where wireline systems cannot easily be employed. In development and exploration drilling, the costs when the BHA becomes stuck down the hole are considerable. +Lactips is an innovative company located in France, founded in 2014. Lactips develops a disruptive thermoplastic material, water-soluble at room temperature and below, for uses in water-soluble or edible packaging. This material is unique on a worldwide scale. +Trawling is a fishing method that involves pulling a net through the water behind a vessel and trawl doors are the steel plates attached to the fishing net to keep it open during fishing. Conventional square shaped trawl doors consume at least one quarter of vessel’s energy cost due to their inadequate design. Conventional doors not only consume large fossil fuel (which increases carbon footprint, air and sea pollution) but also harms the seabed, marine habitats and biodiversity (especially bottom trawling which catches the fish at or close to the seafloor). +The progressive ageing of the population is becoming a major problem for society, who sees how ageing comes accompanied by crucial challenges that constraint our healthcare systems. Dependency is one of these challenges, adopting today the form of over 3 million Europeans unable to live independently due to ageing, disease, accidents or long term disability. These individuals rely and depend on caregivers to accomplish daily activities, being hygiene one of the most critical steps. Fulfilling hygiene tasks becomes specially challenging and time-consuming for the saturated personnel at hospitals, clinics or elderly homes, who need to be extra careful with these patients at higher risk of infection. The complexity of the current processes to wash or bathe bedbound patients (which involves transferring the patient out of bed) enters in conflict with the workload pressure faced by caregivers (which limits the time available for each patient). In response, we have developed and validated Aquabuddy-CARE (AQB), a miniaturized and portable shower system that enables patients to undertake hygiene tasks in bed, rapidly and in a dignified manner. The combination of advanced materials, sustainable production process and proprietary water flow system guarantees the efficiency of the technology concerning water consumption and prevention of contamination. After completing the validation at the pilot scale, this project aims to finalise the industrialization and field-testing of AQB. The Feasibility Study planned in Phase 1 will help us secure the project from all technical, financial and commercial standpoints. Once in the market, AQB will bring significant benefits for caregivers and patients worldwide, helping to alleviate the raising impact of ageing and disability while improving their life quality. In turn, AQB will boost our growth, expecting to hire 12 new people in 5 years, gain €11.2 million in profits and reach a ROI of 4.6 per euro invested in the project. +All ships produce oily bilge water. The MARPOL Convention requires vessels to have oily water separators and prohibits the discharge of water with more than 15 ppm oil content. +Shortage of fresh water has become one of the major challenges for societies all over the world. Water desalination offers an opportunity to significantly increase the freshwater supply for drinking, industrial use and irrigation. All current desalination technologies require significant electrical or thermal energy, with today's Reverse Osmosis (RO) desalination units consuming electric energy of at least 3 kWh/m3 – in extensive tests about ten years ago, the Affordable Desalination Collaboration (ADC) in California measured 1.6 kWh/m3 for RO power consumption on the best commercially available membranes, and total plant energy about twice as high. +The project aims to provide and commercialize a self-adjusting bead forming process able to control the quality of the sealing material in car manufacturing industry. LICORNE (LIssage de COrdons Robotisé Novateur Expert) is an innovative automatic vacuum forming solution able to control and adjust itself in front of the variability. The robotized forming operations are repeatable and 100% certified. They will use a standard sealing material and be used on forming operations on all parts of the car. +BUSINESS MODEL: QuantumWise (QW) has developed a new cross-disciplinary platform – Virtual NanoLab (VNL) – which integrates materials/nanotechnology simulation simulation engines through a plug-in mechanism. VNL is an open platform which can be extended by 3rd parties (SMEs and academic groups) like Adobe Photoshop based on plug-in business model. +The Agro Highway provides a new, innovative mode of transport for perishable food liquids that will enable a disruptive breakthrough for transport and agriculture. The Agro Highway will develop, demonstrate and validate an aseptic, temperature controlled, quality monitoring, self-loading cargo system that will stimulate a shift in transport from road to water. The Agro Highway consortium aims to: +Water management requires massive, low-cost monitoring means coping with differentiated and evolving requirements. However, the majority of multifunctional water sensors only supports predefined goals hindering interoperability, with a high cost, impeding large scale deployments. +Activated carbon is manufactured overseas (30% of production occurs in CHINA). As an example, in 2016, 12% of worldwide AC demand (0.23 million of tons) corresponded to Western Europe . A Europe import about 80% of their internal consumption of AC. PORTABLECRAC provides a successful business case to reduce overseas imports with negative competitive and environmental impacts in key industries in Europe. Furthermore, great exploitation and replication opportunities for circular-local economy development, at business and environmental perspectives, will be pursued and exploitation path assessed as key implementation task after feasibility analysis is completed. However, due to continuous use, EXHAUSTION of AC filters is a common issue with the consequent high cost in producing virgin filters again. Indeed, there is a side problem related to the manipulation and management of exhausted AC that has to be considered as highly contaminant waste and can vary at regional-national level. Accordingly, the viability of AC use at industrial level roots in the regeneration and reactivation of exhausted AC. +Earth observation (EO) satellites yield a wealth of data for scientific, operational and commercial exploitation. However, the redistribution of environmental mass is not yet part of the EO data products to date. These observations, derived from the Gravity Recovery and Climate Experiment (GRACE) mission and in future by GRACE-FO (Follow-on), deliver fundamental insights into the global water cycle. Changes in continental water storage control the regional water budget and can, in extreme cases, result in floods and droughts that often claim a high toll on infrastructure, economy and human lives. The aim of this proposal is to demonstrate that mass redistribution products open the door for innovative approaches to flood and drought monitoring and forecast. +The objective of the SPOTVIEW project is to develop and demonstrate innovative, sustainable and efficient processes and technology components, in order to optimize the use of natural resources, especially water, in three industrial sectors (Dairy, Pulp and Paper and Steel) contributing to 44% of industrial water usage in EU. This resource optimization (including water, energy, raw materials and additives) is a key issue to maintain production competitiveness and sustainability. A total of 14 existing and new technologies will be assessed during the project, including solid/liquid separation, ultrafiltration, deionization, biological treatment, disinfection and chemical heat pump. The technology components will be assessed in simulated or operational environment for 9 new water management practices in the three industrial sectors. Up to 7 selected technologies demonstrators are planned in real industrial environment. The implemented process and technology will be evaluated in terms of environmental impacts and benefits, generated by achieving the SPOTVIEW targets (20% to 90% reduction of water usage, wastewater emissions, chemicals and energy use). The SPOTVIEW consortium covers the whole value chain, from technology development, assessment, supply and industrial applications in each targeted sector. Economic exploitation of the proposed technologies is pursued through a well described business case scenario and market penetration strategy. The market opportunities for future services and technology products beyond the SPOTVIEW project will generate up to 2800 new equipment and 7000 new jobs in Europe. The expected gains for the industrial sectors generated by the recovery of by-products and by energy, chemicals and additives savings represent annually 1.53b€ for Europe. The generated production capacity increase by companies has been estimated at 22.8b€. Dissemination and training activities are planned to maximize the impact of the project. +ACIES BIO, a SME with a decade of profound experience and market understanding, has developed an innovative and disruptive technology already recognized within SME INST Phase 1 to address a major unsolved high-cost environmental challenge for the world’s dairy industry: acid waste whey. Around 200 million tons of waste whey is produced annually, of which nearly 50% goes unprocessed and ends up clogging the wastewater treatment stations or, in less regulated environments, is released into streams thus heavily polluting the environment. +The business of our company is agricultural trading. We realized that our sector lacks a reliable, fast, on-site detection method of Mycotoxins, in particular of deoxynivalenol (DON) in wheat grains, which is one of the major threats to the food and feed sector. We aim to commercialize a Mycotoxin (DON toxin) sensor unit, which is easy to use on-site, provides results with more than 90% accuracy compared to conventional laboratory HPLC method in the whole measurement range, while keeping its selling price low (at 10.000€). Our pilot technological tests and preliminary business planning envisaged a huge business potential of our project. In this phase 1 project, we plan to carry out technological feasibility study, market and risk assessment, freedom to operate study as well as to develop a phase 2 proposal and improve our business plan. +BIOCOMPLACK is a biobased, biodegradable and compostable food packaging with enhances barrier properties. BIOCOMPLACK is a food biopackaging with three main points of innovation: the use of cellulose nanocrystals (CNCs), the multilayer structure and the PLA biopolymer reinforced with organoclays which contain natural food preservatives. These three innovations will enhance the barrier properties to oxygen (more than 100 times compared with common biopackaging) and water vapour as well as will improve the shelf-life of food. BIOCOMPLACK is an alternative to common bio-packaging products that enhances 300% the shelf-life of food. +MATChING goal is the reduction of cooling water demand in the energy sector through innovative technological solutions, to be demonstrated in thermal and geothermal power plants. The project targets include an overall saving of water withdrawal of 30% in thermal power generation, and a decrease of evaporative losses up to 15% in geothermal sector. The use of advanced and nano-technology based materials will be leveraged to make economically affordable water saving in power plants and pave the way to the market uptake. All technological areas of plant cooling systems will be affected: cooling tower, steam condenser, cooling water circuit and water conditioning. The use of alternative cooling fluids will be investigated to develop advanced hybrid cooling towers for geothermal high temperature power plants, and hybrid cooled binary cycles for low temperature geothermal fields, combining dry/wet cooling, and closed loop groundwater cooling. To increase available effective water supply at reasonable costs, alternative water sources will be exploited: different membrane based technologies will be used to re-cycle or re-use municipal, process and blow down waters. To improve cooling equipment robustness advanced materials and coatings for cooling tower and condensers will be investigated, allowing increasing concentration cycles or directly using aggressive fluids. Demonstration will take place in partner-owned industrial sites, operating pilot plants in intended environment and/or in demo scale, guaranteeing the achievement of TRL 6 for all the technologies. The demonstration activities and the partnership composition ensures the validation of suitable business models and the finalization of business plans, guaranteeing the technological transfer from industry to market, increasing competitiveness at European level, and impacting on water use in power generation sector. +The LARA system, the main outcome of the project is a mobile device for utility field workers. The hand-held device integrates different technologies such as: positioning and sensors (GNSS), Augmented Reality (AR), GIS, geodatabases, etc. In practise, this device will guide the field workers in underground utilities to ‘see’ what happening underworld, like an “x-ray image” of the underground infrastructure. The system is using AR interfaces to render the complex 3D models of the underground utilities infrastructure such as water, gas, electricity, etc. in an approach that is easily understandable and useful during field work. The 3D information is acquired from 3D GIS geodatabases. +BERTHA-G stands for “Better enzymes than gas”. Our first-of-its-class system enables independence from centralized supply of fossil fuel (i.e. natural gas, oil) for residential heating purposes (15’000 kWh therm. p.a). +"With the accelerating increase of cloud-based services, the advent of the Internet of Things (IoT) and big data the IT sector is running into a fundamental bottleneck. Indeed, the demand for upscaling the computational power requires even denser server farms, whose thermal management of dissipated heat with conventional air-based cooling is both becoming technically unfeasible, environmentally questionable and economically unbearable. Thus, power/cooling is currently the #1 Data Centre (DC) design criteria. +GreenLight® is a ground-breaking new instrument / kit consumable platform to measure microbiological contamination, developed by international experts in the field of fluorescent oxygen sensing technology. This easy to use, reagent-free detection system is so sensitive, that a single bacteria cell can be measured in hours; rather than days using current agar plate methods. GreenLight® is the first system to market that can be used end to end through the supply chain (from farm to fork). The unique sensor chemistry in the APCheck™ sensor vial, which is the core consumable of every GreenLight® assay, allows contamination to be detected in any food or beverage product. +The use of renewable resources in the process industries is socially desirable and a market pull for products has started to develop in recent years, but renewable products have to compete with identical or similar-in-application products based on fossil raw materials in terms of quality and production cost. One of the main reasons for currently higher production costs of products based on renewable resources is that the production routes involve processing complex dilute aqueous solutions from which the desired products have to be separated during downstream processing. Consequently, a major challenge the process industry is facing, is the development of cost- and energy-efficient water removal and product-recovery techniques. Today downstream processes for products based on renewable resources are often developed using methods from the petrochemical area being insufficiently adapted to the new applications. A re-thinking of downstream process development and the development of suitable methodologies for a fast-track development of tailored downstream processes as well as the optimisation of separation technologies are urgently needed in order to unlock the potential of the renewable-based product market for the European process industry. +Dirt on solar panels causes losses of more than €40bn p.a. and over 100Mtonnes of CO2 emission. Cleaning is expensive (up to €100/m2 depending on accessibility) and wastes water. Current self-cleaning coatings suffer from short lifetime (2-3 years), poor transparency, and high cost (over €20/m2). They are usually not cost-effective, are not widely used, and losses are accepted as part of the operation of the plant. The objective of this action is to bring to market a new product, EverClean, which will provide, for the first time, a transparent, durable, cost-effective and permanent self-cleaning solution for solar panels. This patented coating technology uses multi-functionalised silica nano-particles bonded strongly to the coating polymer matrix to provide a highly transparent, low cost, durable and robust self-cleaning coating. Target markets are utility scale solar and the rapidly growing (18% CAGR €26bn by 2022) Building Integrated Photovoltaics (BIPV) markets. +SOLUS is a trans-disciplinary 48-month project bringing together 9 partners: industries (4), academic and clinical institutions from 5 countries (engineers, physicists and radiologists) representing cutting-edge expertise in their fields, to develop an innovative non-invasive, point-of-care, low-cost, easy-to-operate, multi-modal imaging system (diffuse optics and ultrasounds/shear wave elastography) for high-specificity diagnosis of breast cancer, the most common female cancer in Europe. Mammographic screening is effective in reducing mortality, however the 10-year cumulative false-positive risk is 50-60%, leading to needless additional invasive procedures (e.g. biopsy). The project addresses the unmet clinical need for higher specificity in breast cancer imaging following screening by fully combining photonics with non-photonics techniques, developing and clinically validating innovative and previously unthinkable photonics concepts and components: time-domain small source-detector distance optical tomography, miniaturized picosecond pulsed laser sources, high-dynamic-range time-gated single-photons detectors to achieve unprecedented sensitivity and depth penetration. For the first time, this allows a comprehensive quantitative characterization of breast tissue including composition (water, lipids, collagen), functional blood parameters, morphologic information and mechanical parameters (stiffness). This innovative multi-parametric characterization will significantly improve the specificity of breast screening, with great impact on the quality of life of millions of European women every year, and huge savings for the healthcare systems. The strong involvement of leading industrial players at all levels in the value chain will push the European innovation process and make a significant contribution to ensuring Europe’s industrial leadership in the biophotonics healthcare market, while addressing one of the largest societal challenges in health and well-being. +Polydome is an innovative, sustainable, closed-loop polyculture greenhouse system intended to solve the problem of long distance food sourcing. +The project POLYWOOD (Combining wood and polymers to produce a translucent, reinforced and ecological material) is mono-partner, lead by French startup WOODOO, and responds to the call topic “Coordination and support actions, H2020 SME Innovation Associate”. WOODOO has developed a breakthrough patented technology, focusing on wood modification at the cellular and molecular scale. It starts from native wood, removing lignin and impregnating the cellulosis matrix with selected monomers, polymerizing in situ to create much stronger bonds between the wood native fibers. The result is a translucent wood, three times stiffer than natural wood, much more durable, water and fire resistant. +Everything is digital today in the creative industries value network. The production process, often the products, the supply chains, and the communication with end users. +The EU-28 meat processing industry generates an annual turnover of €160b, with 50% corresponding to SMEs. Over recent years, the production of sliced meat products has grown steadily, driven by increased consumer demand for ready-to-eat products, including cooked and dry-cured ham. Despite significant efforts made by processors to optimize the process, around 10% of meat is wasted during slicing, which amounts to t72,000/year of meat wasted in EU slicing lines. +PROTECT aims to introduce to the market One step antimicrobial finish processes for polymeric materials used in i) specialty textiles for public areas and hospitals, ii) water treatment membranes, and iii) implantable medical devices. Compared to main existing manufacturing routes, the proposed one-step coating technologies are simple, fast, and reproducible. For this, PROTECT uses as a starting point four existing pilot lines emanated from high successful FP7 projects SONO, NOVO and BioElectricSurface. PROTECT will upgrade the nanocoating One step process platform comprising: two roll to roll (R2R) pilots (sonochemical and spray coating) for functional textiles production, a R2R thermo-embedding pilot for antibacterial/biofilm preventing water treatment membranes, and a batch sonochemical pilot for antibacterial/antibiofilm/biocompatible medical devices. This platform will cover a wide range of applications due to their specific characteristics by the following objectives: +Soil is a vital – though often neglected – tool for increasing the resilience and security of food production, as recognized by the UN’s declaration of 2015 as the International Year of Soils; improving it can reduce erosion and enhance drought tolerance, crop yields, water and nutrient efficiency, and long-term land fertility. +Residual Barrier Technology Ltd. is an SME set up with the aim of developing disruptive, green sanitation products while delivering higher performance than state of the art solutions and thus achieve impact globally. Disinfectants are relied on as the last line of defense against ever-evolving bacteria and viruses – but due to current chemistry they come with inherent disadvantages including, toxic/mutagenic ingredient use and offers no residual protection. Methods application such as spraying, fogging and fumigation are time and labour intensive and provide inconsistent and incomplete coverage. We have developed VIRIDIS a patent pending non-toxic, non-mutagenic platform disinfectant that is a breakthrough in the fight to effectively eradicate bacterial pathogens, spoilage organisms, and viruses. However, VIRIDIS MIST does not stop there – once deposited on a surface the advanced micelles holding the active ingredients crystallise to create a protective residual barrier that has been independently proven to continue to kill bacteria for days even when dry - preventing them from rebuilding or mutating to form a resistance. We currently work with clients in the food processing and agriculture market to design and fit bespoke large scale residual misting systems for their facilities operating on a service charge model. However, there is a considerable expense and time involved in installing the network of fixed pipes and nozzles at their sites – making it cost prohibitive in small to medium sites and impossible to implement in haulage and shipping contexts. VIRIDIS MIST will service this much larger market micromedium scale market through the use of autonomous mobile apparatus. We are requesting funding for the development and production of 24 demonstrator application (8 x 3 different sizes) systems to gain customer confidence among our suppliers and end users. +Water is one of the basic and essential human needs for almost all economic activities. The water management sector is facing global challenges that require multi-sector solutions. Small hydro energy plays a key role in power generation worldwide, but installing conventional turbines at a micro level is currently not very attractive because of the large initial investment and their low efficiency. Our “regenerative variable speed control system” works at variable speed. The installation time is between 1 and 2 days, reducing civil works by 80%. The pay back for the final clients (Mini-hydroelectric plants, Aquaculture Companies, Wastewater treatment plants) is 4 years. Our overall goal is to improve, integrate, implement and certify our current product. The final product will be capable of generating the maximum amount of electricity with a constant efficiency (75%) and will be further used as demonstrator plant for our customers worldwide. We have already completed the following feasibility actions: technological feasibility, work plan for Phase II and an assessment of the market, business model, risks, IP and created a Business Plan. By 2020, +Blood is a common by-product of the meat industry, which is obtained in large volumes especially in industrial slaughterhouses. Approximately 1,452 million pigs were processed worldwide for their meat in 2013. The annual available blood supply exceeds 4.35 million tonnes worldwide. Taking into account a typical protein content around 18%, 783k tonnes of protein could be produced worldwide. +Any object submerged in water is subject to fouling, such as boats, oil drilling platforms and aquaculture equipment. To prevent fouling, companies who own submerged assets use antifouling paints (i.e. the use of antifouling paints is estimated to prevent 25% of fuel consumption of the world fleet). +The TIME SCALE project will bring closed regenerative life support system (CRLSS) to the next level by further development of the European Modular Cultivation System (EMCS). The EMCS has been successfully operated on the International Space Station (ISS) for 7 years with rotors allowing scientific research under Moon and Mars gravity exposures in addition to microgravity conditions. The EMCS modular design provides the possibility to replace the individual subsystems including the entire rotor system. +• The need arises from the greater use of PE pipes with a lower capital, installation, operation & maintenance cost and corrosion free during service but is limited through not having a suitable NDT technique to check the integrity of the welded joints between pipes. +The Copernicus program is today at a cornerstone: +Agro-industrial companies face the necessity of acquiring more information and control over their crops and the operations they perform in order to produce them. The challenge lies in reducing the hydric and energy resources they use with the objective of increasing their competitiveness and reducing the impact on the environment. Under the brand name of bynse, our SME cubenube (www.cubenube.com) has developed the first big data solution for agriculture in the world. bynse allows managers and producers to analyse the current and future needs of their crops in real time, using an innovative and inexpensive microclimatic sensing system called bynsebox for collecting field data, and a cloud information service called bynsecloud for processing and displaying the information to the users. This data is intersected with data from weather forecasts and vegetative growth tasks (pruning, seeding, etc), and a number of recommendations are generated, leading to a 30% reduction in energy and water consumption, and up to 40% reduction in the use and subsequent cost of phytosanitary products. +Currently about 47% of the total energy consumption in Europe is needed for space heating and water heating, also considering the industrial heat/process heat. The biggest potential to reduce CO2 emissions significantly is within the heating sector. The ambitious objectives of the European and the worldwide climate and energy policy can only succeed, if the increasing heat and cold supply is considered. The technology of the near-surface geothermal energy offers good prospects for big energy savings and the reduction of greenhouse emissions and also ensures an ideal room climate in summer and winter within buildings. Due to the complex installation, connection and function, existing system solutions (especially in the near-surface geothermal energy) could not establish at the market yet. Another unsolved problem is the large space requirement of the heat source system and the unfavorable cost/benefit relation. Therefore Holzammer Kunststofftechnik GmbH and GeoCollect GmbH developed an innovative geothermal heat absorber system called “GeoCollector”. Project output is the ability to produce the current Prototype GeoCollectors (TRL 6/7) in a way meeting the identified market requirements: +Greenhouses in Europe and Mediterranean produce 30% of the EU’s fruits and vegetables. Growing irrigation water resource pressures are driving greenhouse growers to use of more efficient irrigation techniques, and of non-potable water sources. These lead to a strong need for irrigation water treatment (IWT), to eliminate water-borne plant and human pathogens, mitigate clogging by bio-foul and secure reliable and uniform irrigation, and improve water oxygenation. Our goal is to bring to market a novel irrigation water treatment (IWT) solution based on our technology breakthroughs in on-site generation of hydrogen peroxide (H2O2). Our autonomous H2O2 generation device (HPGen) enables the safe, cost-effective and sustainable on-site generation of hydrogen peroxide, with only water, air and electricity as input. Hydrogen peroxide is a potent but eco-friendly disinfection agent, yet its use in IWT is very limited due the costs, risks and complexities of its present-day supply chain. HPGen will disrupt today’s H2O2 supply chain, enabling growers to reap the benefits of its use in IWT, substantially decreasing IWT and irrigation line maintenance costs, eliminating use of toxic-chemicals in IWT, improving farm safety, and increasing crop yields. HPGen will provide farmers with a positive economic impact of €4k-€5k per hectare per annum, while enhancing agriculture sustainability and reducing environmental impact. Technology breakthrough was made at the Danish Technical University 5 years ago, and a commercialization path was launched 2 years ago by HPNow ApS, a Danish SME. The company has since been highly successful in scaling up its technology, while attracting strong commercial partners, including global leaders in agriculture irrigation and in bulk hydrogen peroxide production, which are actively supporting this project. This project will initiate with pilot and customer trials of a full-scale version (TRL 6), and will end with commercial launch of HPGen (TRL 9). +Gili Ocean Technologies aims to become the leading off-shore (Open Ocean) aquaculture company. This will be achieved through the operation of fish farms as well as through the delivery of turn-key projects for other fish farmers based on our extensive off-shore fish farming expertise and advanced technologies. +The offshore wind market is a young and rapidly growing market, whose current project pipeline for 2025/30 would equal nearly 80 nuclear plants, mostly in Europe. The next decade and beyond may average 1,000 offshore towers/year worldwide, with an overall investment volume around 15-20.000 M€/year. +RIVER-POWER is a disruptive technology able to efficiently convert the water flow kinetics energy in electricity thanks to a turbine innovative design derived from the wind power technology. The new technology enlarges the hydropower potentialities, being able to exploit the zero-head water flows with mini-micro applications (nominal power < 1 MW) and thus allowing the exploitation of new electricity production sources. +The productivity in agriculture has improved enormously for the last 50 years. However, the increased yield comes at a cost. The fields producing our food are sprayed throughout the seasons with herbicides, fungicides and insecticides. We are facing major problems with resistant weeds and pesticide residues in food, soil and water. Farming needs to become more sustainable. +The business project relates to the development of an innovative product-service offer that intends to revolutionise the hydronic market. +Customem Ltd is a company founded in 2014 with the long term vision to harness nature’s capacity to make biomaterials to promote human health in alignment with sustainable development goals.A next generation nanomedia that can be tailored to capture and recycle specific micropollutants in contaminated industrial waste dischargeLack of access to clean water is predicted to affect 47% of the world’s population by 2030. Contamination of water supplies by micropollutants such as metal ions, pesticides and pharmaceuticals is a major contributor to this water stress. These pollutants are released by industrial processes in the textile and manufacturing industries. Existing water treatment removes 99.96% of contaminants, but does not remove the 0.04% of micropollutants. Although the remaining contaminants seem small, they are a major problem as they are exceptionally difficult to capture but also highly toxic to humans and animals. CustoMem have developed a customisable selective nanocellulose media called CustoMem Granular Media (CGM) that is bioengineered to capture and remove all micropollutants including the 0.04% that cannot currently be removed.Customers benefit from a simple, low cost, low energy solution that is low maintenance. It allows removal of all micropollutants resulting in clean water supplies. The company is headquartered in the Imperial College Incubator UK and employ 5 full time employees and multiple subcontractors. The company is currently in talks with companies in the EU who have shown an active interest in the project. +We are RAINMAKER, a Dutch SME specialized in providing sustainable and disruptive solutions to combat water scarcity. We have developed W2W –water to water- the first water desalination system fully off-grid and fully powered by renewable energies (wind & solar). +Polibiotech, an SME from Italy, has developed a patented advanced manufacturing process that successfully formulates any chemical compound quicker, at a lower cost and resource-efficiently. Current chemicals production procedures of wet and dry granulation have difficulties with universality, waste ingredients and energy consumption. Nutraceutical formulation requires repetitive research and testing to prove viability and is an extremely inefficient, time-consuming process (lasting up to several months). The Aerodynamic Granulation System (AGS) is a new process of dry granulation that revolutionises the formulation process and successfully manufactures any drug. The system uses a gas flow to optimise particle transportation and granule separation. The system is eco-sustainable as less raw materials are input and waste can be recycled through the use of a continuous process in a closed system. The AGS method reduces formulation time from several months to one day. At peak performance the AGS could produce more than one new formulation per week and a basic machine would have capacity to produce 1 tonne a day. The system concept will initially be applied to the nutraceutical markets; however, any product that requires the combination of chemicals to form a homogeneous compound can utilize this technique including the pharmaceutical market. An advanced prototype AGS has been constructed and trialled in an operational environment and a variety of products have been formulated. Within the overall project Polibiotech intend to: construct a second pilot plant in Italy; engineer a series of online quality control tests; validate the full scale AGS line for the production of nutraceutical compounds and gain certification for manufacturing roll out within the EU. +Efficient municipal wastewater treatment produces vast amounts of sewage sludge. The latest data show a yearly production of 9.637 thousands of tons in Europe. Sludge treatment issues are often neglected in comparison with water-related parameters which results in serious technical difficulties and highly expensive disposal methods. An energy efficient, environmentally sound and economically viable process for sludge disposal and reuse of valuable resources e.g. phosphorus hardly exists. +SINANN will leverage the identified capability of SonarSim’s high-performance Computational Ocean Acoustics framework to unlock a tangible 10-15% efficiency improvement in coastal zone seabed survey operations. The resulting productivity step change could potentially double the profit margin of a typical survey vessel, an expensive capital investment costing a minimum of €10 million per annum to operate. A significant portion of operational survey time is wasted collecting redundant seabed data and correcting routine errors caused by the inherent deficiencies in traditional manual based vessel path planning and swath coverage prediction processes. SINANN enables end users to identify the optimal fit for purpose survey configuration pre-survey, predict expected seabed survey performance analytics, and execute the optimal survey strategy in the field through smart high performance computerised solutions. Target end users are blue chip survey organisations involved in National charting, offshore oil and gas, marine renewable energy, and subsea telecoms. +Today the application of fertilisers to agricultural crops is mainly based on calculations, estimations and recommendations and not on analyses of the actual demand of soil and plants. The resulting over-fertilisation has substantial disadvantages: Farmers suffer from reduced yields and unnecessary expenses for fertilisers, groundwater is polluted, surface water bodies are eutrophicated, greenhouse gas is emitted from soils and finite natural fertiliser resources are depleted. It is estimated that up to 35 % of the applied fertiliser could be saved if a method for the quick and simple determination of the fertiliser demand existed. +The CEASELESS project will demonstrate how the new Sentinel measurements can support the development of a coastal dimension in Copernicus by providing an unprecedented level of resolution/ accuracy/continuity with respect to present products. The retrieval and validation for restricted domains and for an enlarged set of combined variables (user oriented) will be the basis to advance the state of the art in assimilation, modelling and applications, at a level commensurate with the new Sentinel capabilities. The project will address the multiple scales coexisting in littoral areas by developing new shallow water parameterizations, introducing them into coupled model suites (wind-wave-surge-current-land discharge) and producing new standards for coastal simulations and analyses. The permanent data base, with dynamic repositories, plus the modular structure of the developed models will demonstrate the technical feasibility of a future operational Copernicus coastal service. The set of derived products will be ingested into the users’ work routines, proving the economic feasibility of the Copernicus coastal extension. The level of conflicts in squeezed coastal zones, expected to grow in the face of climate change, will, thus, benefit directly from CEASELESS, establishing tangible contributions for a wide range of economic sectors. The data repositories (accessible via a dedicated portal), regularly updated with the evolving (satellite-derived) bathymetry will facilitate the use/re-use of our high resolution results, supporting a new set of Copernicus coastal applications such as renewable energy, coastal erosion or harbour exploitation. The mutual validation of satellite data, numerical results and in-situ observations will generate reciprocal profit for enhanced competiveness of EU coastal industries where we shall also explore the suitability for cases in 3rd countries, opening new business opportunities for a coastal Copernicus. +The longer offshore distances of subsea facilities of Oil&Gas rigs are now placed further than decades ago, and inability to power the instrumentations that they require may lead to an economic loss of billions of euros. The power can be supplied through a subsea power and umbilical communication or turbo generators connected to a battery. Yet, these alternatives are very expensive and can be low efficient. The use of renewable energies set near the consumer (off-shore wind, solar or wave energy) seem to be a feasible alternative, but their availability is intermittent and present high capital and operational Costs. To solve these issues, born from the idea of Current2Current founders –experienced project managers in subsea oilfield for BP Ltd. projects, we have been working on SUBPORT project since 2007. We have developed a compact and simple tidal turbine that can work with flow from any direction, with current speeds < 0.5 m/s, and stable under any water depth and current speed. It can provide up to 20 kWh /day for up to 25 years without the need to change a battery. +Fish Flow Innovations (FFI) wants to commercialize a fish friendly tidal stream turbine that converts ocean currents into electricity. The turbine can be fixed mounted on a seabed, tethered/moored to a seabed and/or buoyant, or float on the water surface or in mid water. +"The ECO-INK project proposes a green, innovative and comprehensive solution to the great limitations of the digital printing technology within the ceramics decoration sector. The main objectives of the project are to explore new market opportunities and boost the competitiveness of METCO srl business, while addressing EU/global challenges on Climate Change and following the indications of the “Stockholm Convention on persistent organic pollutants” & the "Stimulating technologies for sustainable development: an environmental technologies action plan for the European Union": ECO-INK will promote environmentally-friendly activities as well as guarantee the safe elimination of substances, harmful to human health and the environment, as well as the reductions in their production and use, through the substitution of current solvent based ink with water based inks (WSI) for ceramic tile production. for METCO itself, with the introduction of WSI in their production chain, there will be a saving of about 240-360t of solvent each year, corresponding to save about 0,5-1M€ if the solvent substituted is naphtha and approximately 728–1,093t of CO2 emissions per year. Considering the global market the expected figure is very impressive, since it’ll be possible to save 620,000t CO2 emission per year. METCO srl foresees a 2-years investment (about 1.8M€) to complete the optimization of WSI and to setup the whole technological package. METCO then envisages a full production and commercialization of 450-1.350-2.700t ECOINK ecoformulations per Years 3-4-5. This is expected to result in a +487% ROI by 2019 and in a METCO srl growth with +45 human resources by 2021." +Packaging tapes are the most widely used pressure sensitive adhesive tapes with global production in excess of 10 billion sq. meters per year . Their primary application is corrugated carton closure. However, existing solutions for this application present 3 key constrains: +"Fish stock management in European waters is becoming increasingly important, as it is necessary to ensure the long-term sustainability of fish catch and conserve marine resources. The fish processing industry plays a key role in this strategy, being responsible for ensuring proper handling and preservation of fish products to retain its quality and to increase its shelf life in the market. Aligned with the "Blue Growth Strategy" (COM (2012) 494), Scanfisk, a Spanish company based in Zaragoza specialised in fish processing of fresh & frozen products, has developed ULTRAFISH. The project aims at improving today's processes related to handling and processing of fishery products (fresh and primary processed) by applying a green and innovative technique based on the use of ultrasound to eliminate the use of chemical additives for microbial inactivation. This safe and environmentally friendly processing technique will be implemented at different water-based stages to reduce the processing times and water waste generated in these stages in a cost-effective manner. +Global warming is one of the main environmental challenges nowadays and existing inefficiencies in the housing solutions and its manufacturing processes are one of the leading causes of it. Today the approximate number of houses globally is more than 1.5 billion and steadily growing. Construction and the use of standard houses, according to UNEP, consume around 40% of global energy, 25% of global water, 40% of global resources, and emit approximately 33% of Greenhouse gases (GHG) emissions. +Persistent organic pollutants (POPs) are organic compounds produced by human action resistant to environmental degradation and whose bioaccumulative capacity and toxicity can cause harmful health effects e.g. cancer. Hence, they have become global threats for human and environment. The most extended analytic methods used nowadays for detecting POPs are gas chromatography and/or mass spectroscopy to separate and identify them. These methods are expensive -€1,000/sample-, time-consuming -24h-, require a laborious sample preparation and a well-equipped laboratory. Consequently, there is a great demand to increase the number of water and food quality tests if available for a lower price and shorter time. +Automatic Identification System (AIS) is a VHF based system which is designated to enhance the safety of life and goods at sea by also assuring navigational and environmental improvements. The coverage of national AIS networks are limited because of many reasons (geography, weather conditions, insufficient number of stations etc.) and due to these limitations relevant authorities have difficulties to track and manage the marine traffic properly; causing safety and security weaknesses at sea which also means increased threats of accidents, illegal fishing, immigration & smuggling and water pollution. +Hydrokemos, a high tech Spanish SME, aims to demonstrate and commercialise the first fully clean equipment to purify nitrate polluted water. +Waterborne bacteria are an extremely dangerous source of infection. Water of poor quality can cause disease outbreaks (80% of gastrointestinal infectious and parasitic diseases and a third of the deaths caused by those infections, are due to the use and consumption of contaminated water) and affects human health in two ways: +In Europe, it is estimated that water distribution networks lose around 30-40% of treated water; reaching over 50% in some Eastern European countries. Typically, distribution losses (5%-50%) are much larger than production losses (2%-10%), so it is important to focus on a solution for the first ones. One million miles of pipes beneath our streets need to be replaced as some have over 100 years, which lead to potential problems such as the collapse of a pipeline or damages to nearby assets.Leakage levels can be reduced implementing leakage control programs, but these are costly (av. 1,100€/Km sewer repair) and have associated time-loss between water leak and technical assistance (2 days). Also the difficult access to pipelines can increase these costs. Water suppliers need to optimize investments on leak management in order to reduce annual leaks while minimizing operational and capital costs.The Italian SME Sipe S.r.l. is developing NOLEAK, a new smart system based on a revolutionary self-powered device (saving 50kW/h) that detects water leaks in supply mains. The system immediately alerts the water distributor or home user, and it automatically activates a self-repairing system capable of checking that the leak has been fixed. Furthermore, NOLEAK is able to alert if water is being used in an incorrect manner (e.g., a damaged tap or valve) making the final user/operator more conscious about water consumption/management. This smart system will reduce up to 30% water loss during distribution.NOLEAK has been designed to operate in continuous mode and provides daily updates of water consumption profiles. This information can be sent to water managers and/or consumers via internet, reducing managing costs (20-35%) of operators that have to manually check water consumptions every month. Our wide range of target customers includes water service providers, private water companies, individual households, water professionals, and small businesses. +In order to meet the rising water demand required by an expanding population, which has already crossed the 7 billion mark and is expected to reach 8,5 billion by 2030, and 9,7 billion in 2050, desalination of seawater is envisaged as a solution to provide a portion of the shortfall to fill the gap between supply and demand. Desalination becomes in many parts of the world, and also in Europe, a promising option to combat water stress. Nonetheless, desalination plants generate huge volumes of concentrates, also known as brines, which represent a potential hazard for marine ecosystems. Brines form a very dense hypersaline plume (heavier than normal seawater) that spreads over large areas affecting marine ecosystems, especially to seagrass meadows which are one of the most ecologically important ecosystems in coastal areas. ECOS has developed VENTURI+ a diffuser solution, with a capacity of minimizing in a 99% the environmental impact associated to brines discharges due to a potential dilution capacity 131% higher than conventional diffusers. Thus, VENTURI+ represents a technological leap towards tackling one of the most robust environmental barriers that are holding the full deployment of desalination plants. +Water and energy are highly interdependent and are both crucial to human well-being and sustainable socio-economic development. 1.1 billion people worldwide do not have access to a safe source of drinking water; 1.3 billion people lack access to electricity; 5 billion people worldwide still have no access to internet. +The needs in the water drinking water quality monitoring and treatment are related to: +Three out of four people in EU drink water from groundwater subjected to severe nitrate contamination by fertilizers and sanitary products used in intensive agriculture & farming. High levels of nitrates in drinking water put human health at risk and have been reported to threaten 26% of EU biodiversity. Current technologies do not meet the needs of small water suppliers, who must face costs derived from high energy consumption (3-7 kWh/m3), poor nitrate selectivity, residual streams and by-products, and continuous costly maintenance. 33% of suppliers in Europe are not compliant with quality standards, particularly nitrate levels. ZIRONITRO is the result of 8 years of research and development by Ofra Aqua Plants, an Israeli company with over 25 years’ experience in bioengineering and phytoremediation. Based on the concept of using nature to cleanse nature, ZIRONITRO is a constructed wetland to biologically treat groundwater by removing nitrates to obtain high-quality drinking water (98% removal), at 84% lower cost than current. ZIRONITRO’s innovation resides in the system’s nitrate removal specificity, with a design that allows low-cost operation and maintenance, along with very high rates of nitrate breakdown by bacteria. The key factor is the selection of the best combination of both bacteria and plants, along with the optimal proportion of methanol as carbon source. The particular environment we have generated inside our ponds reduces hydraulic retention time by 90% and uses 100 times less ethanol than current constructed wetlands. Indeed, we do not use synthetic chemicals, energy input needed is negligible, and neither residuals nor wastewater are generated, so it has no negative impact on the environment. On the contrary, it contributes to both biodiversity conservation and landscape value. For 2020-2022, we forecast €61.3 M cumulative revenues (profitability ratio of 12%), increasing workforce to 40 people. +Water and energy are highly interdependent and are both crucial to human well-being and sustainable socio-economic development. In 2014, the UN reports that 768 million people worldwide still do not have access to a safe source of drinking water, and more than 1.3 billion lack access to electricity. +TecLab Srl is a renowned, Italian-based, designer and manufacturer of electronic systems for automation and remote monitoring of water and gas technological networks. With an experience spanning over 20 years in remote control systems, we have more than 25,000 points remotely controlled by our products in Italy and Europe. We have notable experts in the fields of engineering, electronics and software development and have received certifications from 10 international bodies. Our vision is to become the world’s most innovative supplier of remote control systems and to grow our revenues by +€6 million annually by the year 2023. +Agricultural technology is among the most revolutionary and impactful areas of modern technology driven by the fundamental need for feeding an ever-growing population. Its development has to serve the agriculture that is environmentally sustainable and cost competitive. That means fewer pesticides application, less water consumption and more efficient use of machines. Excessive use of pesticides for the suppression of insect pests, diseases and weeds has significant impact on the human health and environment. It is estimated that about 50% of all pesticides applied do not reach their intended target consequently increasing negative impact on environment, but also production costs thus implying that application of pesticides have to bedone with higher accuracy. Agriculture production cost is furthermore burdened by high cost of crop protection, particularly in grapes and other fruits growth. In permanent and close cooperation with fruit growers TEYME has recognized the mentioned challenges and developed technology to enable reducing the use and negative impact of pesticide. TEYME has improved the existing state of the art pneumatic sprayers for vineyards by patented spraying technology supported by guidance system based on video input. The control system is capable of controlling the spraying rate of individual spraying nozzles based on video input algorithms. Machine vision algorithms are providing information about canopy, foliage density and all necessary data that not only guide the process of spraying but also provide vital data for farmer such as growth rate and health status of the vineyard. TEYME's solution under TEVINS brand name will decrease use of pesticides in vineyard and orchard up to 60% and reduce it operations cost up to 25%. Project Commercial objective is to generate in 8 years of commercialization cumulative revenue of above €58 million and more than 70 new jobs created. +Given the pressure on natural resources, agriculture must improve its environmental performance through 'greener' farming practices. As EU's Common Agricultural Policy (CAP 2020) urge to increase productivity and sustainability, as well as farmers’ resilience towards climate change and world increasing population. In an agriculture market where gross margin and profitability are getting tighter, farmers demand to optimise & reduce water consumption, though precision irrigation. Currently no commercial solution measures underground water & soil nutritional content. +"Flying SpArk is a food technology company which focuses on finding new ways of incorporating insect protein into food products for human consumption to support access to alternative protein sources as well as to increase food supply. Insects, even though less popular in the Western world, have been a part of diets of many peoples in various regions around the world for centuries. Flying SpArk’s protein powder made of the Mediterranean fruit fly, has many clear advantages to other sources of protein. Among these they have a better nutritional value compared to animal and non-animal derived proteins as well as other insects. Moreover, insects have a higher feed conversion efficiency than animals, for example, every 10kg of feed provides 1kg of beef and 5kg of chicken, compared to 8-9kg of insects. Flying SpArk’s edge lies in the selection of the insect for production of the protein powder: the Mediterranean fruit fly, which has never been used for human consumption before. It is more efficient in farming and feeding in relation to the amount and quality of the protein product in comparison to e.g. crickets, locusts, and even more compared to livestock, and it is less expensive also to the consumers. Fruit flies are also cholesterol, antibiotic, hormone, and pesticide free. Their farming requires relatively less resources as they require much less water and feed, and produce less waste, manure, and methane than conventional livestock. Flying SpArk’s innovative project provides an opportunity to address relevant challenges faced by European societies – mainly related to provide adequate supply for high-quality food while enhancing innovation and sustainability in production processes. By using food waste in the fruit flies’ diet Flying SpArk contributes to "closing the loop" of food lifecycles through re-use, and bring benefits for both the environment and the economy." +Even though water is a fundamental resource for human-beings, millions of people around the world lack an access to safe drinking water as they can hardly afford/ have access to current water disinfection methods, such as filtration, boiling, chlorination or ultra violet radiation. +In recent years, a growing concern has been expressed throughout EU regarding the use of phytosanitary products in agricultural activities and the significant impacts this practice may have on the environment and on users and consumers’ health. Conventional pesticides are synthetic materials that directly kill or inactivate the pest mainly produced from non-renewable resources. There is an increasing demand for residue-free crop protection products, which lesser or none negative impact on environment and better safety features such as biopesticides which are naturally occurring substances that control pests by non-toxic mechanisms, more efficient and formulated to specifically affect a concrete target pest, in contrast to the broad spectrum of conventional pesticides that may affect many other organisms as birds, insects and mammals through the food chain. When used as a component of the Integrated Pest Management (IPM) and Integrated Crop Management (ICM) programs, biopesticides can greatly decrease the use of conventional ones, while not affecting the crop yields. Biopesticides are also suitable for Organic Agriculture. The BLOSTER project aims to produce different kinds of biopesticides, showing clearly economic (competitiveness in price, creation of market opportunities for the proposer company KIMITEC and other European plant growers and green residues’ suppliers, encouragement of farmers’ competitiveness at global level), quality (R&D based solutions tested and validated following a pharmacological approach, controlled high quality raw material), safety (less use of chemical products, benefiting EU consumers and farmers at international level) and environmental (better use of natural resources with regards to the raw material used (W2R), less impact on the biodiversity, soil, water and air, less ecological footprint by avoiding raw material transport from third countries, is it will be produced in EU) advantages against the current conventional pesticides. +Concentration is one of the most important processes in the food and beverage industry because it impacts in product quality and stability, transportation, handling and storage. This is a high energy consumption process aimed at removing 50-80% of water from foods. As consequence of the concentration processes, product degradation and loss of organoleptic properties are major concerns for the food and beverage industry. OsmoFOOD is a new food process designed to concentrate liquid foods using an eco-innovative technology based on the forward osmosis phenomena, able to save up to 90-95% of enegy consumption (in comparison with the most diffused technology currently used for concentration). The mission of LEF Ingenieros is to provide the industry with new tailor made resource-efficient plants able to concentrate liquid foods without using thermal energy, and improving by at least 50% the quality of the concentrated foods in terms of organoleptic properties sucha as taste, flavor and colour. Customer will also benefit from a 15% reduction fresh water consumption and overall costs savings of at least 30% in the concentration process. This innovative equipment is focused in the concentrate fruit juices market but includes the possibility to be applied also to vegetables soups and purees, sauces, among others.This innovation project constitutes a great opportunity for LEF Ingenieros to develop a high value and disruptive solution which can reinforce their position in the market and increase their business and visibility around the world. For that purpose, LEF Ingenieros need to confirm and improve the initial business plan. Hence, the feasibility study would significantly leverage our business proposition to reach the market and enhance the possibility of successfully applying to Phase 2 in the SME Instrument in order to demonstrate our technology +1 in 3 adults are prediabetic – at increased risk for type-2 diabetes, heart attack and stroke. Diabetes is associated with a high individual, social and economic burden. The global expenditure on diabetes was estimated to be €508 billion in 2015. The average diabetes-associated expenditure per adult person with diabetes in the EU in 2015 was placed at just over €2,640. In recognition of this challenge, many countries in Europe have introduced national plans addressing diabetes specifically (national diabetes plans, NDPs). +Many of the cities in EU are congested, and congestion increases air pollution, leads to more traffic accidents & makes them less accessible. At the same time a lot of cities were built and developed along some body of water which means that 30-40% of locations are within a 10-min walking distance from a river bank or canal. This creates an opportunity for water-based transport that was not exploited before due to low speeds and high emissions of diesel engines. +Founded in 1994 in the province of Brescia, Italy, we, ALPHA-PROGETTI offer our customers in the sectors of industrial automation customized industrial machinery design and development as well as services in the field of new product development, business development and commercialization. Thanks to our 20 years’ experience and on-going development works, we have devised a promising business opportunity in the field of industrial robotics machinery for SMEs that outperforms current limitations. SINNOTECH, is a young technological start-up born in 2008 devoted to the development of automated industrial solutions based on innovative kinematic approaches to solve the problem of the dynamic control of industrial robotic systems, where they hold a number of international patents in the field of Multi- polar Parallel Kinematic (MPK) robotics. Our partnership has led us to SPARK, a new technology to build a full portfolio of cost-effective (25% cost reduction per axis, 30% cost reduction maintenance/processing and production) industrial robotic systems and enhanced productivity (20% productivity increase). Our technology shows improved dynamic behaviour (accurate smooth motion at high G, inertia momentum reduction, reactivity, which translate in excellent metrics, being our goal: accuracy <0,018 mm, repeatability <0,01mm, position velocity up to 6 m/s, and acceleration up to 6G. An important fact is that our solution is specifically designed for SMEs, as we pretend to license our technology in exchange for royalties to SMEs in the automotive, electronics and metal sectors, starting with MPK Fiber-LASE Industrial Cutting Systems, to gradually enhanced our portfolio to other types of torch (plasma, water) and other types of machines (welding, engraving, painting) that share same background technology. With a potential turnover of circa €16M within 3 years, SPARK will allow us to substantially increase our finance figures (current turnover about €2M). +Fluctuating and unpredictable fuel prices in combination with new environmental regulations are putting a lot of pressure on the maritime industry to use more efficient and greener propulsion systems. Besides, there is an increased awareness for shipping contribution to GHG emissions (2.5% global CO2 emissions). Hybrid propulsion systems (fuelled plus electric) have been used for years in large ships to reduce energy consumption, lower polluting emissions and improve manoeuvrability. However, until recently, it has not been possible to apply the quot;state of the artquot; to small and medium size crafts primarily because of the space limitation of these vessels. AuxiliaTM is an innovative patented universal, compact, plug and play hybrid drive for commercial and recreational vessels (tug boats, fishing, off-shore, yachts, public transport, etc.) with diesel engines up to 2.000 kW (up to 40 m lenght). Unlike its competitors, it is easily implemented in quot;new buildquot; and quot;on the waterquot; ships adapting to its size limitations, since it is mounted in the diesel engine housing and rapidly integrated in the propulsion system shaft line ​without changes in the propulsion system configuration. AuxiliaTM has been developed by Realizzazioni Tecniche Navalmeccaniche (RTN) an Italian SME with more than 48 year experience in marine propulsion. This innovation has been possible thanks to technical advances in electric motors and a special clutch type designed and developed by RTN.AuxiliaTM substantially saves fuel, fulfils current and upcoming environmental regulations even in restricted areas, lowers main engine maintenance, significantly improves manoeuvring in harbours and workplaces (fundamental for off-shore crafts, tug boats, etc.) and makes noise and vibrations negligent. The proposed project will be profitable in the period 2019-2023 (IRR of 32.43%) with a payback period of 3.2 years. +Methanol represents one of the most common and widespread platform chemicals and precursors for further synthesis, and is traditionally produced from synthesis gas, obtained by the reforming of natural gas. This methanol synthesis process operates in a stable, high-throughput manner and demands low carbon dioxide/carbon monoxide ratios in feed. The current project, nonetheless, is to encompass flexible (in operation and feed) methanol synthesis with high carbon dioxide concentration-streams as an input, the latter originating from thermal power stations using fossil fuels. The demonstrational technology may alternatively be intended for the application of existing biomass combustion and gasification system streams, operating for the production of electric/thermal energy, as opposed to chemical synthesis. The other synthesis reactant, hydrogen, is to originate from water hydrolysis using surplus energy, which would be conversely difficult to return to the grid. The three main benefits of the process would thus be as follows; the mitigation of exhaust carbon dioxide and reduction of greenhouse gas emissions (1), stabilisation of electric grid by the consumption of the electric energy at its peaks (2), and the production of methanol as a versatile chemical for further conversion (3). Implications of such technology would have a strong connection to the pending exploration of alternative energy carriers and their synthesis as opposed to conventional resources of fuels and chemicals. The principal technological challenge to be overcome is anticipated to be the development of a suitable catalyst and process, which would allow for high-CO2-content feeds, relatively transient operation (save for an upstream buffering technology is developed), and economically viable operating conditions. The primary advantages of this technology are to be its flexibility, medium-scale operation (deployed “at exhaust location”), and facile integration capacities. +Danish SME Unisense A/S has developed an industrial Micro Electrochemical Cell sensor (iMEC) for automatically quantifying dissolved gasses in liquids. In this project, Unisense will optimize their existing handmade sensors, customized for each client, to an auto-calibrated industrial version, targeting wastewater utility companies. +D&A Experiences Oy is a Finnish SME, founded as an Innovation Design Agency with focus on consumer electronics, electric boats and bikes. Our vision is to create beauty and value by implementing the most advanced technologies into form and function that make the world a better place. We specialise in creating novel user experiences based on both advanced design and tested technology. We have created G-Boat™, the World’s smartest and most iconic electric boat for the metropolitan water front market. G-Boat™ contains many innovations in the waterborne transport industry, including hydrodynamics design, environment friendly lightweight materials, battery technology, navigation technology, ownership models and maintenance requirements. By commercialising G-Boat™, our vision is to become the market leader in smart electric boats, in an industry that is worth over €20 Billion. We foresee that our innovative solution will generate over €10 Million to our annual revenue by 2023, increase our annual profits by 25% and grow direct and indirect employment. Phase 1 of this innovative project is to carry out an elaborate Feasibility Study and Business Plan to get G-Boat™ from TRL6 to TRL9 and commercialise it. +"WATEC project deals with the design, fabrication, "on-field" testing and commercialization of an innovative hydro-turbine able to convert into electricity the kinetic and potential energy of waves and the kinetic energy of tidal streams. +The UN have recently succeeded in Paris on the urgent and highly prioritised need to meet new climate goals within the coming decades, which will result in the request for a broad engagement in new approaches and technologies for sustainable energy production and more efficient use of energy, well reflected in the work programme of EU and esp. Horizon 2020. In this context, TRISORP proposes an innovative approach to cold production that fully fits with these objectives and promises a significant contribution to energy efficiency and reduction of greenhouse gas emissions. It has high potential to significantly reduce primary energy consumption and process costs for clients whereby generating significant business and employment growth with focus on Europe. +Air Pollution is the world’s worst environmental health risk: 7 million people die every year as a result of air pollution exposure. 2 billion children live in areas where outdoor air pollution exceeds the established thresholds. From an economic point of view, the costs derived from health impacts and mortality from air pollution are increasing every year: in Europe the overall annual economic cost is estimated at €1,200 billion. Current strategies for improving air quality focuses in control mechanisms but they do not tackle directly the problem of eliminating the pollutants present in the air. The MossTree is a 4 meter-high 3m-wide and 60cm deep, freestanding unit, which contains combi planting of specific moss cultures and vascular plants that eat particulate matter (PM), nitrogen dioxide and ozone – together offsetting 240 t CO2e/ year. The construction contains smart sensors collecting environmental as well as climatic data, to regulate and control the unit and ensure that the moss culture survives. Thus, the MossTree has the same effect as 275 normal urban trees, but requires 99% less space and 90% less investment. Every MossTree has a capacity to clean the air in a proximity of up to 50m. Thanks to solar panels and rain water retention systems, the unit requires less than 10 hours of maintenance per year. Furthermore, our solution allows digital and visual information transmission through e.g. WiFi, iBeacon and NFC for the purpose of sponsored messages and advertising. Finally, thanks to the sensors incorporated that permanently monitor the air quality the tree will become an important smart city climate infrastructure. After having successfully commercialized the first version of our solution in 9 different cities worldwide, the new version of the MossTree will allow us to obtain a cumulative revenue of €200 million in the period 2019-2021, open new offices in other UE countries and Asia, and create up to 100 new positions. +Almost half of the fruits and vegetables production is lost before it is consumed by people. Dehydration is considered the main driver of quality decrease and promoter of fungi/bacteria proliferation. Taking into account that contamination occurs due to water loss and the action of fungi/bacteria, the reduction of the product shelf-life can be summarized as the combination of the above factors. Consequently, marketing of products that have suffered significant water loss and spoilage becomes difficult; therefore key participants on the post-harvest sector is on demand of solutions able to extend the shelf-life of fruits and vegetables and thus increase the profitability of their activities. +REA STEAM CLEANING has developed since 1986 advanced steam cleaning systems, and thanks to its expertise has become a market leader. Steam has some very specific properties that makes it a very efficient and environment friendly cleaning media for an infinity of applications +The FAO estimates that to we need to produce 70% more food by 2050 to sustain the world’s growing population. +The objective of the pHenom project is to produce the next generation pH sensor capable of accurate, calibration free and smart operation, with integral quality and control. Development and commercialisation of this smart sensor, named the “pHenom” will provide a revolutionary pH sensor that meets the ocean monitoring and water management needs. Beyond the ocean monitoring and water management industries, the global pH meter market is expected to reach nearly £1.48 bn by 2022. The pH meter market is segmented into bench top (55% share - £815m), portable, and continuous pH meters. pHims technology can deliver to all three and has the potential to meet a wide range of needs within the segments; pharmaceuticals and biotechnology, food science (41% share), water and waste treatment, research institutes and environmental control boards. Despite US dominance, in 2014, Europe was the highest revenue generating region at 32% due to the high level of R&D activities, advanced healthcare, and industrial infrastructure. Drivers are new technology (microprocessors for auto temperature and pressure compensation), growing health concerns and regulatory pressure to monitor environmental pollution (waste water pH in industries such as chemicals, pharmaceuticals, food processing) and the need to regulate pH levels (routine testing of soil, water, food, beverage, and dairy products). The objective of this feasibility study is to carry out activities that enable the provision of a comprehensive feasibility report with conclusions, recommendations and a specification of the Phase 2 project objectives, together with a detailed marketing and business plan for the development and commercialisation of pHims. +ReLaDe, an Estonian SME, is developing a reusable laundry washing system, based on novel utilization of enzymes. The ReLaDe innovation has the potential to completely replace the current hazardous detergents and bring disruptive innovation into a market that has been in technological standstill for decades. The innovation will reduce the environmental impact of doing laundry by cutting CO2 emission, decreases the amount of chemical pollutants in wastewater, improve people’s health and offer a novel concept for uptake of nanotechnology by reusing enzymes. +The monitoring of oceans and seas provides the required knowledge for understanding the functioning and assessing the state of the marine environment. As a matter of fact, it is a fundamental and necessary step to undertake in order to obtain sustainable growth and healthy marine waters. +GREENAQUA proposal is led by the Spanish SME Centro de Investigaciones Submarinas, S.L(hereinafter CIS) whose core business is environmental consulting specialised in ecology, biotechnology, biology, natural resources and R&D in the field of water. GREENAQUA is part of CIS business strategy to enlarge their business activity lines within water market related to agro-food sector. +BioMicroGels (BMG) are an innovative versatile solution (1) for the removal of oil, oil products, lubes and greases as well as metal ions from domestic and industrial wastewater, and (2) for the clean-up of oil spills in water. +This project is the continuation of the funded phase-1 ECOBREW feasibility study that has finished successfully. A previous version of this proposal for phase 2 was submitted in Sept.'15. It was evaluated with a score of 12.81 and awarded with the Seal of Excellence, but not funded due to budgetary restrictions. +According to United Nations estimations, the world population will reach to 9,7 billion by 2050. Food, energy and water are the three critical resources that must be managed if mankind is going to thrive. With these figures, we will need a 70-100% increase of food supply to maintain the current nutrition levels. Greenhouse farming is a solution to the food worldwide demands as it can increase the food production per acre up to 100% compared to open field agriculture. Although the energy consumption by agriculture made up only 2.8 % of final energy consumption in the EU-281, the global leader in greenhouse production of horticultural products, The Netherlands, has the highest energy consumption in Europe (7.2 %), clearly showing the impact of Greenhouse farming on energy sources. +APA is a filter-less air pollution abatement system working with a wide array of emission produced during industrial processes. Through its efficient method of cleaning and purifying air, APA directly lowers emissions after industrial processes thereby reducing adverse health issues for employees and the overall pollutants produced contributing to climate change. +It is estimated that 20% of storage tank accidents are caused by cracks or raptures on the tank structure. The majority of the bulk liquids stored in these tanks include crude oil and derived products which are extremely hazardous to the environment; a spill of only one gallon of oil can contaminate a million gallons of water. +The Hi-ThermCap project offers a solution for the macro-encapsulation of phase-change materials (PCM) for use in gaseous and aqueous systems as a heat transfer medium. The expected outcome of this innovation project is to put at the market’s disposal a unique solution for thermal energy storage in heating and cooling systems in Europe. +Established process for the manufacture of ceramic parts involve the key step of mixing in the wet state, and controlled drying (also called atomization) through Spray Dryer equipment. It can guarantee the absolute control in the size and shape of the particles, and their residual degree of humidity. The advantages, making this a fundamental step in the ceramic industry, are related to the flowing capacity of the spray-dried granules, permitting the process at high speed and control over the final performances of the products. As a drawback, this is recognized as one of the most energy intensive steps in the ceramic process, due to the massive evaporation of water and the use of compressed air, almost equivalent to the sintering at high temperature. Early results of independent research conducted from DAXEL, in cooperation with a private laboratory in Italy, have brought to the awareness that it can be avoided, through the implementation into a dry-mixing process of fluidizing agents, permitting the granulated powders to reach an equivalent level of fluidity, and therefore enabling equivalent speed of processing. The advantages DAXEL can provide to its ceramic processor customers are the reduction of one energy intensive step, the reduction of capital investments at no modification of the final quality. Technological Feasibility, Market Assessment, Business Models and Plans are the objectives of the DryMix project, oriented to permit the implementation of the project results into real business cases. A new infancy for the industry of ceramics is expected thanks to the revolution of the DryMix project, permitting an ambitious sky-rocket for DAXEL production and its central role in the supply of mixing additives, and the process set up for new ranges of customers, in Europe and Worldwide. +VitamFero, an innovative French SME, is aiming to develop a new approach to protect chickens against infectious diseases during their first weeks of life. The PROVICOL project aims to induce a strong innate immune response in young chickens in order to protect them against a large panel of infectious diseases. +The HydroKinetic-25 is an innovative, hydro renewable energy device designed to harness low-carbon, reliable and affordable energy from riverine and estuarine environments. Unlike other established forms of hydro power, no height differential, or ‘head’ of water, is needed to generate adequate power from the flow of water. This avoids expensive and disruptive civil works. +The objective of the innovation project is to bring to market a high-yield, highly automated aeroponic plant cultivation system suitable for resource efficient, high quality vegetable and fruit production in a limited physical footprint. This core technology and the associated supporting services are expected to be enablers of the widespread appearance of urban farms. +The MISTRALE project proposes to address soils moisture management in agriculture as well as wetlands or flooded areas monitoring by using Global Navigation Satellite Systems reflected signals (GNSS-R) as a powerful technology for humidity or flooded mapping. The detection by GNSS-R is known to be much more reliable than visible/NIR imagery, and will be usable even under a cloud cover, during the night and even under vegetation (bushes, grass, trees) when passive remote sensing is not applicable. +Management and maintenance of pipe systems present a major problem: leaks. The existence of leaks is costly, both economic and environmental terms, especially when considering finite resources. The ISPNET project proposes a new smart pipe system for early detection of leaks and preventive maintenance of networks, including a last generation of transmission system specifically tested for water distribution, but with further application in other fluids’ transportation networks (oil & gas, industrial liquids…). The new system, which has been installed and subject to public trials, will optimize the properties of existing piping systems and in turn, serve as reporter element of all incidents occurring in the pipe system and as management tool of parameters commonly used. The solution offer innovative advantages both in terms of the materials used for the pipe and due to the monitoring and traceability possibilities of the embedded sensor system. There is no other similar system in the market, and the cost per meter of the system is lower than “conventional” ones. SME INSTRUMENT Phase 1 will help to define requirements to validate the product in different configurations (dimensions, monitoring functionalities) and uses (drinking water and other fluids), as well as to automate the production process. Through a feasibility study, ABN will measure the potential of the solution in terms of efficiency, business opportunity and compliance with standards, analyze the commercial impact of the device and define the market in concrete and realistic terms, in order to attract investors. All this will reduce time to market for a very promising solution, which has received expression of interest of major water distrubution companies. It has also been recently (April 2015) awarded at first Ideas Competition (Sustainability award) launched by the Spanish network of Smart and Innovative Cities RED INNPULSO. +With the increase of the density of people in urban areas, modern cities experience significant needs related to planning, maintenance and administration. As a result, many cities are engaged in massive investment for infrastructure development across many structural elements including water supply, lighting, maintenance, traffic and transportation systems, refuse disposal and all the factors which form a part of the completed city. +Challenge +The MOTOR project focuses on ICT-enabled design optimization technologies for fluid energy machines (FEMs) that transfer mechanical energy to and from the fluid, in particular for aircraft engines, ship propellers, water turbines, and screw machines. The performance of these machines essentially depends on the shape of their geometry, which is described by functional free-form surfaces. Even small modifications have significant impact on the performance; hence the design process requires a very accurate representation of the geometry. +SUNTHERM has developed a Worlds first 25 kWh thermal storage compact battery, based on salt hydrate dissolved in mineral oil that enables up to 25 hours of heat displacement (patent pending). SUNTHERM’s game-changer integrated heating system for households - SmartHeat - consists of: +Tocardo International has in the past ten years developed a technology for tidal turbines for generating tidal power from flowing water. For offshore application, integrated tidal system are needed that require low upfront investments (CAPEX), have low maintenance and operation costs (OPEX) and produce large amount of kWh. Tocardo International has developed an solution which fulfils these requirements. +We, the consortium integrating SILVERWINE, composed by ENOSAN and NASTRI-TEX, will put in the market a product consisting on a kaolin-silver complex (KAgC) contained in an infusion bag, that has antiseptic properties for substituting the use of sulfites in winemaking. The KAgC is composed of microparticles of kaolin (99% weight) and nanoparticles of metallic silver (1±0.1% weight). It is insoluble and it has a minimum reactivity with the food matrix, because the kind of silver used is Ag0, which has biocidal power and leaves no chemical or physical residue, as KAgC complex does not contain any potential allergenic protein fraction or any known allergen. +All infrastructure that underpins life as we know it runs underground in some form whether it be telecoms, water, gas or electricity. All underground infrastructure is only accessible through one method – inspection chambers. These inspection chambers are common and 100s can exist within a small area. To prevent criminal damage to infrastructure and ensure safety, all of these chambers are covered with access covers. There have been no major innovations of access covers in recent times and most remain completely unsecure and vulnerable. Requests to increase security has resulted in simple measures taken in the form of padlocks and key-locks, which still leave significant vulnerabilities. Alongside these vulnerabilities, covers in strategic sites need daily monitoring. This is currently done manually with physical inspections. There is a significant cost incurred for this. +The goal of our project is to launch on the boating market a zero-emissions propulsion system that can be installed on boats up to 10-12 metres long. This goal will be reached by developing an electric propulsion system that is completely submerged in water. With its wide range of power (10-25-50 Kw) and high endurance (over 2 hours), it will be able to be installed on both pleasure craft and passenger boats. +The WiMUST (Widely scalable Mobile Underwater Sonar Technology) project aims at expanding and improving the functionalities of current cooperative marine robotic systems, effectively enabling distributed acoustic array technologies for geophysical surveying with a view to exploration and geotechnical applications. Recent developments have shown that there is vast potential for groups of marine robots acting in cooperation to drastically improve the methods available for ocean exploration and exploitation. Traditionally, seismic reflection surveying is performed by vessel towed streamers of hydrophones acquiring reflected acoustic signals generated by acoustic sources (either towed or onboard a vessel). In this context, geotechnical surveying for civil and commercial applications (e.g., underwater construction, infrastructure monitoring, mapping for natural hazard assessment, environmental mapping, etc.) aims at seafloor and sub-bottom characterization using towed streamers of fixed length that are extremely cumbersome to operate. The vision underlying the WiMUST proposal is that of developing advanced cooperative and networked control / navigation systems to enable a large number (tens) of marine robots (both on the surface and submerged) to interact by sharing information as a coordinated team (not only in pairs). The WiMUST system may be envisioned as an adaptive variable geometry acoustic array. By allowing the group of surface and submerged vehicles to change their geometrical configuration, an end-user can seamlessly change the geometry of the ”virtual streamer” trailing the emitter, something that has not been achieved in practice and holds potential to drastically improve ocean surveying. The project brings together a group of research institutions, geophysical surveying companies and SMEs with a proven track record in autonomous adaptive and robust systems, communications, networked cooperative control and navigation, and marine robot design and fabrication. +Recirculating aquaculture systems (RAS) operate by filtering and removing water pollutants from the fish tanks so it can be reused. Since its introduction, RAS production has increased in volume and species with a CAGR of 14%/year, and has a worldwide market estimated in €6.4 billion. Marine RAS is expensive to purchase and operate, and requires high biomass culture density (kg/m3) that implies fast accumulation of toxic metabolized compounds in low water volume, implying significant volumes of fresh water. Thus, RAS end-users need cost-efficient technologies that can work in these conditions. Market available solutions are mainly bio-filtration and ozone treatments, and cannot work under these challenging conditions, showing efficacy fluctuations and start-up periods that increase the production stages and their costs. +Cycling is a crucial mode of transport in the common European challenge of making transport sustainable: cycling is energy efficient, environmentally friendly and very suitable for short distances. +The global population is projected to reach 9.8 billion by 2050. National populations are expected to more than double in 40 countries. The global life expectancy is 73 years for women and 69 years for men—there are more people in the world and we are living longer. While industrial agriculture produces enough food to feed the world as a whole (2790 kcal/person/day in 2006-08), 32% of all food produced is wasted. The logistics of food production and transportation are largely to blame although in developed countries a substantial amount of food is wasted at the point of consumption. As a result, overall global food availability is lower than it would otherwise be, requiring the planet’s agricultural system to produce additional food to compensate for the wasted food production. Consequently, The United Nations Food and Agriculture Organization estimates 795 million of the 7.3 billion people in the world, or one person in nine, suffer from chronic undernourishment. +JET ANTI-FIRE has the objective to bring to market the most secure active fire-fighting system in the market, which is able to extinguish a fire in 50% less time while saving 75% of O&M costs and 55% of water compared to existing systems, thus guaranteeing more security for the operator and patrimony while fulfilling the local regulation far better than current systems. The innovation is based on two new devices: a hydrant tap that maintains the pressure balanced in a building including skyscrapers, and a jet system that breaks water producing an efficient water fog and so temperature decrease 50% faster than with traditional methods, allowing fire-fighters get closer to the fire focus in secure conditions. FIRING is an Italian based company, they are experts in active fire-fighting systems and solutions with more than 12 years of experience. FIRING experience in active fire-fighting systems shows us, that existing methods have problems to comply with regulation especially in high buildings. This makes expensive O&M methods as hydraulic compensation engineering and dynamic tests every six months necessary. Because of that fire-fighting experts are demanding more efficient and cost effective fire-fighting systems. Our system implies to invest a 20% more in active fire-fighting systems but the gain in higher security, lower maintenance and lower water usage outperforms this slightly higher initial investment within the first year of usage. FIRING wants to participate with JET ANTI-FIRE in the extension and homogenization of secure and effective fire-fighting systems in Europe. +Water Insight (WI) specialises in high quality spatial information products for monitoring surface water quality applying the synergistic use of Earth Observation (EO) and optical in situ measurements. Based on a close interaction with users, WI wants to add a new user-tailored service branch to their portfolio: forecasting of cyanobacteria blooms. +The objective of intraView is to implement the professional expertise and skills to set up a high quality 2D and 3D predictive nanoparticle transport model in our company, which would result in a significant upgrade in terms of performance, growth, and versatility. The applied nanoparticle transport model would enable a new level of remediation planning, and truly unlock the potential of groundwater nanoremediation on global markets. +SmartRAIN is our patented image-processing technology for measuring rainfall intensity from images shot during rain events. It is the core of an integrated IoT system which transforms imaging devices, like surveillance IP cameras (SmartRAIN Nodes) and smartphones (SmartRAIN Sentinels), into “eyes” for seeing, gauging and communicating rain intensity in real-time. +"Global competition for water is increasing and is expected to lead to social, economic, environmental and geo-political +European self-sufficiency rate for fish is just 44%, this means that more than half of the fish has to be imported into the EU. Fish is being transported hundred or even thousand kilometres before arriving to the European market. The imported fish has to be frozen to travel the long distances. +INSPIREWATER demonstrates a holistic approach for water management in the process industry using innovative technology solutions from European companies to increase water and resource efficiency in the process industry. This will put Europe as a leader on the world market for segments in industrial water treatment which will create new high skilled jobs in Europe. +The International Maritime Organisation will soon mandate use of ballast water treatment (BWT) systems in all ships over 300T, of which over 31,000 are predicted to be retrofit with electrochlorination systems. However, existing power supply technologies for electrochlorination are very bulky, requiring most ships to be cut and extending retrofit times far beyond the mandatory scheduled dry dock period that ships must take every 5 years. A fundamental barrier to converting all ships during the expected 5 – 8 yr regulatory window exists. +Through VIOTRAP project, the participating SME attempts to introduce a novel alternative to plants spraying as a means of pest control, in European and Global farming, covering a wide array of Diptera species. +The ski business and mountain economy depend on the randomness of snowfalls. Climate change is shortening the ski season because of less snow precipitation and of higher average winter temperature. Ski resorts have to counteract the lack of natural snow, and to guarantee the opening of ski district in the most touristic periods. Current snowmaking techniques (fans and cannons) require an air temperature below 0°C and low humidity, thus are not applicable for large part of the season. NeveXN developed a technology able to produce high quality snow at temperatures above 0°, in all weather condition and without any chemical additives. SnowRESolution is a clean-tech snowmaker that works also when traditional snowmakers cannot be operated. The technology is based on the refrigeration cycle and exploits the triple point of water, a condition that occurs at 0°C and almost in vacuum (6mbar) at which the three phases of ice, liquid, and vapour are in equilibrium. The compressor is driven by thermal energy that is provided by renewable energy sources, which may be either a solar thermal collector or a biomass steam boiler. Winter tourism is very important in all mountain regions, and risk to undergo to huge losses if slopes are bare. SnowRESolution address the market of ski resorts that want to guarantee the production of snow also when ambient temperature is above 0°C, enabling an early opening of the ski season. Interest savings opportunities are offered to ski domes that do no need any additional cooling to produce snow and can chose the solar power supply solution. +The Green Fast Ferry (GFF) is a full-electric, high speed passenger craft, which will be the only zero emission ferry on the market to meet performances of high speed diesel commuters: 30 knots (55 km/h) speed, large autonomy (26 km routes in 30 min) and fast recharge at port < 20 min. GFF is based on a the patented technology Air Supported Vessel (ASV), that thanks to a pressurized air cushion underneath the hull, reduces energy consumption of > 40%. GFF is suitable for substitution of existing diesel commuters and introduction in sheltered waters and inland where conventional fast ferries are not allowed due to cost erosions, due to strongly reduce wake wash. GFF has a huge market potential in Emission Control Areas in EU (Baltic and North Sea). +No attempt to harvest energy from waves has resulted in an economically viable and competitive technology. Many projects stopped and investors have become sceptical of wave power. Currently the cost per watt of usable wave energy is high, due to a focus on energy conversion methods and efficiency, rather than on mooring and grid connection, accounting for more than 90% expenditure. +Water scarcity and droughts costed Europe over 100 billion € in the past 30 years. With the water prices expected to increase in Europe by between +20% up to even 400%, savings in water have become a priority issue for irrigation professionals. Inappropriate irrigation techniques has a great impact on yield (average loss of 20-40%), plant disease (increase of 15-35%) and input costs (average over spending of 25%). For instance, municipalities in Europe, like London with 14.000ha green areas, are spending an average of 15,000€/year/ha for water irrigation costs. Under this context, Precision Irrigation such us irrigation controllers is the only option. This growing technology which optimizes the usage of water is expected to expand its market share by 13% from 2016 to 2023. +Infrarrojos para el Confort S.L is a company specialised in designing and building Far Infrared (FIR) emission equipment for different sectors where high energy efficiency heating is demanded. +While the market of contact lenses has evolved over the years, there still remains a need for contact lenses which inhibit or do not promote bacterial and microbial growth or adhesion to the surface of the lenses, while simultaneously being safe for the wearer. +The project aims to develop an innovative food supplement consisting on a high concentrated emulsion of Omega-3 fatty acid EPA. Omega-3 is utilized as a treatment in psoriasis, arthritis, asthma, multiple sclerosis, chronic inflammatory, cancer, high TGs, retinal diseases and cardiovascular failure. +DIANA is aimed at co-designing and openly demonstrating a commercial service platform that will empower water managers and authorities to optimise the identification and inspection of non-authorised water abstractions for irrigation as well as improve their water management policies and practices, especially in extreme conditions such as drought. DIANA will leverage EO data provided by Copernicus and other data sources as well as state-of-the-art models for the identification of (illegally) irrigated areas and the estimation of abstracted water volumes in order to offer a value added suite of data products and services, that will be affordable and cost-effective. The value propositions of DIANA will be co-created and defined along with users and stakeholders so as to be shaped according to their needs and requirements. Three pilots will be deployed in order to put them to the test in real operational environments of Spain, Italy and Romania. All pilots will be integrated with the work flows of the users and their results will be co-evaluated and validated with them through a multi-layer methodology, fostering the acceptance of DIANA as a marketable solution. In order to ensure the demand-driven design of the DIANA service platform as well as set the stage for its market launch and uptake following the end of the project, a customer-driven business modelling process will be followed during the project, validating its business case and producing an effective business plan to serve as the roadmap for its post-project commercialization. Finally, DIANA is implemented by a transnational and well-balanced consortium, consisting of innovative SMEs and pioneering authorities, all of which possess the complementary expertise as well as the motivation and commitment required to ensure not only the creation of meaningful project outcomes but also their successful commercial exploitation and sustainability. +Wind power has established itself in recent years as a clean alternative to conventional sources of electrical generation.Reduced costs and wider deployment, especially in the European market, have led over the past decade to its use at sea. Here, the wind resource is larger and more constant, allowing higher unitary power turbines. However, the marine environment itself also imposes a number of restrictions and challenges. The technology that is being deployed now is fixed to the seabed, using different types of foundations, but a large amount of wind resources is in deeper waters, where floating solutions are needed. Because of their initial higher costs, these solutions are still under development, with only three prototypes installed worldwide. The challenge nowadays is to reduce the costs of floating wind turbine structures that will ease the access to a much larger energy potential than available in land, more easily manageable and with lower visual impact. The aim of the SATH project is the demonstration in real conditions of a floating structure for offshore wind which will allow a reduction in LCOE (Levelized Cost Of Energy) over the current floating technology. To achieve this, it is proposed as a first objective the validation and qualifying for this technology, of a 1:3 scaled prototype not only from a technical point of view but also from economic and necessary logistics. The SATH solution is a platform that consists of two cylindrical floats (of prestressed reinforced concrete) which can be manufactured onshore and transported and positioned at the final location in a single mooring point allowing the rotation of the platform around, self-aligning with the wind direction. +The growing population is putting a strain on the world’s water resources while at the same time the ever-developing industrialization is causing increasing occurences of water-contamination, both in potable water sources and in wastewater, which is discharged into rivers and oceans. +According to the United Nations Economic Commission for Europe (UNECE), there are 4 billion wooden pallets in circulation in Europe right now, this means 108 billion kg of dead weight. To transport this weight 100 km, trucks will require 334M litres of fuel that will emit 880M kg of CO2. +GReen Desalination Project aims to deliver a well-proven concept to the water and salt markets. The desalination process involves a lot of wastewater that is currently discharged into water bodies, causing environmental degradation, while its energy and resources content goes wasted. These raw materials are leaking today from our economies and can create significant business opportunities, both in and outside EU. +CONTEXT: Water shortages and water pollution constitute major environmental threats in the EU. European agriculture occupies 40% of the land and can reach up to an 80% of total water abstraction and it’s the main responsible of nutrient soil pollution. +Agricultural farm holdings count up to over 12 million farms in EU-28 countries with almost 10 million directly employed labour force. Most of these farms are small to medium sized farms. In the EU live 23.5 million cows and 152 million pigs. Producing pig meat and dairy products are energy intensive processes whose energy consumption makes up to 16% of the whole consumption in the agricultural sector. Apart from being energy intensive sectors, these animals produce large quantities of waste. KUDURA is a disruptive portable solution for waste - to -energy and water treatment, which operates off-grid, which use transforms cow and pig manure waste into biogas to feed a combined heat and power plant to obtain electricity and heat. Furthermore, agricultural waste-water can be treated with the same solution contenereaized solution. With KUDURA we will implement a breakthrough solution to provide farmers not only the reduction of their cost for waste management, but its transformation into power and heat supply, being able to operate in remote locations and completly off-grid. KUDURA is flexible in sizing, functions and location as well as in financing options to ease the market entry in areas with lower income. It is easy and quick to install providing services within less than 48 hours. Our solution will be upgraded and adapted to agricultural markets in European countries, where the need for sustainable, flexible and affordable solutions increases. Our company RVE.SOL is a social entrepreneurship specialized in developing and implementing renewable energy and water treatment solutions. Based in Portugal, our highly internationalised team in RVE.SOL holds a mutually complementing skillset. +European livestock holders and biogas plant operators produce billions of cubic metres of manure and digestate every year that need to be disposed. The disposal of these nutrient-rich suspensions on agricultural fields is restricted by the EU’s Nitrates Directive and derived national laws. Therefore, livestock holders and biogas plant operators cannot dispose their residues in this traditional way and have to pay much money for a third-party disposal. +According to a PricewaterhouseCoopers (PwC) analysis, Europe risks losing the leadership in innovations. To protect innovations/inventions and to ensure the return on investment, intellectual property rights (IPR) are increasingly used. IPR processes are very complex, cost intensive and time consuming. Due to these facts, especially innovative entities (companies and universities) require very high efficient IPR management systems, which have not been existed on the market until now. +The topic of this proposal is to determine the final production model of a scooping-device that allows non-amphibious conventional airtankers to scoop water from a body of water (sea, lake, river or a dam-reservoir) flying at an altitude of +/- 10 metres, in order to suppress forest fires much more quicker by 5 times. Today only dedicated amphibious airtankers, like the so-called Canadairs CL 415, can scoop water. Non-amphibious conventional airtankers have to return to the airport to refill with loss of time. Today such a scooping device (Scodev) does not exist and it will be a revolution in forestfire combating industry, thus it is disruptive. Feasibility studies have shown that it is possible to scoop large amounts of water in very brief time of 15 seconds. Prototype flying tests will prove this ability and serve as mandatory application procedure for EASA airworthiness certification. Once the prototype tests are finished, the Scodev is ready for the market. With the patented Scodev, operators of airtankers will improve their dropping-capacity from 1 to 5 droppings per hour. By improving the dropping capacity with 5 times, the suppression-efficiency will improve exponentially up to 8 times, which means that the damage will be reduced between 50 and 80 %. Today worldwide there are only 110 amphibious Canadairs. There are 1200 non-amphibious airtankers, owned by civil protection entities or forest service bodies. In addition there are 1500 large military aircrafts for disaster relief, and 1500 small airtankers SEAT. Meaning the potential is very big and the trend is increasing due to global warming. Due to forest fires millions of hectares are lost and the financial damage is hundreds of billions of Euros. The use of the Scodev will decrease not only financial losses, but the environmental and ecological damages will also be radically reduced. +Microbiological contamination can be attenuated, never eliminated. Space exploration requires development of reliable rapid significant and safe methods for preventing, monitoring and control the biocontamination within manned closed environments. These methods have to be automated, simple and conceived to decrease the (re-)supply mass from ground. +Precision Agriculture (PA) has been enabled by satellite imagery and provide disruptive new tools and decision support for farmers. However, we have identified that satellite optical data, currently being used by the best PA companies around the world, is not enough to obtain the best results. +CyanoLakes will be a global service for the environmental authorities and commercial sector, concerned by health risks and quality of water resources. The proposed project will deliver a fully automated application for assessing toxin producing cyanobacteria blooms in water resources globally, using ground-breaking Copernicus Earth Observation technology. The service foresees a dual dissemination system that provides user-specific information for monitoring and reporting purposes to customers, and a free and open information service for the public based on mobile telecommunication. South African and European SMEs will partner with users in the environmental authority and commercial sector, in order to establish a sustainable supply chain, based on a sound business model, to bring this innovative service to market. +BIOECOMARINE project is born to bring a cost-effective and eco-friendly Anti-Fouling (AF) solution that can be easily adapted to any type of vessel regardless its length or hull material. In this context, BIOECOMARINE focused on the commercial development and further commercialization of a prototype based on the ultrasonic technology that provides vessels full AF prevention while ships are at berth. Since any kind of vessels can benefit from this system, the commercial scope of this system ranges from recreational boats to the maritime transport sector including shipping companies, commercial ports and shipyards. +Currently, fruits and fresh vegetables production and stores are under severe control conditions, including expensive installations of controlled atmosphere environments with ozone injectors, gases stratification control and other devices for ensuring best conditions. +Despite the encouraging scenario of Wide Solar Thermal Electricity market - it is a reality today with 4.9 GW in operation worldwide in 2015, forecasting 260 GW in 2030, 664GW in 2040 and finally to reach a 12% of total electricity generation by 2050 (982 GW) - CSP growth has been slower than expected because several issues have not been overcome yet. It is not as cost-efficient as other technologies making difficult its access to the generation mix. Another not-solved aspect is flexibility, since one of the main issues of the electrical market is the complexity to match the supply and demand curves due to the arbitrariness of the sun. Finally, CSP technology brings environmental issues related to the usage of oil sinthetic as HTF and a meaningful water consumption. In this framework, MSLOOP 2.0 aims to validate a business opportunity consisting of developing a cost effective solar field for CSP Parabolic Trough Power Plants using optimized ternary molten salts as HTF with an innovative hybridization system. The result of the project will be a new solution of CSP commercial plant with at least a 20 % LCOE reduction and flexibility improvement providing firm and dispatchable electricity based on a disruptive and environmentally friendly innovation. MSLOOP 2.0 will ensure the market-drivers acceptance from the beginning of the project in order to launch the solution in open tenders in less of 6 months after the project final, boosting significant contributions to industry, environment and society and that will make possible a deep penetration of CSP plants in the generation mix increasing the share of renewables. In order to achieve this challenge, the MSLOOP 2.0 consortium consists of a multidisciplinary team formed by 5 partners from 3 European Union member countries in strategic fields within solar thermal sector. This composition will boost an innovative development capable of achieving a strong positioning in the market. +BeadCAP-DNA aims to create a world-first 30-minute on-site DNA test kit, for food provenance, thereby eliminating the 2 to 5 day wait for DNA results from a central Lab. This is achieved by a novel merging of molecular biology and semiconductor capacitive sensing in a single-use microfluidic disposable DNA test kit. No such solution currently exists. Our prototype has no molecular amplification, i.e. no risk of on-site cross-contamination. It has 3-orders of magnitude response, enabling qualitative and quantitative DNA detection. The first product version is defined with end-user customers as 8-multiplex, aimed at GMO detection & 8-food-species testing to 0.1% limits. 3 patents are pending. +Pervasive and on-line water quality monitoring data is critical for detecting environmental pollution. However, it’s not easy to gather such data, at least not for all contaminants. Currently, water utilities rely heavily on frequent sampling and laboratory analysis in order to acquire this information. +Drone Hopper is remote-controlled aircraft that incorporates a container unit to hold liquids that can be used for firefighting, propelling nebulised liquid to be directed towards land. In Europe, fires destroy millions of hectares of forest woodlands causing the loss of many human and fauna lives and an immense economic damage. +EOMORES (Earth Observation-based Services for Monitoring and Reporting of Ecological Status) aims to develop new highly efficient commercial services for operational inland and coastal ecological water quality monitoring. +Green Star Marine AB is developing to commercialize a disruptive electric propulsion system for water vessels, contributing to fossil fuel decrease, environment sustainability while delivering a comfortable, reliable, cheap and highly capable marine vehicle transportation. GSM´s goal is to provide their solution to the <100 hp segment in this multi-billion market where greens solutions are expected to gain market shares primary from traditional inboard/outboard combustion engines. +The world fleet consumes up to 325 million tonnes of fuel/ year, being responsible for the emission of 1,099 million tonnes of greenhouse gas (GHG). Ships only use 28% of the energy from the fuel to generate propulsion, of which the majority is spent overcoming fouling. Thus, keeping the hull clean can result in significant cost savings and reduce the GHG emissions. Currently, when the ship performance decreases significantly a call on-demand underwater service for removal or killing of the fouling is contracted. This is performed when the ship is docked using diver- or unmanned-operated vehicles. These solutions have often poor quality, are expensive, unsafe for the divers and/ or maritime traffic and only provide a transient increase in the hull performance. +ERSO is an Austrian company specialising in the research and development of novel technologies within the energy sector to reduce global energy consumption. Skiing demand has reached almost 400 million visits globally per annum and with over 7000 indoor ice rinks the demand for artificial snow/ice is great. With the rise of global temperatures and the unpredictability of weather conditions the rise in ski resorts limiting the amount of natural snow available, the introduction of artificial snow has been a method of extending the ski season to accommodate further visitors. Some ski resorts in Switzerland, Austria and Italy use artificial snow for 50% or more of their skiing area and the water consumption for this can be up to 20% of an entire regions water usage for a year. Traditional methods of producing artificial snow have a number of disadvantages and environmental effects such as high production costs, short snow lifetime, short temperature range and the damage of the wildlife and fauna. Often, to make good quality snow, water is mixed with either dust or bacteria, of which both can cause damage to the ecosystem when the snow eventually melts. With the huge volumes of water used, the melting process can also lead to instability within the summer season of the ground and can lead to landslides and the destruction of flora. ERSO have identified a business opportunity and have developed technology which restructures the water itself making it more compact and therefore have a longer lifetime which reduces water and energy consumption as well as the environmental effects of artificial snow production. The SnowTech system allows the snow/ice produced to resist melting for up to 30% longer which also means snow can be produced at higher temperatures (up to 2 °C), reduces costs to ~30%. For a ski resort with 10 km of artificial snow slope we can allow savings of up to 1,000,000 L of water, 160,000 kWh of energy and €44,000 in cost solely attributed to electricity. +Widespread contamination from pharmaceuticals (synthetic or natural chemicals found in prescription medicines, over-the-counter therapeutic drugs & veterinary drugs) are finding their way into the drinking water supply, posing serious threats to public health. Pharmaceutical compounds such as hormones and endocrine disrupters are already responsible of major health problems, but modern wastewater treatment systems are not designed for effective removal of pharmaceuticals. +The main objective of FITTOM is the development of a new technological industrial process able to produce innovative fittings commercially competitive for water transport. +HydroNanoCoating will reduce up to 30 times the water absorption compared to common untreated cardboard and by 40% the water absorption compared to current paper protecting alternatives (paraffin). HydroNanoCoating will enlarge up to 3x times the lifespan of paper, cardboard and corrugated cardboard by drastically avoiding water damages to the contained products and its consequent loss that can reach 9M€. +Data has been termed to be the „oil of the 21st century“. Data will also be what the smart city of the future runs on. To make this a reality, cities need a platform where data from a variety of sources – IoT and sensor data, open government data, social media, and other 3rd party data providers – can be processed, linked, and analysed in order to extract valuable information that in turn can also be provided as linked open data, and with which new types of services are created and provisioned. Both cities as well as private service providers can build novel applications and services on top of this platform; the platform thus becomes an economically valuable driver for Smart City Innovation. +R-Fire is a company founded by firefighters and pilots who have used their corresponding experience to create a novel solution to fight forest fires. They have joined forces with TFEX Engineering Ltd and together developed the I4F technology and validated it with our prototype to tackle forest fire by using foam. TFEX has broad range of firefighting products and also own the Instant Foam technology. +"CosmEthics, with its E-solutions, helps EU citizens to identify cosmetics products with potential hazard ingredients (EU Annex II prohibited chemicals, carcinogens, hormones, allergens), and helps them to find better alternatives based on scientific research and user tailored preferences (allergies, vegan, plastics). Nearly all EU citizens use some form of personal hygiene products daily. Cosmetics are a major source of water and food chain pollution via the microplastics they often contain. +Hot water costs a lot of energy to heat, yet most of that heat goes down the drain. Due to lack of effective and efficient solutions at small scales in residential buildings and small businesses, still a huge amount of energy is wasted for heating the water. In Europe alone, that’s a €15B waste every year and this is as high as €18B in North America. Current solutions are mostly focusing on more efficient boilers and not heat recovery, and the heat recovery solutions don’t have high efficiency and are suffering steady loss of efficiency therefore their payback periods are so long. +Located near Bergamo, Italy, our company, AERIS Group, is specialized in design, development, manufacturing and commissioning of air technological applications, ranging from air conditioning over process air technology up to removal and heat recovery. With more than 50 years of experience and a turnover above €4 million, our group is composed of 3 companies: AERIS air technologies, expert in HVAC and filtering, EDENYA for air cooling solutions and MAZZINIICI, our textile division. The technical know-how of our high-specialized professionals, our detailed knowledge of materials, production processes and production methods in the different industrial fields as well as a business strategy turned towards continuous innovation and global presence are the basis of our success and growth. +Octopus is a technology which will lead to the development of an economical, fast and environmentally sustainable alternative to fracking technologies. Fracking is an effective but controversial technology which uses hydraulic stimulation to boost productivity of oil or gas wells, and is currently used in 160,000 wells, worldwide. Fracking technology is surrounded by environmental, economic and political argument and there is rising concern over its use of billions of gallons of clean water which becomes polluted and is injected under pressure into the ground, a practice which is now known to trigger earthquakes. +Industry activities such as manufacturing, mining or construction have to deal with the management of their stormwater and industrial process wastewaters, with high contents of suspended and dissolved pollutants that need to be treated before discharge. Disposal of residual wastewaters from an industrial plant is a difficult and costly problem. However, today's technology is either not effective at treating larger volumes of water, too complex or too costly. As a result, companies struggle to comply with regulations affordably, effectively and safely. This situation can force companies and projects to shut down or relocate to areas with less strict environmental protection regulations in order to avoid fines. +Heating today is responsible for 50% of the EU's annual energy consumption. However, a large part of this energy is wasted because almost half of the EU's buildings have boilers installed before 1992, with an efficiency rate of below 60%. Transition has started with the deployment of regulatory measures (Energy Efficiency Directive, Building Energy Efficiency Directive, Energy Labelling Directive, national building codes…) and the prospect of substantial savings in heating and hot water expenses. +MACIVIVA is a highly interdisciplinary consortium among well established and innovative SMEs with scientific excellence and complementary industrial world-leading experts with unique expertise and know-how in virosome technology, spray and freeze drying, large scale manufacturing and packaging. MACIVIVA will pave the path to other large scale thermostable nanopharmaceuticals products for therapeutic and prophylactic vaccines and other potential applications for direct application by non-invasive routes. +Both regulations and costumer needs resulted in expansion of the market for green labelled food products cultivated at sustainable way. Nevertheless, the availability of affordable technological tools for the production of green vegetables is limited. Furthermore vegetable suppliers (in Europe typically farmers with small land) neither have the essential technological knowledge nor the willingness to change the cultivation methods. Realizing these trends, Vegetable Trading Centre (VTC), a regional market leader of Vegetable production and trading, and Multisense, a technology intensive start-up, put together this proposal, aiming at the establishment of a sustainable agricultural eco-system. An innovative technology for on-site production of microalgae and their usage as bio-fertilizer in vegetable cultivation has been piloted at VTC. In the proposed business model, this technology will be sold to framers helping them to make microalgae based fertilizer on their own land at cost-effective eco-friendly way. The trader (Vegetable Trading Center) guarantees to buy the vegetables produced this eco-conscious way and bring them to superstores at high price. In this phase 2 proposal we target to upgrade and generalize the pilot site to a commercial technology, obtaining upgraded sensor and control system, make generalized designs, user manuals and descriptions, use cases, as well as demonstrate the efficiency in extensive field trials. Furthermore, starting with the suppliers of VTC, we aim at expand our business model to Europe and carry out the early marketing actions within the project. +"The world is facing a strong challenge due to the great environmental cost deriving from the production and distribution of soft drinks in aluminium cans and plastic bottles. A huge amount of resources is in fact required for producing, disposing of and especially transporting these products, which consist of more than 80% water. +FP-Pigments is a Finnish SME, and a manufacturer of opacity pigment with factories in Finland, Germany, and the US. FP´s current success is based on innovative and patented, continuous production method, which enables the manufacturing of unique pigments for high value added applications in a very cost-efficient way. +The objective of the Sea-More-Yield proposal is to commercialise a disruptive blue biotechnology solution to address a bio-oil crop productivity challenge. Three years of independant trials have consistently demonstrated a 20% increase in yield over the current market leading product. Sea-More-Yield powered by Plant Signal Induction (PSI) is a novel patent pending blue biotech innovation to reduce pod shatter in Oilseed Rape (OSR) delivering €5.5bn at the farm gate if implemented across the EU-27. End result, more food and energy security, a theme underscored by Horizon 2020.Sea-More-Yield represents an excellent opportunity for the H2020 SME instrument as it will launch the participating SME Brandon Products into new markets, promote growth, and create high returns of investment. Sea-More-Yield is aligned with the call topic supporting SMEs efforts for the development - deployment and market replication of innovative biotechnology solutions for blue growth. Sea-More-Yield is a perfect example of such an opportunity. The basis of the Sea-More-Yield technology is the seaweed bioresource used in biostimulant manufacture, which is a complex and unique resource whose chemical, biochemical and biological properties provides major undiscovered potential. The main beneficiaries of the development of Sea-More-Yield will be Brandon Products; Growers of OSR gain from increased net margins, increased yield, increased quality premiums; Oil processors will have a larger quantity of high quality oil; Product distributors will have a disruptive technology with a proven mode of action; Consumers will benefit from a predictable harvest = predictable production costs = more stable pricing; The environment less agrochemicals, fertiliser more biofuel and leading to more sustainable biofuel production. +"Water management in Europe and around the world is facing rising global temperatures, higher rainfall variability, population growth and water demand increases, freshwater pollution and other serious challenges. Current Modelling and ICT tools can help farmers to be more efficient regarding water management in agriculture. There are some potential "smart water" applications available mostly as research or information tools. However, there is still a lack of integrated-site-specific solutions offering an adapted service for the agriculture sector and no available commercialization. Zeta Amaltea, and GeoSlab conform the most complementary consortium with high level skills and background on innovative solutions for Integrated Water Resources Management (IWRM) and planning. They will launch SMARTQUA as the first tool to fully take into account agricultural farmer’s needs to provide effective water and risk management; considering key internal and external data input. SMARTQUA integrates water management and nitrate pollution EU legislation, watershed data and underground aquifers, all in a cheaper offer than competitors. The benefits of this service will provide an accurate decision-making via web (online platform) or mobile application and lead to significant return of saving up to 20-35% of farmer’s operation efficiency and 15% of internal cost (saving water, energy and fertilizer use), whilst avoiding nitrate pollution and providing a higher climate resilience." +The aeration of activated sludge accounts for 60% of the running cost of wastewater treatment plants, a staggering 2% of all electricity generated at country-level. The project will improve upon an existing prototype of on-line microbial respirometer with near real-time capability for monitoring the activity of the microbial population (biomass) in activated sludge, and suitable for industrial and municipal wastewater applications, with the following environmental and financial benefits: +The ambition of the Oceanid-project is to commercialise our disruptive system for cost-efficient ocean-bottom data acquisition. An automatic Oceanid-system will compliment a large swarm of autonomous Oceanid-nodes, and facilitate a novel launch- and recovery system, incl. inductive re-charging and simultaneous data-transfer, for retrievable of said subsea sensors, enabling a short turnaround on deck. This will reducing operational duration versus similar survey-system with up to 63%, and thus reduce seafloor survey OPEX with more than 50% compared to competitors. The Oceanid is directly contributing to solving the worldwide industrial and societal challenge of unlocking new resources in deep water by provide an effective means for large area exploring of the ocean floor. The innovative Oceanid-concept consist of a large quantity of retrievable and fully autonomous underwater vehicles [AUVs], which in one scenario has an Ocean Bottom Node [OBN, Oceanid-OBN] fully integrated with a novel wireless power and data transmission system [Oceanid-Link]. The handling system topside will automatically deploy the Oceanid-OBNs LARS-type multi-node basket, and recover the nodes safely back on deck after surfacing. A minimum configuration of two standard ISO-containers is developed, comprising the deployable launch and recovery skid (LARS), combined with means of re-filling the novel salt-ballast tanks on the vehicles, and a container for storing of 250x nodes with simultaneous downloading of data and re-charging of batteries. The Oceanid-OBNs has the capacity to log sensor data down to the design depth of 3,000m, and will self-guide upon release from an over-boarding basket to a predetermined location on the seafloor. Upon received acoustic command the vehicle releases the salt-ballast, gain net positive buoyancy and returns to the surface of the water, where the recovery system is recovering the numerous nodes released. A GPS-fix is relayed to the ship via VHF. +Due to the health risk for those suffering from Celiac Disease and other intolerances, Allogen Biotech Ltd.’s Rapid Allergen Detector (RAD) kits can detect a range of protein-based allergen in food or cosmetics, in a compact portable reader and disposable testing strips. The kits are versatile, with a cartridge-based reagent to identify and concentrate allergens for detection, and an accurate reader that can provide quantitative readouts for industrial users or a simple “traffic light” system for consumer model users. Results are available in 10 seconds or less, a reader can be used for over 10,000 tests, and test strips are simple to use, with a low cost. +The energy market is rapidly transforming towards locally produced renewable energy. At the same time the society is concerned about the environmental aspects and dependence on carbon based energy. Polarsol’s mission is to become one of the most influential drivers of that transformation by providing means for highly cost-efficient local generation of clean heating. Polarsol has brought to the market the most advanced in terms of cost-efficiency hybrid heat management solution that can be successfully applied across EU. +The general objective of ULISENS project is focused on the development and further commercialization of an automatic early warning system able to detect and quantify Legionella species in water. The system integrates an innovative fast detection biotechnology with an automatic module able to carry out “in situ” analysis in real-time to minimise time to results. +Hiperbaric is an SME leader in designing, manufacturing and commercializing High Pressure Processing (HPP) machines on an industrial scale. HPP is an innovative processing technology for many types of food (meat, seafood, vegetable, fruit products…) with an important growing potential over the traditional techniques such as thermal pasteurization. This process inactivates food microorganisms, increasing safety and shelf-life, keeping flavor, nutrients and product freshness. +ACIES BIO has developed an innovative and disruptive high-value technology to address a major economical and environmental challenge of the world’s dairy industry: waste whey. Over 200 million tons of whey is generated annually, and only limited economical solutions exist to process it. The innovative patent pending technology Whey2Value uses a unique bioprocess to utilize whey as a primary ingredient for microbial fermentation to produce sustainable high-value products, such as vitamin B12. The technology greatly reduces the negative impact on the environment by almost eliminating the organic content of the wastewater, allowing for its recycling, while the product of the technology is a protein-rich biomass with high content of vitamin B12 to be used as a very high quality animal feed to complete the dairy industry’s circle. The innovation W2V is perfect example of how circular economy should work. The Whey2Value technology requires a very low-cost processing facility, which can be installed on site, and minimal maintenance costs. It represents a truly unique opportunity to create a huge and disruptive impact on dairy industry, particularly for the competitiveness of small and medium sized European dairy companies, generating high-value products from waste material, and at the same time creating a sustainable solution with a greatly reduced burden to the environment. The objective of this project proposal is to prepare a thorough business plan and feasibility study in the scope of Phase 1, followed by scaling-up and demonstration of operational technology in industrial setting with a local dairy company in the scope of Phase 2. The technology is ready for industrial demonstration, which will be followed by EU and global commercialization of Whey2Value. We expect a rapid worldwide market adoption of this disruptive eco-biotechnology. +NVP Energy presents the first to market, high-rate anaerobic digestion (AD) technology that successfully treats low strength wastewater (WW) at ambient temperatures (< 20°C). The low-temperature (Lt-AD) process provides a novel solution to Food and Drinks industrial sectors producing large WW volumes requiring treatment. The sector of interest is milk treatment and processing, a growing market producing over 367 billion litres annually; WW is typically treated using conventional aerobic processes resulting in high sludge yields, requiring a large footprint on-site and a heavy reliance on fossil fuels. Lt-AD produces negligible sludge volumes, has a compact design, requires no heat input or biogas recirculation, and produces effluent of urban wastewater directive (UWWD) standard (< 125 mg/L COD) without post-aeration. A typical dairy processing plant producing 5,000 m3 WW per day can save 97% on operational costs by replacing aerobic treatment with Lt-AD, and generate annual biogas revenue of €616,266. The technology's low temperature operation allows for 100% of the biogas produced being available for reuse or resale. The process also has a high impact on environmental savings through reduced greenhouse gas (GHG) emissions, lowered thermal energy and fossil fuels requirements. +To improve energy efficiency, modern “zero-energy” homes are highly insulated. As a consequence homes can no longer ventilate resulting in poor indoor air quality. Thus, the use of efficient ventilation is becoming increasingly important. But ventilation causes significant heat loss, reducing the energy-efficiency of the building. Although advances in last years, current trends in energy systems for climate control and water heating in residential buildings are still unsustainable and further energy savings are fundamental. +The market for carbon accounting is a niche but rapidly growing market with the EU market alone being worth £2 billion. Currently all carbon accounting solutions for companies are a time-consuming and expensive process carried out manually by specialised carbon accounting firms. +Pulverizadores Fede is a technology leader in the production of agricultural machinery for vertical crops found, for example, in orchards and vineyards. As such, we are well positioned to contribute to resource-efficient eco-innovative food production, which is not only good for the environment but is also key for the agricultural sector’s competitiveness with a clear European dimension. +Uncertainties in water availability, rising fertilizer and energy costs and increasing demand for renewable raw materials impose serious challenges on the primary sector with far-reaching implications. Irrigation practices put more and more pressure on scarce freshwater resources and mineral fertilizers are often overused leading to environmental problems and heavy impacts on the production costs of producers. Increasing resource efficiency, productivity and competitiveness of agricultural practitioners are crucial for addressing the aforementioned societal challenges. Fertigation, a novel concept merging irrigation and fertilization to one process, poses an innovative alternative to conventional cultivation practices. Hydro-Air, as SME in irrigation technology development and provision, developed and integrated the concept of fertigation with pivot- and linear irrigation systems. Using GPS & GIS data in conjunction with sensor based soil and crop property parameters the SMART Fertigation system enables sub area specific farmland management and fertigation. Optimised resource application leads to an immense savings potential in production costs (water & fertilizer by 20%) besides increasing crop yield from growth phase adjusted water and nutrient supply. This ‘saving & gaining’ makes Hydro-Air confident to supply an internationally growing market demand for resource efficient, green technologies. Based on encouraging results in field trials Hydro-Air prepares advances towards market introduction. Hydro-Air will apply and use the funding in Phase 1 to conduct a feasibility study which will reveal the European market potential of SMART Fertigation. Client groups in targeted countries will be evaluated and a business plan will developed considering estimated costs and revenues including return of investment schemes. The results and experiences will feed into the continuous improvement of the SMART Fertigation system preparing for subsequent development phases. +According to many international studies, world population growth and climate change will end in a reduction of food, energy and pharmaceutical resources. One possible solution is an increase in the production of microalgae. The business opportunity consists in the construction of a production plant integrating algae cultivation in photobioreactors with a syngas CHP as a source of carbon, required for the photosynthetic process of microalgae. Market application deriving from algae include: biomass for combustion and organic matrix for anaerobic digestion plants; food supplements for human/animal use; pharmaceutical/cosmetics products; fertilizers; complete pilot line for cultivation. Other applications include licensing of concept, technology and brand and experimental photobioreactors for bio-lighting algae research. It is a growing market with a world potential estimated at +30% each year and a global size of 150M€ in 2016. Key reasons explaining its novelty are: reduced need of land; use in low-quality agricultural land; no emissions of greenhouse gases/pollutants; absence of aggressive waters; significant amount of carbon dioxide captured and stored; pure product with high Ω3 content. Potential customers include: food supplement producers and retailers; livestock and poultry producers; pharmaceutical and cosmetics industry; agricultural product retailers and farmers; bio-fuel refineries; agricultural and processing companies interested in market replication or in becoming licensees; research institutions; general public, families and young people. The structure of the work plan starts with the management (WP1), includes one WP devoted to a pilot line for microalgae production, including PBRs for research on bio-lighting algae (WP2) and continues with a WP dealing with pilot production, performance verification and market replication (WP3). WP4 will take care of dissemination, exploitation and marketing. Communication will be covered by WP5. +A prototype of a newly developed agitator has shown great potential for energy reduction in agitator technology. The developed agitator was inspired by the way ducks move their feet in the water – a very energy-efficient way. Consequently we call the new agitator a bionic agitator. Now we want to validate the findings from the test of the prototype in a beta-phase test. +Alleco, a Finnish SME, has developed the world’s first tablet computer with a fully functional touchscreen that works under water. With patented core technology, 25 years of experience in the industry and existing cooperation with the world’s leading diving equipment distributor, Aqua Lung, Alleco is well positioned to bring this novel solution rapidly to the market. With the developed product Alleco is expecting to realize its growth strategy and become a global leader in providing the diving industry with ground-breaking new information and communication technologies. +Sea-More-Yield is a revolutionary non-transgenic platform for trait introduction via single 1.5L/Ha foliar spray, enabling immediate expression of desirable anti-shatter traits in OSR. This pioneering technology enables growers for the first time to modulate OSR pod physiology to minimise seed loss and yield risk with an early season spray (in the absence of pods). With a global population set to reach 9 billion by 2050, OSR is a key crop for human and animal consumption and is central to mitigating a future food and/or energy security crisis. OSR due to its relatively recent domestication suffers from a number of defects which limits its success as a modern day crop. Fully mature pods of oilseed rape are extremely prone to opening, resulting in seed loss (pod shatter). Typical losses vary between 15% and 25% of the potential yield, but reductions of up to 50% were estimated in seasons when weather conditions were poor prior to and during harvest. A reduction in the tendency of pods to opening is the number one trait sought by farmers and would serve to increase the proportion of the yield recovered by the combine harvester and thereby improve production efficiency and sustainability of OSR as alternative food and energy source. To address this industry-limiting problem, SMY offers a unique blue technology that modulates OSR pod physiology to control unsynchronized pod shatter leading to recovery of an additional 20% of the yield potential. +Across Europe and the world, the installation of underground utility services continues to grow. The ground beneath Europe’s cities streets, which already contains a myriad of pipelines and cables, is rapidly becoming over congested. For example, the city of Rome’s 3million inhabitants are serviced by 65,000km of buried pipes and cables. Due to this congestion, delivery of vital utilities through the installation and maintenance of new and existing underground services is becoming increasingly difficult and dangerous. The personnel working in the various utilities sectors (telecoms, water, gas, electricity etc.) face daily challenges with regard safe excavation for installation and maintenance. +Objective of the innovation project is the worldwide market introduction of a new generation of plant-derived biostimulants able to enhance crops yields without resorting to chemical inputs and to improve plant resilience to climate change in a stable, reliable way. +BIGAS ALSINA, a family owned company specialized on machinery manufacturing for the Food sector, aims to commercialize PigHeat, a novel technology that allows processing pig fur and pig roughing. +ELOXIRAS is an innovative water treatment concept specially developed to improve the productivity and environmental impact of marine RAS used by the exponentially growing aquaculture industry. +Low quality sanitation is a huge global, growing environmental and health problem with large costs to society. Poor hygiene +There is a huge number of small and medium sized sewage plants in and out of the European Union that cannot pass over urban sewage sludge for agricultural use in sufficient proportion (less than 50% in the EU), therefore the management of these sewage plants usually ask and receive permissions from environmental authorities for disposing the communal sludge in disused mines or dumps. Instead of disposal/landfilling – that regularly causes pollution of natural water resources – it would be more beneficial to produce sludge pellets. Such experiences drove us to create the InnoPellet technology, a self-supporting biofuel pellet producing system for treating communal sewage sludge that is economical in case of small scale production too. +No need for heat! NVP Energy presents the first to market, high-rate AD technology that successfully treats low strength wastewater (WW) at ambient temperatures (4 - 20°C). The low-temperature anaerobic digestion (Lt-AD) process provides a novel solution to Food and Drinks industrial sectors which produce large volumes of WW. The European milk treatment and processing sector alone generates over 367 billion litres annually which is typically treated using conventional aerobic processes. The latter treatment process is unsustainable. It results in high sludge yields, requires a large footprint on-site and is hugely reliant on fossil fuels for aeration. The Lt-AD technology produces negligible sludge volumes, presents a compact design, requires no heat input or biogas recirculation, and produces effluent of urban wastewater directive (UWWD) standard (< 125 mg/L COD) without post-aeration. Comparing Lt-AD to conventional aerobic treatment of WW from a typical dairy processing plant producing 2,000 m3 WW per day, Lt-AD can provide annual OPEX savings of €1,662,106 p.a over a payback period of 2.49 years that includes RHI revenue of €374,176. The low temperature operation of Lt-AD allows for 100% of the biogas produced being available for reuse or resale. Lt-AD also has a high impact on environmental savings through reduced greenhouse gas (GHG) emissions and lowered thermal energy and fossil fuels requirements. This Phase 2 project will allow NVP Energy install and commission a demonstrator plant and gain 8-12 months operational data. The results obtained, in conjunction with ETV assessment, will build the business case for each targeted market channel ahead of commercialisation. Other key project objectives include: commercialisation partner relationship development; promotional materials development; exploitation planned; assessment and protection of IP assets and project risk management. +Phase 1 of CoMPi aims to assess the feasibility of an innovative service on integrated coastal monitoring, with the use of low-cost autonomous observational technologies, that will allow the estimation of the future coastline displacements and the evolution of the shoreline, contributing in this way to the development of the Blue Growth Strategy. +The objective of HTC4WASTE is to demonstrate – at full scale and in a real market application – the technical and commercial excellence of Loritus’ unique, patented Hydrothermal Carbonisation (HTC) technology as a flexible organic waste recovery technology, suitable for converting organic waste streams into carbon neutral biocoal, carbon sequestering biochar, fertility products, water, and local thermal energy. +Our company, ALEPH, was founded in 1999 (Lurate Caccivio, Italy) as a Software House & Integrated Hardware textile solution company. Since then, we have become a respected large-format printer manufacturer and consumables+software provider. This comprehensive capability allowed us to deliver our textile-industry customers strong sets of solutions so they can turn their design ideas into material reality. Thus, we cover the two main bases for this industry: 1) design+development, marketing and support of CAD/CAM software; 2) development of the OEM plotters themselves. We are framed within the so-called “Digital Valley” at Lurate Caccivio industrial area. As a result of our 15-year experience, we offer our customers integrated ad-hoc solutions in hardware and software for the Textile Industry in the digital print field. +The most important innovation in marine fish aquaculture is the improvement of survival rate and development during the larval stage of the fish. Reasons are that the current nutritional quality of most common live food organisms (rotifers and Artemia nauplii) is inadequate leading to high mortality, deformations and sub-optimal growth during the larval phase of these fish species which limit the overall production. +The SME Planktonic has succeeded in cryopreserving marine crustacean nauplii (hereafter called CryoProduct) in large user-friendly entities, and to revive them as live individuals after thawing. The ease-of-use CryoProduct meets the nutritional requirements of fish larvae. A doubling in growth rate and a 25-30% shortening of the live feed period compared to a diet of the suboptimal live feed diets commonly used at marine hatcheries have been demonstrated (large-scale industrial trial, TRL6). With a well-functioning feeding protocol to be developed in the project period, it is expected that performances of the fish larvae will be even better. It will be put effort on optimizing the cryopreservation protocols to achieve a CryoProduct with even better quality than today for improving the performances of fish juveniles. A bio-security evaluation will be performed, and a screening of microorganisms will be needed for the registration of the CryoProduct. To successfully launch the CryoProduct into the EU market, it will be of major importance to scale up the production, to establish efficient logistic systems, identify end-users needs and to provide a reliable commercialisation plan for the best possible market introduction. As the CryoProduct has outstanding performances compared to today’s alternatives, we expect a market share of 50% of the live feed market on a longer term. This corresponds to a revenue of more than 100 million €. As the market grows 3-4% per year, the market size will double in about 20 years. It is a considerable aquaculture production in the EU. If the product meet the expectations, it will most probably be a major contribution to realize the production potential of marine fish in aquaculture in the EU. This will result in many thousand new jobs, and primarily in the Mediterranean region. The business innovation project fits well to the business strategy of Planktonic, and to the Horizon2020 SME-2 programme under the topic BG-12-2015. +The consortium of BioCurve and Quintín laid the groundwork for a new generation of condensing boilers, C-Heat. We have developed a biomass condensing boiler that has been internationally awarded (i.e. Expobiomasa, Spain; BoisEnergie d'Argent, France), surpassing from far the current state of art, in terms of performance (10% higher than high-end average boilers), ripping design (extremely compact with the best materials) and price (at least 20% less than comparable solutions). By taking advantage of the identified market opportunity, C-Heat will contribute to the growth of BioCurve and Quintín with a turnover of 11.4Mio. € and 37 new jobs by 2023 introducing an innovative technology powered by renewable organic sources (pellets) and available in a broad range of power outputs (25kW to 200kW). +The problem: Feeding an expected global population over 9 billion by 2050 is a daunting challenge. Aquaculture can play a major role in acting on this challenge while also meeting the so needed sustainable growth in food production. Salmon farms have become very large nurseries for sea lice – the main pathogen affecting salmon in net-pens (sea cages) – materializing in a huge threat both to the salmon farming industry and to wild salmon populations. Money spent by the Norwegian salmon farming sector on combating sea lice surpassed €500 million in 2015. Uncontrolled sea lice infestations are also affecting wildlife because wild juvenile salmon have to pass through the fish farms before they reach their offshore habitat. +The total global water demand is expected to rise by 35–60% until 2025 compared to the level of the year 2000, and could then double by 2050. Already today, Europe’s Mediterranean regions suffer from water scarcity and thereof foremost the food sector, accounting for 80% of freshwater demand while representing a decisive economic factor in that regions. Depending strongly on secure and sustainable water supply, green technologies for water treatment are needed to safeguard its economic prosperity. Against this background WTS has developed an innovative, energy-efficient and sustainable technology for decentralised seawater desalination to generate high-quality potable water cost-efficiently (by using special high performance heat exchanger technology) and environmentally-friendly (using waste heat as energy input and avoiding salt pollution). The system provided in a sea container is portable and easily scalable imitating a weather-like cycle. The WTS solution is advantageous related to state of the art technology w.r.t. energy use, environmental burden and costs. The key market application is decentralized water production for users or user groups with the need to consume water directly on site but face limitation on available freshwater resources (due to large distances or over-exploitation). The idea is to offer small-scale, distributed desalination for the extraction of raw water from saline water sources for 1) drinking water production and 2) process water production. It will be viable to use the WTS technology in Mediterranean coastal areas and islands. The global capacity of desalination plants is expected to grow with a CAGR of 11%. The project helps safeguard sustainability and secure food production in the Mediterranean countries and other water stressed regions. Objective is to assess the technical feasibility of Water4Food in relevant industrial environment as well as the economic justification in the first target markets (Greece, Cyprus, Malta). +SAKLAS will mature and validate a disruptive, cost-effective, and 100% sustainable Recirculating Aquaculture System [RAS] concept for farming two high-value fish species, Atlantic Salmon [AS] and Yellowtail Kingfish [YK], solving critical production problems related to current RAS-based farming methods. +In the UK, 6.2 million1 homes, in the Netherlands, 2.65 million2 homes built before the 1920s have uninsulated suspended timber floors, and based on our preliminary research across the EU (such as Belgium, NorthFrance, North-Germany) it is anticipated that further ~10 millions of homes have similar floor construction due the same climatic and ground-water conditions, resulting in a 18.3 million homes European market. +Domestic Hot Water (DHW), defined as human water needs (such as personal hygiene, toilet flushing, laundry, cooking and cleaning) is the dominating use of water in buildings and occurs in both residential (households) and non-residential (commercial, public and industrial) facilities. The residential water use represents 72% of the total water use in buildings, and 28% for non-residential buildings. +The iPURtech Nanoreactor effluent fluid treatment system recycles metal working fluids in an almost closed loop. iPURXL builds on 2 years successful sales and a growing list of enquiries to transfer the technology to other sectors, particularly for the treatment of water and other aqueous liquids. This will required scale up from our current >20-50 Litres per hour systems to those capable of processing >1000 in line with customer demand. This will enable us to sell into both single line and full site effluent treatment, ranging from small meat rendering plants up to full scale municipal waste water treatment. +Naturbo is a breakthrough air-cleaning technology that boosts over hundred times green walls’ air-purifying capacities, making plants clean everything traditional air filters can’t. A green wall is a wall covered with greenery that includes a water delivery system and a growing medium. The Naturbo process happens here, in the growth medium, where the plants’ roots are located. NaturVention has designed an active green wall that exploits the Naturbo technology absorbing the air impurities in the root zone of the plants to transform them by breaking them down into nutrients for the plants. This enables the replacement of the synthetic chemicals and microbes in the indoor air with nature’s own healthy chemicals. A Naturbo-powered green wall provides offices, schools, hospitals and many other indoor facilities, with the best possible indoor air quality. The effectiveness of this process is amazing: e.g., one single Naturbo green wall device has the air cleaning capacity of over 8000 houseplants, naturalizing a space the size of an average classroom. No ordinary green wall is capable of doing the same. Artificial intelligence remotely controls the Naturbo’s operation and its environment via remote connection to a cloud server. Thus, Naturbo’s functions are constantly adjustable when conditions like temperature or seasons change. This way, people in the space always have the best possible indoor air quality: the fresh and healthy air of the virgin Finnish forests is brought to thousands European city dwellers. +Bioplastics are an essential part of our efforts to reduce pollution and increase sustainability. Of these, the most ecoefficient bioplastic is PLA as it is biodegradable, requires 50% less energy and produces 10 times less emissions in comparison to standard thermoplastics like PET and PP. Furthermore, as it does not need to be recycled, it not only saves the energy and cost involved, but also the fact that only a fraction of the plastic produced reaches the recycling plant, the rest ending up in landfill or the sea. +The growing world population and the change in dietary patterns will dramatically increase the demand for food and feed, which will turn into a greater use of water, agriculture’s primary production factor. In a context exacerbated by the ongoing climate change, which results in farmers’ increasing need to irrigate cost-efficiently to stay competitive, policy makers around the globe are striving to implement strategies and new technologies for better use and conservation of water resources. However, while the introduction of new drip and sprinkler-based irrigation practices allowed substantial water savings, these came at the expenses of an increase of energy consumption and capital expenditure, making modernized irrigation less profitable. Leveraging on the successful launch of the Barsha Pump, a floating river pump for small-scale farmers throughout the world, which does not require any fuel, electricity to operate, aQysta will develop and demonstrate a large-scale system for canals (with a power of 1.5 kW, compared to 150 W for floating river pumps) that can serve the needs of irrigation communities in Europe. This will be achieved by integrating the patent-pending Barsha Pump with the Hydrostatic Pressure Wheel concept, which is up to 90% efficient, compared to only 29.6% maximum efficiency of floating waterwheels and has been successfully proven as a prototype in both lab conditions and in field. This novel HyPump system will be designed as a size-scalable concept, allowing for several variants according to the specific needs of the targeted customers in Europe, and will allow users to benefit from up to 6-times increase in agricultural yield (compared to rain-fed irrigation) and up to 70% savings on operating costs with respect to standard fuel or electric pumps. Furthermore, the proposed solution will drastically reduce the environmental footprint with respect to conventional pumps and is at least 2 times less capital intensive compared to solar alternative. +The IceChilling project will demonstrate an enhanced cooling system as an add-on solution for the air chilling and spray chilling methods current used by most poultry meat processors. Food safety and quality are the main concerns of consumers who demand more fresh foods, longer shelf-life and safer foods. Western consumers eat 30-50 kg of chicken meat per person/year and they prefer fresh meat over frozen. As up to 75% of chickens are contaminated with Camphylobacter, this is a major concern and challenge for the meat industry and health authorities. Increased size of chickens, along with high speed slaughterhouse output requires more efficient cooling than is possible with the currently used technology alone. The ThorIce add-on solution provides increased chilling efficiency that is applicable in most current facilities, without the need to build larger chilling chambers or installing of longer conveyer belts. Therefore, offering great savings for the meat processor, as well as improved food quality and safety. +The project intends to explore the feasibility of introducing to the market Sea Litter Critters, a compact, unmanned, renewables-powered and self sufficient marine litter collection and treatment vessel based on a patent pending device treating waste thermally with plasma technology and no harmful emissions. This device is designed to operate near the shores especially nearer tourist facilities substituting the mechanical collection of litter currently adopted. By picking up litter (plastic debris mostly) near the point of entry, Sea Litter Critters contribute to minimising the pollution risks linked to plastic in the sea, where plastic items become brittle and break down into small particles, but basically never dissolve. Such particles can be eaten by zooplankton thus enter the foodchain. Therefore picking up plastic debris while still intact and as soon as possible after their disposal supports and complement in the short term all the high level policy actions for litter prevention (minimisation of waste, use of biodegradable plastic, awareness raising, beach clean up days etc.). This study aims to check the attractiveness of the innovation to the market involving potential customers (coast towns, associations of tourist and fishing ports and marinas, representatives from the cruise and hotels industry, marine natural reserves authorities). The first markets identified are on the Mediterranean Sea, which is at the center of a very highly populated area of the World with many Countries relying mostly on tourism. Studies confirm that the Med has mostly marine litter derived from this economic activity and up to 80% of it originating from land. Italy, with its over 7600km long coastline and a strong dependency upon tourism, will be the first market, followed suit by France and Croatia and then Spain and Greece. After a 3 year phase to cover development, industrialisation and commercialisation, production is expected to start in 2019, with employment of 17 new staff. +90% of antifouling paints contain copper and secondary pesticides to make copper effective, which is toxic. But any company or individual who owns assets submerged to water for long periods need antifouling paints. There is increasing regulatory pressure from different governments that copper cannot be used for this reason anymore. A lot of research has gone into the subject with us being the first to find a real solution that is cheaper and more effective than copper as well as harmless to nature. +Business Opportunity:. Hydroponics is a closed-loop food production system in a controlled environment and grows without soil, also known as soilless growing. It is a sustainable solution for meeting growing demand of food consumption, reduces water waste (+70%) and contamination, increases crop production and enhances the community environmental-care feelings. Despite advantages, the process must be professionally controlled to avoid constant losses ending of users’ disappointment. +Our overall objective is to bring to the market a new solution which will not only reduce the environmental impact of blood produced in slaughterhouses, but optimize the protein production process for animal and human feed purposes too, in a reliable and cost-effective way. +Since their discovery, carbon nanotubes are one of the most acclaimed materials in both science and industry. But despite all their useful electrical properties, as well as their flexibility and strength, carbon nanotubes have proven very difficult to manipulate and arrange into patterns and so to be used in industrial applications. Carbon nanotube ink was one of the great answers found by researchers: they dispersed multi-walled carbon nanotubes in water creating ink to be used through commercial desktop inkjet printers. The so created conductive inks have unique physical and electronic properties: In our In-K Strain System we make use of these exceptional properties for strain sensing. +Slag is a by-product of metal smelting, and ~3.5 million tpa are produced globally in refining Non Ferrous Metals (NFM) and making alloys. Slag contains impurities and forms a protective crust of non-metallic & metallic oxides, and contains significant ‘free’ & alloyed metal (from 10 to 70% by weight). While slag can be used as aggregate, there are increasing concerns over ‘leaching’ of heavy metals into water courses from using these materials in civil engineering. While some metal can be recovered by re-melting slag (at very high temp), this is extremely expensive with very high energy burden which often makes recovery un-economic, but necessary. Landfill of slag is increasingly not an option. Our idea is to use a relatively new technology called ‘implosion’ to selectively break down and separate non-metallic components of slag from metallic particles. This will be combined with ultrasonic vibration sieving for accelerated recovery of metal from the finest fraction. This novel technology was originally developed to recycle waste glass by reducing it to fine ‘sand’, with uniform size and no ‘sharps’ compared to normal crushing techniques. This technology has not been applied commercially to other materials. Benefits to partners, endusers & society could be: +The food processing industry is a large water user worldwide. In particular, water is used as a cleaning source, conveyor of raw materials and cooling agent for quickly perishable commodities. Recently, the food industry is facing increasing pressure to ensure company activities follow environmentally sound protocols, but there is also pressure to increase profitability against competition. A primary concern of the food-industry is consumer safety. The use of alternative control means other than chemicals to reduce water microbial contamination and postharvest decay of fruit and vegetables is becoming increasingly important to enhance food safety and minimise residue levels in fresh produce while preserving water. Although water will always be an integral part of food processing, environmentally sound technologies for pollution prevention and water preservation have potential for cost-effective resource reduction practices. +"Problem: +Clean water, electricity and communication are crucial for human well-being and sustainable socioeconomic development. Their provision is in deficiency in most rural areas of the world and in specific Mediterranean areas of Europe. Yet, solutions for the above needs are developing very slowly due to lack of funds and the risks associated with payments for the supplied services. +The cost of installation of a typical offshore wind farm is approximately 40% to 50% more than that of an onshore wind farm and one of the main cost components is the underwater foundation. Thus, foundations installation, together with O&M costs, have been identified as interrelated R&D priorities for driving down offshore levelised cost of energy (LCOE) over the next 15 years. +Environmental monitoring is a key element of the EU agenda and its market is estimated to grow at a CAGR of 5.4% by 2018. Artys offers a disruptive Decision Support Service - DSS, to manage emergencies caused by extreme weather events, based on the analysis of Smart Rainfall System – SRS’ measurements. SRS is the only nowcasting system (IT patented, EU pending; Artys uniquely owes its rights) providing real-time spatial rainfall maps on a detailed scale, by means of the analysis of satellite television’s signals, received by commercial parabolic antennas. +Scubacraft has been developed with the explicit capability of being able to be a submerging vessel with the carrying capability to hold vital equipment to be used to perform testing and sampling. The vessel’s design has the optimum on-board capacity to carry up to three people, and designated space specifically created for the cargo of detection equipment, sensors and other kit. Introducing patented technology, Scubacraft will become the state of the art technology for use in underwater industrial applications for the energy industry sector, specifically offshore inspections for wind turbines. The applicability of Scubacraft can also be adopted for marine conservation and search and rescue operations. The current state-of-the-art method for performing underwater inspections uses divers to manually carry equipment to the inspection site and then perform the inspection. Scubacraft can revolutionise this way of inspecting by transporting a team of divers and equipment directly to the inspection site quicker, thereby creating a larger window of opportunity for the inspection to be performed, maximising inspection efficiencies and enabling earlier defect detection of structural integrities. +Meat processing industry generates an annual turnover of €160.6b in the EU-25, from which 50% corresponds to meat processing SMEs. Over the past years, the demand for sliced cured meat products has steadily grown driven by the higher acceptance of consumers for ready-to-eat products. Despite the growing market demand, operational costs of automated slicing lines are significant. Meat losses represent over 5% of the total costs, and are responsible for wasting tons of meat yearly in Europe. About t10,000 and t3,0000 of meat are annually lost during bacon and ham slicing operations, respectively, with an impact of over €110M. +This is a feasibility study to enable the development of a novel portable radar system that provides a simple non-invasive mechanism for inspecting railway infrastructure. At present different techniques are needed to inspect the ballast, track substructure and tunnels. TRACKSCAN would undertake these activities and more through non-invasive inspection. Within Europe ballast inspection requires digging a trench or driving plastic lined steel tubes into ballast with a pneumatic hammer. This is obviously impractical, time consuming, labour intensive and can miss ballast fouling. TRACKSCAN inspects all ballast so that maintenance can be targeted and effective. The feasibility study proposed intends to verify the technological and practical aspects of the system and ensure the business concept is sound. The system is described in terms of what can be achieved the science behind it is retained as confidential, as permitted by the call. The penetrating radar system has a rotating antenna which allows 360 degrees inspection and in any plane, this means that unlike other ballast inspection systems in the US, the TRACKSCAN system can extend beyond the vehicle width. The TRACKSCAN system is innovative, unique and we believe has a large market potential. The areas of inspection include: ballast; sub-ballast including drainage systems; water pipes and utilities, tunnel linings and tunnel track systems and bridge surface structures. +Biocides are extensively used across the agriculture and livestock sectors to prevent the proliferation of bacteria, algae, fungi and viruses. With sharpening regulations, environmental concerns, and the need for sustainable practices to ensure continued agriculture and food supply, the market is witnessing increased demand for safe and sustainable biocidal agents, while maintaining demanding requirements in cost, scalability, and availability. HPGen is a disruptive technology product, enabling for the first time on-demand, cost-effective production of hydrogen peroxide - an eco-friendly biocide and oxygenator, directly at the point of use, using only water, air and electricity as feedstock ! HPGen is set to displace presently used, increasingly regulated toxic chemical products in agriculture, and in turn in livestock sectors. By doing so, HPNow will address EU objectives in improved food and water safety, increased crop yields, and reduction of environmental impact, transport and handling of toxic agri-chemical agents. Implementing HPGen at agriculture and livestock farms in the EU and globally will substantially reduce direct and indirect biocide costs, and create a > EUR 2 billion market opportunity across the value chain. HPGen is being developed, and will be brought to market, by HPNow ApS, a Danish SME. The company has already attracted the attention and collaboration of multinational industry players, including an EU-based global leader in hydrogen peroxide production, three of the world’s leading micro irrigation companies, and one of the EU's largest specialty meat producers. These global firms will be contributing resources and knowhow to the project at their own cost, with their interest in later serving as HPGen channel partners - a key to our company's scalable go-to-market strategy. In Phase I commercial, technical, and production activities related to HPGen market introduction will be analyzed, and a comprehensive business plan will result. +The overall aim of TRILO-BWTS (Ballast Water Treatment System) is to bring to market a system for purification of ship ballast water based on Trilobite Microsystem AS' (TM) patented microfluidic technology for removal of small particles and microorganisms. +The worldwide most common type of marine foodborne intoxications is Ciguatera Fish Poisoning (CFP) caused by the consumption of fish contaminated with ciguatoxins (CTXs).It is estimated that affects up to 500,000 persons poisoned, annually. Only in USA it is estimated economic losses of up to 82 million $/year from HAB, related mainly to commercial fisheries impact (37%) and public health costs (45%). +Established in 1971, our company LEADING METAL MECHANIC SOLUTIONS S.L. is a Spanish specialist in design, development and manufacturing of precision components (machined, welded, forged or casted). In recent years, we have directed our business strategy to technology and knowledge-intensive sectors – Oil & Gas, Power plants, Airspace and Defense – where we have been continually striving to get involved in highly innovative projects, large-scale scientific initiatives and new materials. +Vitality Vector creates efficient applications of solid desiccants in thermodynamic processes. The main company focus is towards developing and commercialization of high-efficient desiccant based technology for a variety of HVAC and atmospheric water recovery applications. Vitality Vector has been recognized by the panel of experts (venture capital and industry insiders) at the global H2O challenge, which evaluates the innovation and uniqueness, sustainability and economic viability. As well as, the management team and the value proposition +The specific remit of this project is to launch an innovative, environmentally friendly, low-cost process to deink surface-printed plastic film. This process is focused on removing ink thus allowing recycled printed plastic film to be used for the manufacture of added-value products. +Water is used in almost all ceramic processes. The production cycle of porcelain stoneware in particular, as all wet production cycles, uses large quantities of water and generates considerable quantities of sludge. Currently, a line that processes 1.000.000 sq/m of tiles per year requires approximately 113.000.000 litres of water and generates sludge that contains more than 600 tons of abraded dust. It is estimated that the European ceramics industry, to produce approximately 1.300 million sqm of tiles, consumes more than 30.000 million cube meters of water, compared to the 8 million used by a city of approximately 300,000 inhabitants. In addition, the market demand in ceramic sector requires more and more products to have high intrinsic technical characteristics (reduced absorption, high surface hardness, abrasion resistance) that are typical of porcelain stoneware. These features are obtained through mechanical finishing treatment (polishing and lapping) of fired tiles. Unfortunately, there is a negative side to machining surfaces after firing: it implies the use of a considerable amount of water and generates and equally large amount of sludge. This generates waste, which in addition to material removed, also contains process water. +Loowatt’s objective is to develop a validated growth model for our innovative toilet system, and to bring Loowatt technology into continental European markets. The EU toilet hire market is worth £3bn/year and serves 2bn people annually, but relies on inefficient 1970s technologies. Loowatt has developed a toilet system that is waterless, chemical free and generates energy, and has been demonstrated at UK events. The patented Loowatt toilet uses biodegradable polymer film and a sealing system to contain waste. The polymer film and waste are then transported to energy-generating Anaerobic Digestion systems in existing Wastewater Treatment utility infrastructure or small-scale onsite systems. +The REvivED water project will establish electrodialysis (ED) as the new standard providing a source of safe, affordable, and cost-competitive drinking water, using less than half the energy required by state-of-the-art Reverse Osmosis (RO) plants. +Solar Water Solutions (SWS) is a company developing solar and wind powered reverse osmosis (RO) water desalination plants for remote islands and locations. In the core of the business is a patented innovation, ANVS technology which enables the use of solar panels or wind turbines without the need of using expensive batteries in RO desalination which is not possible with the current desalination plants. Furthermore, Solar Water Solutions water desalination plant has zero fuel costs and zero CO2 emissions. The business opportunity for Solar Water Solutions in remote islands and locations is potentially over a 100 million € yearly. SWS solution fits small water desalination plant market well. This is a niche in the total fresh water production market. +There is a trend towards encouraging biowaste management companies (solid waste and waste water treatment plants) and biowaste producers (shopping centres, food manufacturers, agricultural cooperatives and farms) to invest in composting plants in order to improve the treatment of organic waste. Additionally, laboratories are also installing composting facilities focussed on biomaterials testing taking into account that these materials, whose production is increasing year by year, need to be validated with regards to compostability requirements. +The project intends to explore the feasibility of introducing to the market a small milk steriliser unit based on a patent pending device developing high voltage (>100kV) nanopulsed electric discharge in liquids, to be used mainly by farmers selling directly their fresh dairy products through vending machines. +In times of declining fossil fuels and increasing problems caused by climate change, it is important to find alternative fuels to ensure an efficient and sustainable energy supply in the future. The use of wood or other energy crops especially the utilization of biomass residues is at the center of research because of the large application potential in the manufacturing of CO2-neutral biomass fuels. So, this proposal relates to the topic SIE 1 – 2014/2015. +CleanOil consists on the introduction into the market of an innovative filtration solution to treat and reuse the produced water (PW), a highly polluted oily wastewater which is the largest volume byproduct associated to oil and gas production. The solution will allow achieving up to 80% reduction of water demand for oil extraction through the reuse of up to 99% of the PW, and will be based on a proprietary product - ceramic nanomembranes with an innovative production process - installed in a fully integrated solution with the equipment, instrumentation and advanced fouling monitoring and control tools and software. +EOFARM project will cover the topic of Precision Farming (PF), one of the main applications of Earth Observation in the agriculture industry; it makes use of satellite images to help farmers in monitoring and managing crops from planting to harvesting. One of the main needs of farmers, in particular smaller ones which account for 80% of the UAA in EU27, is the possibility to increase yields while reducing the costs and environmental impacts of current crop production processes. +PROVALOR is a highly innovative Dutch SME dedicated to the development of functional foods located in Hoofddorp (The Netherlands) and employing 15 people. Since 1998 we have been working in processing food wastes, particularly from vegetable remnants and obtaining functional ingredients for human consumption. Our strategy focuses in obtaining high-value ingredients, and we have a vast know-how in this field having released to the market several successful products such as foodfibers refined from vegetables, a meat substitute made exclusively from vegetables (first without soja), and juices refined from vegetable remnants. +Low-grade waste heat (“LGWH”) is defined herein as being water of <120ºC, usually 80º-95ºC. Most power producers are making no use of their LGWH. The amount of waste heat produced worldwide every year is equivalent to 12 years of electricity consumption in the EU. There is currently no commercial solution to the LGWH problem. A commercial solution could have a global market of €440+ billion & reduce CO2 emissions by 700 million tonnes p.a. (c.2% decrease on 2014 levels). Up to 5,400 direct & indirect jobs could be created across Europe, and Europe’s energy security could be improved, as a result. +Food safety is actually one of the most burning problems in the agro-food sector. +The main objective of the project is to produce in a cost effective way new high quality seaweed iodine products and become market leaders in this niche market. The expected revenue in 5 years will be 3,3 million euro and we expect to increase our staff in 20 people. +Challenges facing the agricultural sector, such as climate change, shrinking land and water resources and land degradation, are a major threat to food security. Key in facing these challenges is better management of the existing land and water resources. Accurate and detailed data on crop and water conditions is essential to make this possible. Farmers need reliable data for efficient resource management, monitoring crop developments and understanding market conditions for planting decisions. Existing data solutions do not meet their needs. In developed countries, Smart Farming requires better information than currently available. In many less developed countries even the most basic information is not available, leading to poor agricultural practices and low productivity. +FIORDELISI, leader in the production of dehydrated vegetables in Italy and the first in the production of sun-dried and semi-dried tomatoes was created on 1960. Around 3,500,000 square meters of fields cultivated under Fiordelisi’s careful supervision and an annual production capacity 1,200 tons of sun-dried tomatoes, 700 tons of semi-dried tomatoes, 200 tons of artichokes and 500 tons of other vegetables show our business development. In order to offer always high quality food products, we start by a targeted seed selection and we use modern processes of sanitation and storage, which are constantly studied and improved. +Sewage treatment and the management of the waste is a major cost factor for communities, as sewage treatment plants are often the biggest consumers of electrical energy (share up to 20%). Energy, in particular electricity, is also a valuable resource. Its rational use saves not only money but also resources and helps to reduce CO2 emissions. Through the prohibition of the dumping of untreated sewage sludge and discussions on limitations of its agricultural exploitation, many wastewater treatment plant operators, wastewater associations and disposers must develop and implement new concepts for the treatment of sewage sludge. +Scope of the present proposal is the technical and economic feasibility evaluation of the industrial production and distribution into the EU market of a Modular Powered Reel Drive (PRD) for maritime operations of cable laying and retrieval. The proposed solution, compared to existing products, enables to operate with a significantly wider range of reels, both in terms of reel’s diameter and weight. The result is an innovation that increases safety, flexibility, efficiency and efficacy of maritime cable laying operations. +Seafood is a major source in the human diet of Omega 3 long-chain poly unsaturated fatty acids -such as eicosapentaenoic acid (EPA) and docosahexaenoic acid (DHA)- , which plays a very important role in human health. +TETRANE wants to further develop REVEN®, a product that automatically discovers, characterizes and helps solving nearly any software flaw that could be exploited by malicious hackers. REVEN represents the only answer to a growing social issue: cybersecurity for critical infrastructure and loss of revenue due to cyberattacks. +MAYIM will develop to industrial production stage a wastewater treatment integrated technology for industrial factories able to remove total suspended solids, and dissolved organic and inorganic substances simultaneously in one single treatment with two consecutive steps: magnetic settling and catalytic oxidation. +"R.Z.E.E. has a 25 years experience in sewerage system monitoring, wastewater treatment and remediation activities, providing since 2004 more than 95% of short term sewer flowrate monitoring services in Israel. +LC Paper 1881, SA is a family business located on the town of Besalú, in the eastern side of the Pyrenees. Today, LC Paper continues to develop technology in the tissue manufacturing sector to meet the needs of today's customers and society and create environmentally sustainable products. Every product that leaves our factory is certified with the Ecolabel, PSFC, FSC, ISO 14001 and ISO 14037 environmental policies. +ifoodbag addresses the challenge of the ‘last mile’ of the food retail industry with a unique, low-cost, low-footprint, reusable hybrid carrier bag system that enables food to be kept cold/frozen for up to 24 hours. +The objective of the SCALEPHA Project is to contribute to the protection and sustainable management of natural resources and ecosystems through a sustainable supply and use of raw materials in the industrial production of 100% biodegradable bio-plastic, in order to meet the needs of a growing global population within the sustainable limits of the planet's natural resources and eco-systems. +The slaughtering sector in the EU28 plays a key role in the meat industry. It embraces over 3,300 pig abattoirs, which process yearly 252 million pig carcasses, and generate a turnover of €73b. In a context of strong market competitiveness, and driven by the demand of meat processors, abattoirs are increasingly interested in new strategies to improve their product segmentation, which allow them to optimize the production value. +Waste water networks have been an organic growing system in a 200 year process of pipes, leads, wells, etc. As there was never a standardized inventory system, governments have no or only partial information of their underground (waste) water infrastructure. +Industrial Automation and control systems are vital for city critical infrastructures which are soft targets by excellence. Awareness of their vulnerability arose since 2009 with the worm Stuxnet damaging Iranian nuclear sites. +In order to reduce the environmental impact of waste produced by the Transport sector, the Directive ELV (End Life Vehicles) require an integrated approach that involves all the main players of the automotive chain. Within the transport sector particular attention is devoted to the life cycle of vehicles, including their disposal, that must reach well defined recovery targets. Critical issues remain unresolved, in particular the disposal of some car residues which still end up in landfill and in addition it is required a more efficient recovery of used tires. +The objective of SELAM is to commercialise and bring to market our exclusive and high-quality EU lobsters based on our disruptive and fully automated production process for lobster aqua and mariculture. The fully automated SELAM process is combining land-based aquaculture of hatched eggs through the larval (1-3) and juvenile (4-5) stages before released into sea-ranching ocean mariculture, where growth happens without human interference and at no cost. Combined with our novel business model for shellfish sea ranching this will allow us to bring a new product to the market – sustainable and high-quality farmed EU lobster with significant added value for the customer compared to existing wild-caught alternatives. +The Drinking Water Treatment Industry is subject to a stringent legislation regarding contaminants in water. Quality of water intended for human consumption and its monitoring are regulated under the drinking water directive 98/83/CE. Pesticides and heavy metals must be monitored and tested regularly with maximum allowable concentration of 0.1 μg/l for individual pesticides and 0.5 μg/l for the total amount of pesticides. The directive 2013/39/EU concerning emerging contaminants to be controlled in the field of water policy establishes what contaminants are identified for priority action at Union Level. +Crop protection measures are essential to prevent or reduce the productivity losses caused by pests and pathogens. They play a key role in achieving sustainable food production and optimising the use of agricultural resources. This proposal explores the properties of AMIXTM technology in producing inherently healthy plants and simultaneously enhancing the activity of tank-mixed pesticides, facilitating reduced application rates; addressing the call ‘SFS-8-2015’. +In long-term, cocoa production is faced with serious challenges. Changing weather conditions, low and decreasing yields, ageing cocoa farmers, competition with other cash crops, volatile prices and pest-related diseases are threatening the future supply of cocoa. Around 4 million tonnes of cocoa beans are required each year just to keep up with current demand. About 500 million new cocoa plants (5%) are required each year. With demand for cocoa on the rise, cocoa production is set to receive special attention in the next few years. Micropropagation has emerged as an important global agro-technology routinely used for rapid generation of high quality, uniform and disease-free planting material. Boereboom Invitro Portugal is a SME specialized in in vitro plant micropropagation that will be pioneer in in vitro cocoa plants micropropagation worldwide, aiming at enhancing profitability and growth performance through innovative and competitive products seizing Europe and global markets opportunities. The SME can answer the increase on demand by presenting a maximum production capacity of 1 million cocoa plants and a net profit of €600,000, enable a corporate growth of a total net profit of €1,200 million by 2020. Boereboom already has a two years agreement with Theobroma, to whom will sell the product initially. Nowadays, the main commercial available solution for cocoa propagation is seedling. In vitro micropropagation offers several advantages over seed propagation, resulting in reduced costs, improved market access and sustainable increases of consumption. A competing solution to Boereboom’s product is cocoa plant propagation by somatic embryogenesis. However the application of this method is still in a development phase. Boereboom’s team has the relevant know-how to implement the business, having created a project management structure that can ensure a competent management and a solid integration and communication throughout the whole project lifecycle. +The Desolenator team offer a novel technology that uses an original photovoltaic system to collect both thermal and electrical power in order to desalinate and purify water from any source. The off-grid household product is on track to become the most affordable and environmentally friendly method of distilling water from any source. We believe Desolenator can make a major contribution to global drinking water shortages. +Coffee is the first food commodity in the world, and a big part of it is consumed in form of expresso in bars, restaurants or coffee shops. However, current professional espresso coffee machines are based on technologies that have barely evolved in 100 years. These machines are extremely energy inefficient whilst also, due to the materials used internally in the machine, generate unhealthy metal impurities which are then passed to the customer in the drink. +The olive culture is widely distributed around the world, with more than 11 million ha of culture (the biggest area of permanent crop in the world) and it means a very important socio-economic resource due to its cultivation in dry areas, where it becomes one of the few economic opportunities for inhabitants. The olive fruit fly (Batrocea oleae) is considered the most devastating insect pest of olives in the world, being known in the Mediterranean region for over 2000 years and having reached every other olive oil production area throughout the time. It affects the most important competitiveness factor for this culture, the fruit quality, for both table olive and olive oil production, even with low infestation levels. All solutions developed until now have not achieved an optimal performance of the treatment together with no environmental side-effects and low cost for farmers. This is precisely the aim of DACUSNEX COMBI, a product joining the action of semiochemicals (a pheromone or other chemical that conveys a signal from one organism to another so as to modify the behaviour of the recipient organism) and specific traps. It has been already developed and tested in more than 6,000 ha of olive cultivation with perfect performance results, environmental soundness and a low cost, improving the performance of current options. The company, ECONEX, has been working for more than 25 years in the development of biocontrol solutions and is now facing the development of world commercialization of this product. To do that, the company needs to prepare for a fast and wide market uptake and to solve production constraints, finish the IP issues and develop the final commercial kit. Currently, the company has more than 8,000 customers in 27 countries and has 30 delegations in 11 different countries. With DACUSNEX COMBI, ECONEX expects to become the world leader in the control of the olive fruit fly. +New tools have to be developed to mitigate emissions of greenhouse gases and adapt to impacts of climate change with +Wind power has established itself in recent years as a clean alternative to conventional sources of electrical generation. Reduced costs and wider deployment, especially in the European market, have led over the past decade to its use at sea. Here the wind resource is larger and more constant, allowing higher unitary power turbines. However, the marine environment itself also imposes a number of restrictions and challenges. The technology that is being deployed now is fixed to the seabed, using different types of foundations, but a large amount of wind resources are in deeper waters, where floating solutions are needed. +YODFAT Engineers is a company specialized in providing novel, unconventional solutions to complex environmental and civil engineering challenges. In the last years the company has been working in the development of IRRISAVE system, an innovative solution: reaching up to 50% savings in water and energy through a system that will accessibly transform the irrigation networks management forever. IRRISAVE is an innovative smart technology that maximizes the efficiency in water application. IRRISAVE integrates an intelligent software to control the soil water level avoiding water wastage and improving sustainable crop production. Introducing IRRISAVE systems will provide a universal and friendly user technology that will have a huge impact on fertilizers and energy savings as well as avoiding water table pollution for all irrigation methods. This cost-effective and user friendly system can make end users (agri and urban systems) save up to 1.200€ per hectare yearly. +Development of novel probiotic solutions for specific illnesses and health problems, ex: Obesity, Depression, Crohn or Colitis diseases. +Packaging has improved the safety and quality of poultry products. Currently, MAP (Modified Atmosphere Packaging) is the most widely used packaging system. MAP seals fresh produce in a tray with a controlled atmosphere that contains gases that slow the degradation of the product. +The project intends to commercialize an integrated precision farming service model in the cloud to increase farming productivity and profitability in a sustainable way. Today, the majority of farmers manage their crop by gut feeling, leading to inappropriate fertilization, plant damage and unnecessary environmental impact. The AgriCloud system is the first holistic management approach, processing all available data from agronomic sensors, machinery and service companies and, backed by plant nutrition expert knowledge, will facilitate a targeted use of fertilisers and herbicides, efficient machinery utilisation and workflow management. +Thanks to CHAMPIPACK project, NEW PACK TECHNOLOGIES aims to irrupt in the European food packaging market with a new active container able to remarkably extend the champignon shelf life while its organoleptic properties are maintained. +With 630.000 beekeepers and 16 millions of hives, the apiculture sector is an important part of the EU agriculture. In addition, honeybees play the crucial ecosystem service of pollination, guaranteeing also the maintenance of the biodiversity. However, since a few decades, apiculture is facing important losses.However, since a few decades, apiculture is facing important losses due to abiotic and biotic factors. American foulbrood (AFB), caused by the spore-forming Paenibacillus larvae ssp. larvae is the most +Water is increasingly recognized as the most relevant resource of the 21th century, and UN Water recommends in sustainable water investments to prevent future conflicts. Significant social and economical impacts are associated with changes of water quality in inland waters. It is almost impossible to think, in the 21st Century, that water industries and governments would produce sustainable economic and ecological development plans on water without reasonable information on hand. Accordingly, an increasing demand from water industries, including aquaculture, water construction or dam operators, insurers, development banks and water agencies on actual or long-term historic water related information is observed. +SEPPELEC, S.L. is an engineering company, we are specialists in process engineering for drink factories and facilities. The ultimate goal we seek in ASEPTIC-VACBID project is to develop an automatic and aseptic equipment to empty concentrated juices out of aseptic bags. We have already developed a semi-automatic prototype achieving aseptic conditions to empty bags up to 25L. The objective of this project is to scale-up the aseptic system in a complete automatic equipment to empty the standard 250L and 1,500L bags used in the juice industry. By incorporating an ASEPTIC-VACBID system into the production process, capable to empty 18,000L of concentrate per hour, the juice industry will reduce energy consumption costs of €150,000 per year (1.324.422 kW), representing an improvement of 13% in the energy efficiency of the whole process. The use of water is reduced by 30.000L per hour and the automated equipment also reduce personal costs. +Aquablast Limited, www.aquablast.co.uk, are pioneers of Ultra High Pressure (UHP) waterjet technology with operating pressures up to 60,000 psi, which is now an industry standard for steel and concrete surface preparation and cutting. +FITOPLANCTON MARINO S.L. (FM) is one of the European leading companies in marine microalgae production and is the first microalgae production company in achieving the European Novel Food approval for the marine microalgae species Tetraselmis chuii. The company, currently involved in microalgae production for aquaculture, cosmetics and human nutrition, aims to position itself as a leading company in the production of high-value bioactive compounds for the food sector. +Meat industry generates an annual turnover of €203b in the EU-28, and employs 560,000 people. The slaughtering sector plays a key role within the meat industry, being represented by more than 4,500 companies, and generating a turnover of €73b. +Our object is to introduce resource efficiency solutions in the liquid detergent industry to minimize wasted efforts and expenses in producing and selling processes. Instead of sending end products, waterless dilute-ready form detergents will be forwarded to retail points and mini machines will instantly dilute, pack and serve customized end products to consumers directly at retail points. Expected outcomes of this project are economic competitiveness among global detergent players, easy access to remote markets, offering higher profit to retailers, delivering sustainable environment solutions, lower cost per wash and customized product offerings to end users. This promising project will be impactful in 3 dimensions: (1) natural environment and circular economy will benefit from our greener and more sustainable products and production processes, (2) individual consumers will have access to safer, more effective, more convenient, customized and still less expensive detergents, and (3) retailers will be able to provide their customers with individualized detergent solutions in a reliable, fast, efficient and appealing way with lower operational expenses. Emerging companies with leading advancements in terms of innovative formulations and sustainability technologies would be impacting fabric and home care industry. Every €1 spent on sanitation brings a €5 social return by keeping people healthy. Every €1 invested in eco-innovation brings €20 commercial return by leveraging brands’ market reception. In short, being supportive to our initial studies and draft plans, above facts show that it is both societally and commercially worth to invest in this innovation project. So the question is how to best tap into this opportunity rather than whether or not to pursue it. And the answer requires a robust feasibility and a comprehensive business plan, which we intend to accomplish via SME Instrument Phase 1 support. +Olive Mill Wastewater (OMW) is a highly polluted medium produced in large quantities during olive milling, rich of several polyphenolic compounds, which limit OMW biodegradability in conventional treatment processes. For olive oil producers OMW represents a problem and a disposal cost. Such polyphenols are interesting because of their tanning behavior and high antioxidant strength. The innovation proposed is to transform OMW from waste into raw material with a stabilization process, promoting also highly antioxidant phenols enrichment, to be used in tanning step as medium process in place of water and tannin chemicals, and as reaction medium to produce a new class of antioxidant tanning resin. +Today the application of fertilisers to agricultural crops is mainly based on calculations, estimations and recommendations and not on analyses of the actual demand of soil and plants. The resulting over-fertilisation has substantial disadvantages: pollutions of the groundwater, the eutrophication of surface water bodies, emissions of greenhouse gas from the soil, the depletion of finite natural resources, reduced yields and unnecessary expenses for fertilisers. It is estimated that up to 35 % of the applied fertiliser could be saved if a method for the quick and simple determination of the fertiliser demand existed. +The potato is excellently positioned to play a very important role in turning the high demand for resource-efficient and sustainable food production world-wide into an opportunity. The potato is the world’s number one non-grain food commodity, with an annual production reaching 374B kilo. The main current varieties of potato are in cultivation for many years due to the genetic complexity of the potato and inefficient breeding process. Breakthrough in potato breeding will enlarge the potential of potato as a food, feed and industrial crop. +ABD will aid transition to a resource efficient, circular economy via wide use of its disruptive, bioprocess intensification technology. This technology will cut business costs and help the EU exit economic crisis through job creation and exports. ABD’s first process is nitrification of used water, part of a €4.8 bn global market that we will access. We have developed a full-scale prototype package plant (TRL7) for tertiary nitrification with a UK licensee and have a second UK licensee for landfill leachate. Phase 1 funding is required to evaluate other European markets, identify additional licensees and potential end-users, and revise plans to obtain risk finance for business development. Phase 2 will develop a European network of licensees and end-users and build commercial prototypes (TRL9) for validation across Europe under different regional and climatic conditions, before exporting globally and developing new products. +"VEZ will be a zero emission boat for public transports in water cities, featuring mission and characteristics at least similar to the typical Venice ‘Vaporetto’, which can be considered a worldwide reference for public water transports. VEZ will be powered by a hybrid energy generation and management system based on hydrogen-air fuel cells, roof mounted PV cells and electric batteries, demonstrating the possibility of reaching “Zero emission” in boat services even in such stressing conditions as in the Venice canals. It will exploit the advances that the automotive industry drove on those technological areas, particularly in Europe. +Explicit I/S is seeking phase 1 funding in order to assess the commercial feasibility of Project Sense ― a drone technology system to monitoring sulphur emissions from ships during cruise. +Industrial Phycology (I-PHYC) has developed a wastewater treatment (WWT) process that can meet increasingly stricter discharge consents for the concentration of nitrogen (N) and phosphorus (P) in wastewater (WW) effluents. Elevated levels of N & P are linked to detrimental environmental events e.g. eutrophication. WWT operators require a treatment process that is able to remove nutrients in an energy efficient manner which current technology cannot meet. +The business of our company, IEG Technologie GmbH is soil remediation by using our groundwater circulation technologies. +The general objective of ULISENS project will be focused on the commercial development and further commercialization of an automatic early warning system able to detect and quantify Legionella species in water. The system integrates an innovative fast detection automatic module able to carry out “in situ” analysis in real-time based on information and communication technologies to minimise the time for obtaining results. ULISENS will have the following functionalities: +Mineral and metal resources are the foundation for our lives and lifestyles, and mining is still the primary method of their extraction. The sustainability in mining industry can be increased only through more intelligent, efficient and optimized processes that use reduced amount of energy, water and chemicals, and cause reduced amount of waste during different mining stages. Material flows in mining sector are huge. Globally, it is produced 5 billion tons of ore and 10 billion tons of side rock every year. About 70-80 % of mine energy consumption is used for transport, crushing and grinding – 2/3 of that in vain for side rock transportation, crushing and grinding. Even a small improvement in mining selectivity can achieve significant reduction to energy and water use and prevent waste formation. +Hiperbaric is a Spanish SME leader in the designing, manufacturing and commercialization of High Pressure Processing (HPP) machines on an industrial scale. HPP is an innovative processing technology for many types of foods (meat, seafood, vegetables, fruit products…) with an important growing potential over the traditional techniques such as thermal pasteurization. This non-thermal process, also called Cold Pressure Technology, inactivates microorganisms thanks to pressures up to 600 MPa (6000 bar or 87,000 psi), increasing food safety and shelf-life, keeping flavor, nutrients and product freshness. +In the next future, the global population growth will increase the demand for animal derived food. +The problem: OECD countries, on average, spend more than 2% of GDP on maintenance of road, rail, sewage, water, park, power, telecom, and harbour and airfield infrastructure. Specifically, sewage maintenance is an increasing cost for municipalities with the growing number of flash floods in Europe, which in turn puts enormous pressure on gullies to diverge water. It is expected that the occurrence of these events will continue to increase in the near future. Therefore, servicing and maintenance of this infrastructure will become even more important to prevent flooding. +Target market of GIDROM project is Greenhouse (Gh) Agriculture. A main problem of Gh farmers is monitoring the Gh environment to control plant diseases. Unchecked plant pathologies cause extensive crop damage and direct losses to farmers up to 15% of yearly incomes. The cost of pesticides and chemicals application is €2.000-5.000 / ha x year. Worldwide area dedicated to Gh agriculture production is about 800.000 ha of which 20% (160.000 ha) is situated in Europe (mainly in Spain, Turkey, Italy, Greece, Netherlands, France). +The objective of this project is the creation of Wavegardens all around the world. A Wavegarden is a place where surfers can practice surf: a lagoon in which a mechatronic device creates waves that could fulfil surfers expectations. According to the report “Blue Growth Scenarios and drivers for Sustainable Growth from the Oceans, Seas and Coasts, Third Interim Report, March 2012“ an important niche in coastline tourism is represented by nautical sports. For example, 10 million people in the world travel each year to wind and wave surfing destinations and the trend is growing, and 500 thousand more people every year practice this sport. Surfing is ranked in the top 20 most popular and fastest growing sports in all countries, cultures and demographics. The surfing industry, with an economic impact in the range of US$100 billion, is estimated to continue its growth in the years to come. The ‘stoke’, or feeling, of surfing, which has been limited to the lucky few who live near quality surfing waves, is now accessible to everyone thanks to Wavegarden. +Every year, approximately 30 million tonnes of food is wasted in Europe because it was not consumed before the expiry date. Currently, expiry date labels do not provide an accurate indication of the food’s freshness, instead reflecting the worst case scenario of how long a product should be safe to eat. FRESHINK is an ink product that changes colour as the food’s freshness status changes, allowing consumers to make decisions on whether to eat or dispose of the product, based on the real freshness status of the food. +Biofactoría Naturae et Salus is a biotechnological company created in 2011 which extracts healthy ingredients and additives from fungi and vegetables in order to produce high value foodstuffs. The company has 12 employees and an operational manufacturing biofactory of cutting edge technology. +The overall innovation project is intended to bring our novel ‘OrchardMan’ vision-based tree-fruit measurement technology to European market-readiness. This will provide in-field data based on cost-effective image capture technology and novel image processing algorithms, which can identify commercially relevant yield factors such as fruit size, growth and tree architecture automatically in the difficult environment of the orchard under variable weather and lighting conditions. The project will demonstrate that that the developed system has the capability to support precision horticultural management at the single tree level, reducing waste from growing undersize fruit by up to 50%, and increasing overall tree yields by up to 20%, This would give European users a cumulative benefit of €1bn from 500 units implemented over the first five years. +The German SME Kälte-Klima-Sachsen GmbH (KKS) has developed and field-tested in a relevant environment a prototype of a highly cost-efficient ECOiCE ammonia/water-absorption chiller system (AWA) driven by the otherwise not utilised low-exergy coupling product heat from combustion engines of combined heat and power plants (CHP) for the purpose of decentralised trigeneration of electricity, thermal heat and cold. Up to three quarters of electric power, and thus CO2, are saved when compared with chillers of comparable refrigeration capacity operating with the established cold steam compression refrigeration technology. The system, using driving heat below 100°C, provides adequately low temperatures of -6°C as usable cold for industrial purposes and storage of food. With the ECOiCE AWA the company primarily focuses on market segments with continuously high need of refrigeration like supermarkets, hotels, catering and food processing firms for the provision of cold at competitive prices in line with demand. +The raise of Fab Labs and maker spaces are creating new opportunities for citizen-driven innovation in a myriad domains ranging from open hardware to digital fabrication, community informatics, and participatory sensing. In the past five years, the broad availability of open hardware tools, the creation of online data sharing platforms, and access to maker spaces have fostered the design of low cost and open source sensors that independent communities of citizens can appropriate to engage in environmental action. By collectively measuring and making sense of changes in environmental phenomena citizens can become aware of how their lifestyle affects the ecosystem and be inspired to adopt more sustainable behaviours at the individual and community levels. +Frama is seeking phase 1 funding in order to assess the commercial feasibility of ClearSalmonLice - a new sustainable solution to combat the dreaded Sealice and Salmon lice. +From SAFTRA PHOTONICS we will bring to the market: NanoScreen, a portable sensing device that will detect in-situ contamination in any food matrix and water with most deleterious Persistent Organic Pollutants -POPs- at a cost-effective price and in a reduced time-span, with a simpler procedure when comparing to current methodologies, allowing multiplexing. +Vegetable proteins are more than ever an issue for future generations. Unfortunately, today’s Europe suffers from severe chronic dependence on protein imports from the American continent. Significant works are therefore underway among the industry’s manufacturers to reduce dependence and to develop products for human consumption based on vegetable proteins with superior characteristics. +“ProTreaT” is a 100% natural, cost-effective, resource efficient, multi-purpose and multi-beneficial solution for the removal of heavy metals from water, simultaneously benefitting environmental, social and economic objectives. The innovation of ProTreaT lies in the use of fish-derived proteins to thoroughly remove HM and other pollutants, such as bacteria and viruses, from primary water (i.e. suitable for human consumption and/or suitable for agriculture/breeding) and from industrial process and wastewater, and, therefore, from the food-chain. +Aquaculture has done reasonably well to supplement the expanding consumption of fish and seafood in the EU but has still been unable to have the desired impact because of the high set up, operating and maintenance costs; lack of space along the coastal shores; pollution and threats of diseases and eutrophication. Hence, we developed SubCage – a working proof of concept prototype to TRL 6 which is based on a patented Tension Leg Cage (TLC) technology capable of submerging fish cages to depths of up to 55 m at a controlled velocity based on the principle of wave ispersion. This prototype is a 12 m diameter fully submersible fish cage, which has been tested for 2 years in Crete using red porgy. This was successfully demonstrated as there were no issues during the operation and thus confirmed that SubCage satisfies all customer needs, such as: cost benefit solution for fish farming in unsheltered area; increase of fish quality; improvement of fish health and mortality rate. Despite the risk surrounding aquaculture in the unsheltered regions due to its environment; we proved that, by using SubCage, expanding production capabilities in such areas is feasible, commercially beneficial to farmers and can increase the value of the fish species. With the help of the SME instrument in scaling up our prototype to a 30-55 m diameter commercially acceptable fish cage, we would expect to contribute to an increase in fish price of up to 20% and additional increase in yield of up to 2% in comparison with surface cages. In comparison with competitor technologies, our prices will be several times lower by 30-40% as well as an estimated ROI being achievable in approximately 3 years. Within 5 years, we can humbly anticipate to enhance the production capacity of the EU by 2%. This translates to Refa Med Srl. deploying 402 SubCage units in the EU within 5 years, generating a revenue stream of over €80 million and helping create between 300 and 400 product-related full-time jobs. +The HYDRACTVAL project aims to design, test and demonstrate a leak-proof double seat control valve for the brewery and dairy industries. It will be based on and fully exploits the benefits of its core technology – a patented water-based hydraulic actuator with regulation functionality. The novel technology holds a range of clear advantages over compressed air: +BioCurve and Quintín laid the groundwork for a new generation of condensing boilers. We have developed a biomass condensing boiler that has been internationally awarded, which led C-Heat to surpass from far the current state of art, in terms of performance, ripping design and price. By taking advantage of the identified market opportunity, C-Heat will contribute to the growth of BioCurve and Quintín with a turnover of 6.7Mio. € and 20 new jobs by 2022 introducing an innovative technology powered by renewable organic sources and available in a broad range of power outputs.Former technologies for domestic heating are either unsuitable for moving forward towards a sustainable energy model across EU, or insufficient in terms of energy efficiency. In order to overcome these issues, Biocurve and Quintin have developed a cutting edge biomass boiler capable of working under condensing conditions. Thanks to a novel spiral heat exchanger that enhances 50% the exchange surface, C-Heat compact solution shows > 100% energy efficiency by capturing almost all latent heat of condensation of water vapor in the exhaust stream. In addition, an accurate control of the system enables low temperature applications (i.e. radiant floors). Until now, C-Heat has passed rigorous technical assessments, procuring international quality standards certifications. Also, several units are well operating in real condition, installed in private apartments since 2013. Therefore, an appropriate technology readiness level together with the unmet needs invite us to establish an ambitious but achievable aim for the next years: To become an international reference in the bio heating domestic and tertiary segments as well as the small scale industry. In fact, it does lead us to believe that C-Heat is potentially the best solution for the appointed market niches, if we notice its competitive price and its unique features. +The objective of the overall innovation project is to commercialise the service of composite patch (COMPA) repair for damaged ship pipes. COMPA pipe repair is a cost-effective alternative to the traditional method of repair of crack and corrosion damages in ship structures and pipes that occur frequently on various types of vessels. Total economic benefits of a COMPA repair over traditional methods are considerable. considering total savings, costs of COMPA are estimated to be up to 10 times lower than the costs of traditional methods of repair by steel cutting-welding-inserting. Additional advantages of the technology are reduced total repair costs, exclusion of flame, applicability to complex structures, shorter repair time, lower added weight and reduced maintenance. COMPA repair can thus support competitiveness of the ship repair sector in Europe. +JEKO Disain OÜ is an SME founded in Tartu Estonia in 2005. It is focused on industrial automation and measurements. The team consists of highly experienced engineers with expertise in mechanical engineering, optical sensors, electronics and software. JEKO owns a unique and proprietary flow-through liquid fluorescence sensor, SPECTRA-280™, that is currently used in Dialysis medical equipment. JEKO is exploring new ways how to adapt this sensor for the Food Industry, specifically for detecting concentrations of adulterant substances and assessing quality in milk, fruit juice and olive oil. JEKO sees a huge business opportunity through sales. The benefits of SPECTRA-280™ are on-line, high-accuracy, low-cost, contact-free and non-destructive. The uniqueness of SPECTRA-280™ solution will disrupt the Food Safety Market bringing new benefits to the industry and to the consumer. JEKO believes that SPECTRA-280™ will raise the Company’s profitability and sustainability and grow its workforce. JEKO requires further financing through SME Instrument to fund the commercialisation of the product in the three markets. In Phase 1 our specific objective is to prepare a clear Feasibility Study and Business Plan to determine the feasibility, possibility, risk, viability and sustainability of this new project. +The project aims at improving the quality and quantity of fish products by implementing ultrasound into the current processing lines of fresh fish. This technology is well-known to have significant effect on the rate of preservation, reducing the microbiological activity (99.9%) at low temperatures (0-3C), decreasing the processing times and costs, eliminating post-treatment of water waste and consuming less energy. Ultrasound is a green and non-toxic technology that will contribute to increase the commercial shelf life of fish products and will help fish processing companies in Europe to increase their production capacity. +Reduced herbicides! Ubiqutek presents the first to market agricultural electrical weed control, Ubiqutek Glide a cost-effective, safe to use and environmentally friendly solution to be integrated to existing technology manufacturer’s platforms. +Econboard is a startup company which introduces a design based on 2 owned patents, able to modify the nautical transport in internal and coastal waterways. +The United Nations predicts that by 2025 two-thirds of the world's population will suffer water shortages, especially in the developing world and the parched Middle East. In Europe, water is also a major concern in countries that fall under the Mediterranean basin such as Spain, Italy, Turkey, Greece, France and Israel. Fresh water is required not only for drinking and domestic purposes. Industry accounts for nearly 60% of fresh water withdrawals in the developed world and agriculture consumes 70% of fresh water supplies globally. Consequently, an adequate supply of good-quality water is a pre-requisite for economic and social progress, and competition for water poses a growing risk to the economy, communities and the ecosystems they rely on. +Current trends in the global construction market show a scenario in which sustainability and modularity are the predominant concepts. These trends are shifting the value chain of this sector towards economic, strong, fast and versatile construction systems. In this line, accessories for quick connection of pipes (fittings), known as push-fit fittings, have great advantages over conventional ones. However, their use is limited because they are neither universal (usable for any kind of pipe) nor compatible (valid to be used with pipes of any manufacturer). +The seed market will grow at a CAGR of 10.57% during the period 2014-2019 and is expected to increase to $24 billion from its current $14.52 billion value. Europe, with 3 of its countries (France, Germany and The Netherlands) as three of the top four seed exporters in the world includes nearly 7,200 seed companies and more than 50,000 employees. Production of high quality seeds can increase crop yield by 15-20%. Seed moisture content needs to be controlled to ensure high germination rates, thus high quality seeds. An optimum drying process with control of air’s relative humidity and temperature is needed to ensure harvested seed is at safe moisture content before storage or other purposes. Existing drying and cooling methods for seeds lack of control of these parameters, are not energy efficient and require high investment from farmers. Moreover, seed drying is one of the most energy consuming processes on farms, consuming as much energy as all field works together. With an efficient seed drying process, savings for farmers could be more than 50%. DryCoolerSeeds is able to dry and cool the seeds in a continuous monitored process with adaptation to climate variations, saving energy (99% of energy saved), time (2.5 less time needed than traditional dryers), ensuring the correct moisture content and temperature of seeds, resulting therefore in high quality seeds. Marcold’s technology is a step further in automation, simplification and costs savings (>60% compared to mix flow drying) being able to incorporate two different functions (drying and cooling) in a single machine surpassing the competition in the current market. The aim of the project is to build and demonstrate in real end user’s facilities our DryCoolerSeeds prototype adjusting the working parameters for effective conservation of seeds while ensuring a successful commercialization of the technology in Europe and Latin America that will drive Marcold into an exponential growth. +Wastewater by olive oil mills is offering GreenTech several opportunities to boost its competitiveness and growth across the Mediterranean regions, thanks to the scale up and further commercialisation of a new eco-innovative process and its green products, namely ReSpirA. +DelAgua Water Testing currently retails and distributes water testing equipment and consumables to over 150 countries globally. Our client base includes private, public sector and significant numbers of non-governmental organizations. +As the number of drones is increasing fast and new, very serious risks associated with them are emerging, the overall aim of this innovation project is to deliver world’s first integrated system – SAFESKY, dedicated for critical infrastructure and personal sphere monitoring and protection against aerial threats. +Compsule is a compostable capsule designed for instant espresso coffee machines such as ones produced by Lavazza and Nespresso, that operates at a high temperature and pressure. Compsule aims to contribute to reduce the amount of recyclable material being sent to landfills as a result of the increased use of capsuled coffee. In Italy alone over 1 billion plastic coffee capsules are consumed annually. Albeit being made of 100% recyclable materials, coffee capsules are barely recycled due to the time and effort required in cleaning and sorting the capsule’s components after use. Point Plastics have developed an innovative chemical additive that when mixed with bioplastics increases their thermal stability, making them compatible for extreme operational applications such as espresso coffee extraction. This process technology has a great impact on biobased polymer producers enabling a wider market share in fields impossible to target today. Compsules will be able to be disposed of with other food and green waste that is commonly collected by municipalities within the European Union, thus reducing the amount of waste being sent to landfills by hundreds of thousands of tonnes per year. For coffee producers the capsules will reduce their carbon footprint and respond to the demand of an increasingly environmentally conscious consumer base. For the capsule printing manufacturers, the Compsule does not impose any new machinery on their current production line as the Compsules can be manufactured similarly to the polymers currently used. For capsuled coffee drinkers the Compsules are both airtight and designed to fit user’s current machines, allowing them to be easily adopted. +Overuse of antibiotics in meat production causes human antimicrobial resistance, diseases and gut related disorders, leading to 1.2m life-threatening hospital infections and 19,000 deaths from MRSA-bacteria each year. The best solution is sustainable antibiotic free food production, improved food safety and nutrition value, wider use of probiotics and increased functional foods production. +The objective of Asalvo is to develop all the necessary stages to introduce in the market a bio-pesticide with a proved efficacy in different major pests affecting some of the most important cultures in the world. This bio-pesticide is able to replace the chemical pesticides that currently dominate on the market, providing a bio-product with improved environment and food safety features that avoids also the problems that legal restrictions on the use of chemicals are causing on farmers’ practices. The use of this product will provide farmers with effective and environment-friendly alternatives to cope with pests like aphids and trips even under more restricted environmental regulations. On the other hand, consumers would have healthier and safer food products available. +MET s.r.l. is an Italian SME focused on translating the sanitizing action of ozone into innovative industrial applications for transportation, agro-food and, recently, greenhouse crops. Greenhouse farms are very efficient food producers facing two major challenges: a) up to 15% crop losses due to several thousand pests caused by fungi, bacteria and viruses and b) the urgent need to comply with environmental European regulations (Integrated Pest Management) and with the growing demands of European consumers for healthier and environmentally sustainable food (i.e., organic agriculture). Existing solutions are insufficient to cover greenhouse farmer needs: Chemical phytosanitary products are inefficient (pests develop resistance), environmentally undesirable and unsafe for greenhouse workers and consumers (synthetic chemicals may leave toxic rests in food). Biopesticides, yet environmentally friendly, are excessively selective (each substance targets only one or few specific pests) thus ineffective for the broad pest spectrum faced by each greenhouse farmer. In this context, MET has developed O3MET: an innovative technology for spraying aqueous ozone (O3) for pest control and sanitation of greenhouse crops, taking advantage of the powerful oxidation-based (hence non-selective) anti-pathogen action of ozone. O3MET offers greenhouse farmers a solution that is: clean (self-disintegrated into oxygen in a few minutes); cost-effective (€6000/ha/year savings in chemicals and labour); environmentally sustainable (decreasing the need for polluting chemical pesticides); and safe for workers (remote ozone application by the operator from outside the greenhouse, and minimized post-application safety interval) and food consumers (ozone is residue-free and also extends vegetable shelf life). Once brought to industrial scale, O3MET would reach 10,000 ha of greenhouses (i.e., 2,000 farmers) in the EU/Mediterranean market, with a €60 million turnover accumulated in 5 years. +The project addresses the global need for a reliable mass production of a pathogen free live feed for the larval aquaculture industry. The new ready-to-use solution will be produced sustainably to supplement or replace Artemia, the most important current live feed. +Meeting demand for sustainable plant-based protein is set to be a crucial challenge for future food security. For that reason NapiFeryn BioTech (www.napiferyn.pl) aims to develop and commercialize technologies for the isolation of nutritional components from plant sources and in particular from legumes, cereals and oilseeds. To do so, co-founders rely on their extensive international experience, gained at world-class food companies as well as actively cooperating with academics and scientists. +Jensen Predictive Maintenance (JPM) is a system (to be developed) of on-line monitoring (internet-of-things) and fault location service (to be patented). The primary customer segment is district heating companies, world-wide. JPM fulfils a need of better monitoring and more accurate fault location of pressurized hot water pipes. The benefit is that weak sections of pipes can be located and replaced before leakage and failures. Pipes can be replaced just-in-time, at their end-of-life. Due to lack of condition monitoring pipes are replaced long time before end-of-life – waste of capital. +FuturaGraft is an SME from Israel. It has developed a high performing automated robot system to replace the existing time-consuming, laborious method of grafting plants. Plant grafting is the combination of a stronger root with a desired plant seedling and is used to improve the quality and performance of vegetables, flowers and herbs. +The Anyoon Rotary Engine is a concept engine that incorporates a unidirectional rotary design and obeys the Otto cycle to perfection. The engine allows for all four phases of the Otto cycle to be optimised for better efficiency without losing power. Anyoon can boast an exceptional break thermal efficiency of more than 78%, achieved by: constant volume heat addition (CVHA); a higher expansion ratio; internal cooling by water injection. CVHA can provide 50% more power while using the same amount of fuel and thereby more efficient (15% of total fuel energy is gained). By implementing a higher expansion ratio, through the Atkinson Cycle, a 30% improvement in efficiency is achieved (9% of total fuel energy). The internal cooling by water injection creates an 80% improvement in efficiency by reducing cooling loss by 50% (15% of total fuel energy) and exhaust loss by 30% (9% of total fuel energy). Assuming the efficiency of the current petrol engine is 30%; the new engine can provide efficiency of 78% (50+30+80=160%). As affect Anyoon can reduce fuel consumption by 1/3 and Co2 emissions by 50%. +Eco-efficient high-yield production of antioxidant compounds from microalgae +Food processing and production industry in the market of fresh organic food are facing with the challenges, in their working facilities, of improving food safety and quality while achieving a significant reduction in energy use and waste generation. The RLTProFood project aims at a feasibility assessment for a product, the RLT (Remote Lighting technology), that exploiting the energy saver, efficient, and environmental friendly LEDs (Light Emitting Diodes) technology, together with customized optical systems, delivers a lighting system for the food working facilities addressing such challenges. The product is a compact system, realized with sustainable components and with a structure that allows to remotely deliver different kinds of light (e.g., visible, and ultraviolet) without losing performance, according customers’ needs. It is easily installed in food industry facilities (e.g., production line or cooking oven), avoiding, with its design, the direct contact with the food. Currently it has two main settings: the LED visible light RLT contributes to optimize the process of lighting food facilities, the UV LED RLT provides a sterilization and germicidal treatment. The product aims to reach the EU market of organic fresh food producers and in particular of vegetables, fruits, dairy, bakery and fresh pasta, where the beneficial effects of the RLT in its two main configurations allow for energy and waste reduction, while improving food safety and quality. The feasibility assessment in the Phase 1 includes: (i) economic viability of the RLT system with its main settings in the EU organic fresh food market with market analysis and a commercialization plan and (ii) technical feasibility of the LED UV RLT developing a pilot application for testing the product in an industry environment. Phase 2 funding could improve the economic assessment of the product in the EU market and implement the pilot application for porting the LED UV RLT in the market. +Mastitis is an infection of the udder in dairy cattle. It is a major problem in the dairy industry, costing European farmers tens of millions of Euros annually. Milk somatic cell count (SCC) is used as a main indicator of mastitis, as the number of somatic cells in milk increases in response to infection in the udder. Krysium Technologies has developed and patented LacDetect® – an innovative, portable, economic test system allowing reliable and truly rapid detection of sub-clinical mastitis on-farm based on enumeration of SCCs via ATP-luminescence technology. This allows farm workers and veterinarians to make quick decisions on herd management and avoid significant costs associated with clinical mastitis. Furthermore, as SCC is also used as a measurement of milk quality, dairy producers base their milk pricing policy significantly on SCC values in raw milk. LacDetect® will enable recording of SCCs on-site for payment purposes. LacDetect® is at Technology Readiness Level 6. Initial testing has repeatedly shown results from our prototype test system compare very favourably with those from a major milk laboratory. In this Phase I project we intend to review the specification of LacDetect®, to ensure that production costs are reduced and that the end-product specification meets user requirements. We will re-contact and add commercial partners for field testing and commercializing plus explore other routes to market. On completion of Phase I we intend to progress to a Phase II project during which we will carry out final product development, scale-up manufacture, validation and final customer trials prior to commercial launch of LacDetect® initially in key EU markets. Completion of the overall project will deliver a one-minute, on-farm raw milk test system enabling EU farmers to detect problems in dairy cows early, enabling better antibiotic treatment decisions, improved production, reduction in costs, higher margins, better animal welfare and less environmental impact. +The world production of table olives has been increasing in the last few years. According to the International Olive Council (IOC), the 2013/2014 season could reach a production of 2.5 million tons of olives, 4% more than the previous season (2012/2013). Although the table olive production process has become a very high-tech industry in some aspects, one of the most important steps in the process, the debittering stage, is still very much based on the tradition, experience and subjectivity of the technicians who are in charge of it. This is mainly because, to date, there is no available system or tool aimed at improving this process. Thus, there is a clear need in the European table olive industry for technological innovations that can improve the table olive manufacturing processes, particularly in the debittering stage. TELEOLIVA, a new debittering-process monitoring system created by Global Olive, proposes a profound, ground-breaking invention that will lead the transformation of the European traditional table olive sector into an innovative, sustainable and optimized one. The system, which is a set of self-developed ICT tools capable of on-line and real time monitoring of the debittering process, aims to improve product quality by objectively determining the optimal duration of the debittering process stage while reducing production costs and reducing waste generation and negative environmental impacts by avoiding unnecessary input utilization. The main objective of this project is to determine the technical feasibility of the TELEOLIVA system at an industrial scale. At the same time, an economic and market feasibility assessment of the new tool will be conducted in order to prepare a business plan. TELEOLIVA´s target market includes all table olive manufacturers, beginning with those in Europe and eventually expanding worldwide. Currently, no high-tech solutions such as the TELEOLIVA system are offered by any competing company. +The project’s overriding aim is to develop a new system for the processing of semi-preserved anchovies, produced by a salting process, which allows creating a new kind of anchovy that has a reduced salt content, and does not need to be refrigerated for its retail and storage. +Laboratorios Dr. Larrasa. S.L is a privately owned biotechnology company founded in 2002. Led by a team of experts in veterinary, genetics and molecular biology (most of them PhDs), the company was born as a veterinary diagnostics laboratory to serve the needs of the farming industry. +The main objective of the INNOPROCITI proposal is the set up of a business plan for the development and selling of: +The project aims to develop an eco-innovative product: a zero emission autonomous (unmanned) robot-boat system intended for use as a monitoring station for quality & quantity of surface waters. The proposed innovative product (system) aims to contribute to solving two important issues: +Current utility PV installations require a large quantity of PV panels (semiconductors), space (land resources) and are consequently very capital intensive. +WHEYCOM was born to solve a twofold problem: the necessity of more healthy and sustainable sanitizers for washing of whole and fresh-cut F&V and the need to reduce the amount of waste coming from the cheese industry. +The Watergate project aims to bring to the market by 2017 the most competitive desalination solution for middle scale applications, a market niche accounting for 900 Million € of annual investment in 2014. Its major value-added lies in the unique combination of a total independence on fossil fuel, the solution requiring only solar energy, and very competitive water costs ranging between 0.80€ and 2€/m3 for applications above 100m3/day. +In the project ACT4INFRA a novel technology for an automated and remote controlled valves in public networks, such as water, gas or district heating, shall be commercialized on mass market scale. The technology addresses the public urban piping systems, e.g. for water, gas or district heating, which are today almost fully mechanical, manually controlled and extremely vulnerable with respect to criminal interventions or terroristic attacks. The ACT4INFRA technology has been developed within the past years by the German SME company 3S-Antriebe GmbH. Core of the innovation is a patented rotationally locked support plate (‘System Berliner Kappe’), which enables retrofitting of automated actuators in already existing valves without flanging and without a manhole. Additionally, the actuators have been optimized for low energy consumption and can operate fully decentralized powered by batteries. The entire system is controlled by safety-approved wireless communication systems, fulfilling the strong requirements of the German Federal Office for Information Security (BSI). No construction work for cabling and no switching cabinet is required. The ACT4INFRA system is a key enabling technology for low cost retrofitting in order to protect vital urban infrastructure against unauthorized access. This allows to implement smart and secure networks of piping systems. Within ACT4INFRA, 3S strives for systematic market development, distribution strategy and effective international commercialization of this technology on abroad, international mass markets. Thus, Phase 1 starts with a feasibility study , where market structure, customer needs, boundary conditions in different countries and geographical areas, cost structures, economy of scale and production strategies are analyzed. An updated business plan with these results will be prepared. +The objective of the proposed innovation project is the commercialization of the SmartTap Platform: An early-warning real-time water contamination monitoring system for the protection of water distribution systems against accidental or malicious chemical contamination events, provided as a service to utilities. Currently, water utilities rely on manual sampling to monitor water quality; however it may take days before a contamination event is detected. Competition relies on expensive sensors; as a result, most water utilities can only install such specialized sensors at very few locations within a network, thus offering reduced coverage. +The growing demand for sea food has resulted in the depletion of natural fisheries and it is estimated that 62% of the sea food will come from aquaculture farms by 2030. The profitable operation of aquaculture farms is being hindered by unbalanced and un-predictive fish feed amount, unreliable biomass estimation, fish escape and fish mortality. Fish feed alone represents 50% of the total operating costs of the fish pans and cages. Permanent and accurate estimation of fish size and weight is of significant importance in the fish farming industry for the provision of key data with which feeding, grading and harvesting operations are controlled. +Skeleton Technologies is a developer and manufacturer of high performance ultracapacitors, devices which store and deliver energy much more rapidly than conventional batteries. Their specialist technology, based on in-house-manufactured carbide derived carbon (CDC) electrodes, produces 2.5 times the power to weight ratio, subsequently a 40% reduction in costs, compared to the state of the art. +Biocontrol has been the fastest growing segment of the global plant protection business over the last few years. Its market is estimated at about 2,3 billion $, and within biologicals, the microbial products have been the fastest growing product type segment of biocontrol today. The multinational agricultural input companies such as the Crop Protection Multinationals have shown a strong interest in the biocontrol industry with highest priority in the microbial market segment. Regulatory Authorities are committed to encouraging the development and use of low risk biological pesticides as alternatives to conventional chemical pesticides than have shown to have a high toxicity. +The aim of this project is to boost European produced saffron through innovative cultivation and crop system. This system is composed by two innovations, once focuses about Floating trays system cultivation and another by the automatic crop system. This global system will increase the European producers competitiveness making better quality saffron, reducing production costs and using an environmentally sustainable cultivation method, in conclusion, one more resource-efficient and sustainable saffron production and processing. +The EASY Project has as its main objective the establishment of a technology that reflects the strategic guidelines for sustainable and profitable development of aquaculture in the EU. In order to follow these guidelines, this project has developed an innovative focused on the development of organic aquaculture feed formula. This formula completely excludes fishmeal and fish oil in its composition, and makes up to 50% cheaper production costs in our product (Tilapia fresh), allowing us to provide the end user, a product with high quality, traceability and profitability. Although Global aquaculture production is increasing, particularly Asian production, European production is stagnated. In EU Countries there is a strong trend in healthier and higher quality fish consumption, furthermore, consumer are requesting fast and comfortable food products without compromising its quality and safety. Obtaining raw material (spirulina and quinoa) inside of our facilities for the production of feed, along with the use of new technologies in the field of aquaponic, is undoubtedly the main key to the viability (feasibility) of EASY Project. The opportunity that this tool SME (Horizon 2020) offers drives the growth of the European inland aquaculture, create new jobs and position us as a world-leader in sustainable aquaculture. Analyzed by University of Murcia the results describe our fish as a very high quality due to the organoleptic properties, and perfectly suitable for the new market challenges. In Phase I our principal aim is to conduct a feasibility study including a business plan and market research with our partners regarding commercialization of the products, specially V range products (new formats), taking advantage over our Asian competitors, thus, becoming a leader in this growing market. +After a four-year program of research and development MONTELOEDER has identified highly active components in well-known and safe herbal extracts (Hibiscus sabdariffa and ; Lemon verbena) that preclinical results shows to modulate triglyceride accumulation, oxidative stress and inflammation in insulin-resistant adipocytes and their capacity to decrease body weight, serum cholesterol and triglycerides levels and hepatic steatosis signs in a hyperlipidemic mouse model subjected to high-fat diets. +Solar Energy for Food Industry +Sofi Filtration has developed a novel and innovative way to process industrial water filtration. A new style of filter that utilises Sofi’s patented technology and process is applicable to several different industry segments and particles as small as 0.5µm and outperforms traditional filters and methods for fine particle removal. +Impact Laboratories Ltd have developed a method for the cost efficient separation of mixed polymers, using a patent pending process of vertically arranged blades oscillating to produce separation. +With this CLEANPACK project we, TECSELOR, will put in the market a thermoforming machine that manufactures ultraclean packaging trays, oriented to fresh food products. The machine can be used for aseptic tray manufacturing or for the whole process of food packaging, coupling the adequate module (vacuum, modified atmosphere, etc). Our aim is to reduce the presence of pathogens and spoilage organisms in fresh packed foods, having the biggest impact in foods that are consumed without a cooking step, offering a cost-effective, eco-innovative and energy saving alternative to clean rooms, which are very useful in food industry but expensive to build and maintain. +BlueMorph have developed a unique patented waterless sanitation system for steel vessels and large tanks used in the beverage production process (to be used by wineries, breweries, milk and juice producers,...). The system is based on a UV (UltraViolet) light capable of full sanitisation that fully replaces current chemical, water and steam methods. The system uses germicidal ultraviolet light to inactivate and kill microorganisms. By eliminating the use of water and chemicals BlueMorph is very environmentally friendly and low cost. +Safe drinking water is essentially a global concern, thus resulting in a considerably large market for water quality monitoring. Besides, potential terrorists might threaten water infrastructure in European cities, since poisoning the tap water is a low-cost attack that easily generates social panic and economic loss to the society. Due to lack of the ideal early warning tools on water safety, large amount of routine sampling and testing have to be done frequently to fight against possible CBRN threats on urban water supply. This project addresses feasibility study for the technical and economic viability of Biological Water Alarm System (BiWAS): An innovative low-cost early warning device for monitoring of drinking water safety over a broad spectrum of harmful substances, including (1) acute toxicant chemicals, (2) chronic carcinogenic chemicals, and (3) waterborne pathogens. The innovative content of BiWAS lies in the miniaturisation and integration with multidisciplinary knowledge, which makes BiWAS a continuous, automatic and portable device working for long period with only annually or biannually maintenance. The potential customers include public water suppliers, household users, hospitals, hotels, culinary and food industries, etc. An early warning system against CBRN threats in drinking water can be realized without more investment. A feasibility assessment on BiWAS product under Phase 1 includes market investigation, business plan development, risk assessment, intellectual property management and innovation strategy development. In the potential Phase 2, a commercializable prototype of BiWAS will be expected, which can be probably the first low-cost and broad-spectrum early warning device for water safety. With the outcome of Phase 1, it will guide the European companies towards the leading role of the global water quality monitoring techniques, and open a big door to the large market of global water quality monitoring, from Europe to the world. +OOVAL develops, manufactures and markets hydraulic control valves for irrigation, water networks, fire extinguishing systems, and industrial manufacturing applications. As an Israeli company we excel in dealing with the water scarcity problem, being a world leader country increasing the efficiency of water management . Water losses in municipalities and industry, also called Non-Revenue Water (NRW), are largely attributed (up to 50%) to pipes faults such as leaks and bursts. The total loss of NRW worldwide is €10.2 billion according to the World Bank estimations. Each year more than 32 billion m3 of treated water are lost through leakage from distribution networks. Pressure control is an effective way to reduce such burst and leakage in water distribution systems. We have developed TECOVAL, the first hydraulic all-purpose control valve allowing pressure control with 40% head loss reduction. The objective of the project is the industrial development (from TRL6 to TRL9) of a range of control valves (8” to 16”) that includes: +The end users of solvent based varnishes for High Vacuum Metallization (HVM) are since long searching for solutions at a lower environmental impact, unlocking full green growth potential, at the same performances level of current products. Early results of independent research conducted from MARBO, permitted to foresee a true revolution in the sector, empowered by water-based formulation. Technological Feasibility, Market Assessment, Business Models and Plans objectives of the Wave-Metal project are oriented to permit the implementation of the project results into real business cases. +"""PENTABIOL has developed and tested PROBISAN, a fermented fodder for nutrition of animals that overtakes the performance of any other fodder in the market. The most strict and unbiased product test has been undertaken on a single commercial swine farm in Spain comparing PROBISAN, DIAMOND V (the leading product in the market) and the best performing fodder ever experienced in the farm, namely PROBIO, which was a fodder specifically engineered for this farm using probiotic additives. Each fodder was used to feed during the same period of a population of 1.575 piglets (252 each fodder).PROBISAN piglets ate 3,3% less and grew 4% more than PROBIO piglets, and ate 10% less and grew 4% more than DIAMOND V piglets. Considering both effects PROBISAN offers 14% more yield than the market leader and 7,3% more yield than the best specially engineered product. Furthermore the average deviation of results with the group of 7 independent tests showed that PROBISAN is much more stable than the other fodders."" +TEKFRIGO was founded in 1997 by Alessandro Aldini taking over the activity of the family owned business ALCA Srl. Nowadays, TEKFRIGO is one of the leading Italian refrigeration, condensing units and cooling equipment providers to important customers such as CARPIGIANI SPA, the world leader manufacturer of ice cream machines. Since 2007 we have been working to develop a novel green heat recovery system for professional laundry systems (ReHeat) by applying the heat pump water condensed dryer principle. +The world is sitting on a ‘CRT mountain’; For TVs and monitors, Cathode Ray Tubes have been the main screen technology, up until the revolutionary change to LCD and plasma screens that has recently taken place. Consequently, the current CRT population (1.9 billion screens; 500 million of them in Europe) is becoming obsolete and will require processing (not landfill) according to WEEE regulations, since the high proportion of lead in the glass means that landfills have an unacceptable risk of lead leaching into groundwater. The very low manufacturing rates for new CRT worldwide now mean that recycling the glass back into CRTs is no longer an option, and the only alternatives to avoid landfill have been to use the glass as a smelting flux (85% of it remains as a toxic slag), or using foundry temperatures (1000°C) melt extraction for the lead, which is extremely energy and CO2 costly, and at best produces an 80% co-stream of low value glass. +Every year, nearly 360 million pigs, sheep, goats and cattle as well as several billion poultry are killed in EU slaughterhouses according to the FAO. Processing feedstock produces large amounts of animal waste and wastewaters, more than 16 million tons each year in Europe. These waste are a key challenge as they cannot be treated as standard waste due to banning legislation and technical issues. +Honey crystallizan is a natural phenomenon by which honey turns from liquid to a semi-solid state obtaining cloud, thick and grainy. Nearly all honey crystallizes, some while still in the comb, others within a few days, weeks or months after being extracted. Honey crystallization is little understood by the consuming public. Many consumers assume incorrectly that crystallized honey is spoiled or has been adulterated and they either not purchase it or discard it. Other consumers directly prefer liquid honey. +Today’s current food system is unsustainable economically, environmentally and socially. Given finite arable land, fuel and water supplies, innovative self-sufficient farming modules are a solution to contribute to mitigate this global challenge. +"Cascade, a spin-off of LPRL laboratory, is a French SME located in Clamart founded by Mr Frederic PEILLERON in 2012. +The way to more resource-efficiency goes through the stomach in many ways: Resource-efficient grocery production is a core challenge of sustainable development. Food that is not being eaten, destroy ecological and economic resources and aggravate social conflicts. +The project is about designing, manufacturing and marketing a range of stand-alone power supply products based on pico-turbines able to efficiently produce on-line and deliver the few tens to hundreds of watts needed by the process and quality control equipment of the water supply networks. +"Hydrowashr has developed an all-in-one washing device which will save up to 99% of water each time someone uses it for washing their hands. Next to that it is a disruptive innovation in the sanitary market, in the light of environmental, economical, hygienically and aesthetic values. +Pig meat is the preferred meat in Europe but its production has a dramatic environmental burden both in the local neighbour populations and in overall air pollution impact. Pig farming is at the center of clear conflict of interests, as there is a constant market drive to increase production efficiency, while society demands for an environmentally cleaner and more animal-friendly pig farming industry. +The objective of SLIGHT GRANULATION project is to validate on the market an innovative production process, reducing both the use of water in ceramic industrial processes and the energy consumption. The new process will address a specific phase of production chain (i.e. granulation), reducing by 40% the use of water and completely cutting off the energy consumption in this phase. +The fruit and vegetable processing market is growing exponentially driven by the increasing demand of frozen products, juices and ready-to-use products. In this context, industries that process very sensitive fruits are facing great difficulties/challenges to increase their competitiveness. Indeed, this segment is unable to fully benefit from the industrial technologies like automation and artificial vision - already used in other segments - to increase the productivity, the quality and the safety of the final product as well as working conditions. +According to reports by the US ‘National Institutes of Health’ (NIH), most western populations are magnesium deficient. Magnesium deficiency can lead to a number of health problems such as high blood pressure, heart disease, stroke, osteoporosis and arthritis, to name only a few. Sulphate is also essential for many biological processes and at the same time sulfation is a major pathway in detoxifying drugs and environmental contaminants. According to the School of Biosciences of the University of Birmingham, sulphate is not easily absorbed across the gut wall. The recommended treatment up to now for absorbing these nutrients was bathing in Epsom salts, a procedure that calls for a considerable amount of time, water and electrical energy. +Olive oil production uses considerable volumes of water (50L/100kg olives) in European Mediterranean countries where this resource is scarce (Spain, Italy and Greece). The processes used by this sector leads to significant wastewater containing phenols and polyphenols. The EU Legal Framework sets the need of an efficient solution that reduces water use, improves water quality and recycle the waste produced. However the benefit margin of olive oil producers is very low, making production without support uneconomic for farmers. As yet, there are no cost- effective techniques/ technologies for combating this negative environmental impact of this sector. +The main aim of this proposal is to generate an updated revision of GTZ’s initial Business Plan (BP I), to overcome the main challenges detected for the successful MicroLAB market launch. The following aspects will be pursued: 1) specific marketing tools and sales strategy (Europe, North and South America, Asia) devoted to feedstock producers and micro & small food companies (≤50 employees), to speed up, the market share achievement (2,6%); 2) product innovation policy to assure the company growth in the food safety business; 3) technical feasibility study for a cost-effective production process (<5 €/device) and its lay-out definition; 4) revision of the organization growth plans to assure its sustainability; 5) and an updated review of the economical and financial plans. The food sector is the second largest manufacturing industry micro, small and medium sized companies suppose the 99. The business size profile has a relevant impact on the deployment of the safety assurance measures and the feedstock sustainable production (minimization of waste and GHGE). Due to the micro and most of the small companies’ size (< 20 employees), the accomplishment of the mandatory plans for quality and food safety assurance, makes of it a big hurdle difficult to overcome. Alternative rapid kits have been developed to facilitate food pathogen assessment, but none of them, covers the whole microbial detection routine in an easy and affordable way. So, micro and small food companies ought to outsource this service (18-20 €/test, 8,500 €/year), with the added drawback of relying a very sensitive issue in third parties. The small dairy, meat and poultry farms, can’t cover these controls, being assumed by the secondary transformers, with the additional costs of logistics, cross-contamination and factory’s stops, if feedstock refuse. The solution has been carefully considered, and it’s a challenge that GTZ is eager to assume, by the manufacture and the market launch of MicroLAB. +In recent years, we have been witnessing a boom of gastronomic themes and a constant and continuous emergence of new and sophisticated food products in contrast with the simplicity of the traditional cuisine. There are around 2,000 Michelin Star restaurants and more than 20,000 high standing restaurants all over the world. The competitiveness in this sector is very high and there is a necessity of differentiation from the competence, looking for new flavours, aromas and textures that allow their dishes to have high value-added. +The purpose of the project is the large-scale commercialization of an integral both preventive and predictive maintenance service by means of cleaning and inspection actions of wind turbines for the increase of its energy efficiency, based on a monitored robotic platform. +FIBandCO aims to develop a new exotic veneer made from banana plan trunks as a clean alternative to wood: GREEN BLADE®, an exceptional coating, 100% natural and eco-designed. +The DEFLUG project will develop and commercialise a fully automatic flue gas filtration system for industrial and private customers. MyCapital OÜ in cooperation with its scientific, technical and marketing partners will introduce a very cost-effective and environmentally friendly flue gas purification solution that is based on the company´s patented substance. +Nordic Ground Support Equipment AB (NGSE) plans to install 5 to 10 demonstration units of the world´s first fully automatic, battery powered aircraft washing robot, at 3 to 5 different airports within the EU (i.e. operational environment). Compared to state of the art, the robot will decrease washing time by approx. 40-60%. The robot will also decrease water and chemical consumption by approx. 20-30%. This will have a positive impact on EU aviation industry since it will allow them to lower the down time of airplanes and decrease congestion at the airports. +Europe's consumers are increasingly requesting products that are organically and sustainably produced. At the same time, Europe has been lacking incentives to develop and bring to markets new marine products, without increasing pressure on natural resources. +Natural gas is the world’s fastest growing fossil fuel with global consumption expected to increase by 70%, from 4 tn m3 in 2014 to 7 tn by 2040. Raw natural gas varies in composition and also contains undesirable impurities and contaminants, including water, CO2, nitrogen and hydrogen sulphide (H2S). Unconventional sources such as shale gas have an even greater variance. Despite this, the composition of gas delivered to transmission pipelines has to be tightly controlled by the gas producers to meet stringent quality standards and specifications. +A water distribution network is an important part of the infrastructure. In every water pipe system around the world more than 20% of the produced water is lost before it reaches the consumer, corresponding to a production cost of more than 20 M€ every day. It is a challenge to find small leakages before they became major and causing an emergency. +The overall objective of the project is to commercialize the unique technology for production of 98% concentrated HTP. This will be developed and exploited twofold: (2) Construction and installation of the technology line located at our premises and distribution of 98% HTP to the customers; (2) Construction and application of a container based mobile plant that will be able to produce HTP at the client’s premises. This solution will be tailored for the customers with regular large demand for the HTP and to whom the delivery of the ready product will be problematic due to formal and legal constraints concerning transportation limitations. +By 2050, the size of wave and tidal energy is expected to reach an installed capacity of 100GW, which will be able to power 66 million European homes and also enable the EU to meet its target of reducing emission of green-house gases by 80-95% below 1990 levels. +75% of imports and exports and 37% of the internal trade of the EU takes place through seaports. From Delco TS, we envisaged UltraBoat as a durable and reliable solution to avoid the formation of fouling (bio-fouling) in ships (attachment of marine animal and plants to the surface of underwater parts of the vessel). This may seem a minor problem but every ship owner knows about the importance of making an adequate choice of antifouling treatments due to associated operating costs. The formation of fouling on ships increases the surface roughness of the hull, which leads to increased fuel consumption. After six months, a ship without an appropriate antifouling system can suffer a 40% increase in fuel consumption to maintain normal speed. +Ostomy drainage pouches are medical devices made of heavy-duty plastic used to collect waste from a surgically diverted colon, ileum or urinary system. Unfortunately, their disposal can cause users psychological, social, and work-related problems, negatively affecting their quality of life. Soiled ostomy devices become domestic waste and the heavy-duty plastic is non-bio-compostable and so ends up at landfill sites with over 850 million ostomy pouches disposed in landfills annually across the EU representing more than 100,000 tonnes of liquid and plastic waste. +Natural Machines is a SME that has created the first 3D food printer that works with sweet and savory ingredients. We are focused on helping people get back to home cooking, back to healthy food, by bringing the food processing plant to the home kitchens, giving an eco-efficient alternative to traditional food processing, reducing food waste to zero and with significant savings in energy and packaging needed with no need to spend time cooking or knowing how to do it. Following the lean startup model, we introduced a model for B2B customers that allow them to create dishes, decorations, customizations, suitable for hospitals, restaurants, bakeries, etc. In order to get our product to the home kitchens, users have requested two main features that go far beyond 3D printing technology. The two systems are a new cooking technology that uses just a fraction of the energy used by traditional ovens and microwave ovens and a prefilled capsule system. Both systems working together will convert our new device in an optimised sustainable mini food processing plant at home. The cooking system provides a very granular control of the temperature of the food being cooked, allowing to preserve the nutritional properties of the ingredients and cook according to the user tastes. This system can work also as a standalone device, which opens also new OEM and licensing opportunities for our company. It provides also a safer operation, as no element in the device will be heated to a point of causing harm, as compared to an oven. From a business perspective, reaching the mass market (home kitchens) will allow us to more tan double current revenue forecasts according to initial interest in USA, Europe and Asia, and to introduce new business models, like capsule licensing that will generate new revenue sources. We expect the feasibility study to provide us with a better market insight and a complete business plan for bringing our device to the market. +Climote is a multi-award winning remote controlled home heating hub. With Climote, you can control your home heating from anywhere using our full suite of remote services. +The objective of the proposed project is to devise a new type of spectrometer for measuring the volume scattering function (VSF) in aquatic environments – initially in seas and oceans, but later also in other bodies of water. As the VSF is a fundamental inherent optical property of the aquatic environment, the proposed novel tool will be of interest to virtually all private and public organisations that gather, analyse and make use of information related to sea and ocean environments.The fields of climatology, marine research and optical communication and their various sub-sectors can be outlined as key groups benefitting from such a tool. +Magpie Polymers, a start-up founded in 2011, produces proprietary filtration technology with extreme selectivity and high performance in difficult to treat waste or process water. Selectively removing metals from complex effluents creates value for industries dealing with precious metals such as palladium, platinum, iridium, rhodium and gold. The main focus of commercial development of the SME is the precious metal refining industry, with growth potential in precious metal mining. +Each year, tens of thousands of MW of Steam Turbine (ST) power generation capacity are installed globally. For all of these installations it is necessary to condense the steam at the outlet of the ST. The global market for condensers for this application in 2011 was estimated at $1.9B and it is expected to grow at a Compound Annual Growth Rate of 5.2% to reach $3.3B by 2030. +Efficient municipal wastewater treatment, such as the systems currently in place in most European municipalities, produces vast amounts of sewage sludge. The latest data collected show a yearly production of 9.637 thousands of tons in the EU28 countries. Sludge treatment issues are often neglected in comparison with water-related parameters which results in serious technical difficulties and highly expensive disposal methods. As a result, an energy efficient, environmentally sound and economically viable process for sludge disposal hardly exists. +Poultry farming worldwide is among the largest sectors of animal husbandry for food production. As with other bio-farming activities poultry farming is associated with manure production. In contrast with other manure types poultry manure is very rich in nutrients as nitrogen & phosphorus and also in organic material. +Nova Innovation is a leading designer and manufacturer of tidal turbines. We have designed, built, deployed and are currently operating a grid-connected turbine in Scotland. In this project we will conduct a feasibility study into the market potential for our direct-drive tidal turbine design. +The innovation project consists in a system of floating photovoltaic panels for the decentralized generation and stocking of energy at off shore fish farms (and more generally sea activities with necessity of electricity). The project FLOTA (Floating Offshore Photovoltaic systems) addresses the industrial problem of the autonomous supply of sustainable and green energy for the quickly increasing industrial branch of fish farms. +Today, because of the large dimensions and costs of finishing machines, most printing houses cannot be equipped with a full production line and, after digital printing, they must send fabrics to third companies for finishing and for specific functionalizations. For European SMEs, this leads a general increase of production time and costs and a further threat to competitiveness against the larger and mass-production structured Far East companies. All over Europe, several digital printing SMEs located out of a textile district, are currently suffering the absence of a close, complete supply chain, and they seriously risk of closing their activities because of this scarce completeness. ECOFLEX is going to be proposed to the market of digitally printed fabrics, which is leaded by Europe with 45% total share and is expected to grow in the next years according to recent Industry surveys. Thanks to ECOFLEX, all the operations needed for the textiles finishing and functionalisation will be performed in a single, all-in-one and customized machine, available at low price and compact dimensions. The main benefits for the ECOFLEX users will be: Reduction of the initial investment of about 70%, Reduction of waste and production costs of about 30%, Reduction in the consumption of water and energy of about 30% and 50% respectively, time to market reduction, floor optimization, full control over the quality and repeatability of the final product, resources valorisation. +The objective of GALNIMBUS is to improve irrigation-water use efficiency up to 30% by developing a cloud-based irrigation controller able to perfectly match irrigation and fertigation doses to crop needs. +The problem: water reservoir and water wells are fragmentarily managed. This causes high energy inefficiency of water pumping and provision operations and depletion of aquifers. +The year 2014 has been proclaimed, by UNESCO, the International Year of Crystallography. Irina Bokova Director-General of UNESCO said : “Crystallography is essential to sustainable development, to tackling global challenges in food, in water, in the environment, in energy, in health. It is by understanding the basic forms of matter that we can transform it for the better, develop new materials, design new drugs against diseases, improve water quality. Development needs innovation, and in most cases, scientific innovation needs crystallography”. +Problem +Ultimate target is to develop a reliable and transparent online solid biofuels quality control system and concept that enables for the biomass power plants: +LIRON 2020 addresses the €Multi-Billion global market for domestic laundry equipment with a highly innovative, disruptive technology that will revolutionise the industry and provide significant economic, lifestyle and environmental benefits. +Waterborne transport still offers an enormous potential for pollution reduction and energy efficiency gains. The reduction of pollutant and greenhouse gas emissions is far removed from the progress made in road transport, particularly in the category of older, small to medium-size vessels which make up a large proportion of intra-European waterborne transport, including inland navigation. +Ten years ago, our innovative Israeli SME company, Aqua Solutions Ltd. was founded. Since the beginning, our CEO, Mr. Ahmed Alimi, focused all our efforts on the optimisation of laundering processes by means of cleaning and disinfecting solutions without the usage of detergent. This led us to develop a process that has a strong cleaning ability and a strong disinfecting ability consuming only three elements: electricity, water and salt. +Sea lice are the most damaging parasite to the salmonid farming industry in Europe, inflicting an annual loss of €300 million. Lice originating from farms also represent a grave danger to wild populations. Fish farmers use many different methods in the effort to control sea lice infestations. However, none have proved 100% effective and sustainable over time due to environmental impacts, negative consumer perception, violation of fish welfare, and not the least of which is cost. Both governmental bodies and the aquaculture sector are now asking for a sustainable solution to the huge problems resulting from sea lice infestation of both farmed and wild salmonid stocks. Optical delousing (Stingray) is a new proactive, gentle and sustainable method for controlling the amount of sea lice in net pens. Using camera vision, software and laser allow for fully automatic louse removal without posing any danger to farmed fish, other species, or surrounding environment. The project aims to develop a dedicated advanced machine vision unit, the EctoVision, to increase the field of view, depth perception and image processing speed. The unit will be made available as an upgrade that can be easily integrated with the existing Stingray platform. The aim is to create an efficient range to detect lice and treat fish that passes within 0.4-1.5 m in the proximity of the Stingray to improve the lice removal performance by a twofold. Activities in the feasibility assessment includes investigation of possible solutions for the machine vision system, mapping best available state of the art and evaluate performance balanced against cost, in addition to search for additional partners. Case studies will be performed to provide a detailed assessment of the expected economic impact using the Stingray with the EctoVision upgrade compared with competing methods. The results will be outlined in a business plan with proper risk assessment, including a preliminary product design specification. +To meet the challenges of growing world food consumption, environmental preservation and sustainable food production, spirulina has been identified as an extremely valuable solution by many international bodies. However, this microalgae is still a largely underutilised food resource. The reasons are organoleptic (foul taste and smell) and, most importantly, cultural (algae are not part of the Western culinary art). +Our company, La Sanfermese, with more than 200 year experience, is specialized in the clearing, drying, storage and commercialization of cereals, in particular maize and wheat. Our main products are white maize, yellow maize, flint maize, durum wheat, peeled durum wheat and calibrated durum wheat coming from non-genetically modified crops (non-GMO) in the Po Valley (Italy). Our main customers are mills and producers of grain-based derivatives. La Sanfermese has an annual storage capacity of 80.000 tons of maize and 40.000 tons of wheat. +The project is to commercialize Remote Controllable Trawl doors that will support Europe’s environmental and economic competitiveness by: +Food Safety controls for all +Blue4Green will develop a portable sample handling/sensing system for DNA and/or RNA fragments. The input to such a system is a raw sample of milk, containing the bacteria to be analysed that causes mastitis. Most of the time treatment starts without knowing the responsible pathogen. Often, the wrong (or not most optimal) antibiotic is used as treatment. When therapy fails, new mastitis incidences and prevalence’s are rising. To test, at this moment farmers collect their samples in testing tubes. These tubes should be transported and send to a laboratory. Within the laboratory, the fluid is tested and the farmer receives the results within three (or more) days. The new technology, concerns a more rapid detection method. Within the technique of B4G, it is possible to know which pathogen is responsible for the inflammation to treat mastitis infection within three minutes instead of three days (or more) since the farmer can test it by himself. With a rapid mastitis pathogen test: +Fresh’ fruits for the consumer market can only be sold as such if they are shown to be a certain standard of ‘ripeness’, as judged by the sugar content and firmness. There is great commercial pressure on producers to provide produce which is of the appropriate standard. Apples which do not meet this standard can be sold to the wholesale market or juiced with losses to market value of 50% and 95% respectively, but apples & citrus fruits which are destructively tested are sold as animal feed, composted or sent to landfill. +In order to feed the larger, more urban and richer population, food production must increase by 70%, and annual cereal production will need to rise to about 3 billion tonnes from 2.1 billion today. However, there are limited opportunities to expand the area of agricultural land without huge detrimental impact on the natural environment. As a consequence, sustainable increase of food supply must be based on productivity improvements. Plant breeding has significantly contributed to and will continue to be a major contributor to increased food security. +By realising a very high process intensification of the electrochemical metal deposition process, the InlinePlat project aims to develop and bring to market modular, fully automated production units for electroplating of mechanical parts and components which can be directly integrated into the manufacturing lines of mechanical engineering companies, automotive suppliers, components and systems manufacturers etc. as self-standing functional metal coating systems. Compared to the very high degree of automation and production integration of the machining, assembling and other mechanical manufacturing processes, the electroplating processes still have a very high potential of optimization in terms of process efficiency, reduction of logistics, increase of automation and production integration. +The SMILE project aims at developing a microalgae-based innovative natural marine ingredient with scientifically demonstrated benefits on weight management and metabolism issues. + diff --git a/spiders/draft/urls.txt b/spiders/urls.txt similarity index 100% rename from spiders/draft/urls.txt rename to spiders/urls.txt diff --git a/wp_urls/FP7_ENERGY_URLs.csv b/wp_urls/FP7_ENERGY_URLs.csv new file mode 100644 index 0000000..ce5f67f --- /dev/null +++ b/wp_urls/FP7_ENERGY_URLs.csv @@ -0,0 +1,385 @@ +"url" +"https://cordis.europa.eu/project/rcn/111468_en.html" +"https://cordis.europa.eu/project/rcn/109879_en.html" 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