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Alerion Technologies commercialises turnkey data solutions for extreme environments through proprietary RPAS that are autonomous and intelligent. After a Feasibility Study, Alerion has decided to focus on windmill inspection market, due to its high barrier of entry, and geographical proximity to important customers that can accelerate international growth. According to the EWEA windmill operations and maintenance represents 30% of the cost of windpark project, and NREL (U.S. Department of Energy) estimates cost of windmill inspections €22K/ MW for onshore and €67K/ MW offshore. Nowadays, most windmill inspection tasks are performed using high-rise equipment and specially trained altitude workers. These solutions are expensive, time consuming, and inefficient for most cases, while effective autonomous and automatic damage identification tool such as an RPAS is a highly desirable solution across the industry. Alerion has estimated that the potential market for autonomous windmill inspection with RPAS is currently €830M annually, with expected growth to €2.6B by 2025. The WEGOOI systems developed by Alerion Technologies will allow customers to drastically reduce windmill infrastructure inspection costs, increase damage assessment effectiveness, and eliminate health risks. This platform is especially suited for structures of difficult access such as windmills, and the company will adapt its technology to fit the exact needs of this market. Alerion has been testing its technological developments in windparks maintained by a multinational company and service provider, and it has already validated Alerion’s prototype RPAS, for its windmill inspections. The prototype version of WEGOOI is at TRL6, capable of inspecting one blade at a time and analysing images in a ground computer. The main goal of WEGOOI is to adapt the existing platform to inspect three blades in one flight and analyse images on-board in real time, and industrialise and commercialise the solution.

International shipping is a large and growing source of greenhouse gas emissions (GHGs). It transports 80% of the global trade at the cost of 940 million CO2 tons (2.5% of global GHGs). Despite mandates from the EC or the UN on tackling this situation, the industry remains heavily fossil-fuel dependent. Some efforts are being made in harnessing the wind to propel ships, going back to its origins. These are soft-tails, fixed-sails, flettner rotors, kite sails and even some wind turbines. However, they all remain at the research stage failing to represent a feasible and reliable power source. Sidewind is a breakthrough innovation in the use of wind power in transport ships. Designed to utilize the wind energy that is wasted around cargo ships by converting that energy (kinetic) into electricity, Sidewind incorporates horizontal turbines inside recycled cargo containers. This results in a flexible, practical and cost-effective solution to the maritime transport sector, without the need for major changes in the ship. By installing just 20 turbines (standard cargo ship), a ship will save 40% average fossil fuel and energy, translated in €328k per year. The EU has 329 key seaports, controlling around 60% of all container cargo ships. Our customers are maritime transport companies (183 in Europe, managing 23,000 vessels) and ship builders (150 shipyards in the EU). The number of vessels calling in the main EU ports in 2017 was estimated at above 2.1 million, and we will target the most important shipping companies. We count with support from public entities (Ministry for the Environment and Natural Resources, Ministry of industries and innovation) and key industry players like Samskip (maritime transport), Hedinn (engineering in fishing industry) and Rafnar Hull (ship builder). Sidewind is opening a new market niche as provider of wind technology for the maritime transport. Our vision for Sidewind is to play the leading role in a new green shipping era

The biggest challenge for renewable energy sources is to match the demand with the supply. By using thermal energy storage for concentrated solar power (CSP) plants, the stability, reliability, and capacity factor of the plants are improved. Conventional CSP plants typically use mirrors, which are expensive to produce, install, and maintain. Apart from that, conventional thermal storages are also expensive as these are based on molten salts, which are expensive and their handling require special materials. Based on a novel micro-structured polymer foil, Heliac, Denmark, has demonstrated cost-effectiveness of the Fresnel reflector integrated foil based CSP plants. The primary objective of “Small-scale CSP” is to design a novel thermal storage for Fresnel reflector integrated foil based CSP plants. Detailed numerical works as well as experimental demonstrations are included. The intention is to design a packed bed storage system with heat storage charging and discharging using evaporation/condensation of one or more heat transfer fluids. For the thermal storage to be designed in this project, the cost is estimated to be around 4 €/kWh which is less than half of the cost of conventional storage system using molten salt (~ 11 €/kWh). The estimated cost of electricity and heat generation from the Fresnel reflector integrated foil based CSP plant with storage (at Seville, Spain) is 38 €/MWh and 8 €/MWh, respectively. By involving research topics from different fields and collaborations with world-leading organizations from industry and academia, this is a truly inter-disciplinary and inter-sectorial project, ensuring its successful completion. In broader terms, the project will contribute to the development of cost-efficient renewable energy systems, reducing the dependence on fossil fuels and reducing the carbon dioxide emissions of the heat and power generation sector, thus helping to attain socio-economic and environmental targets in context of the EU 2020 vision.

Replacing fossil-fuels with solar energy in electric power generation is one of the most important challenges to humanity. From an economic point of view, the important parameter is the Levelized Cost of Electricity (LCOE), or Levelized Energy Cost (LEC), which is the net present value of the unit-cost of electricity over the lifetime of an energy generating asset. The minimally expected LCOE for any solar energy system in 2030 is 0.045 [€/kWh], similar to today's Photovoltaics (PV) LCOE, and at the same level as fossil-fuels. In this proposal, we aim to demonstrate a Proof of Concept [PoC] for a low-cost CPV operating at LCOE of 0.025 [€/kWh] (50% reduction of PVs today). The proposal is a direct continuation of our ERC project on new thermodynamic ideas for solar cells, where we demonstrated that; In contrast to thermal emission, photoluminescence (PL) rate is conserved when the temperature increases, while each photon is blue-shifted (photon-energy increased). We also demonstrated how such Thermally Enhanced-PL (TEPL) generates more energetic photons, by orders of magnitude, than thermal emission at similar temperatures. These findings show that PL is an ideal optical heat pump, and can harvest thermal losses in photovoltaics with a theoretical maximal efficiency of 70%, and a practical device/solution that can reach 48% efficiency. In our preliminary unpublished work, we demonstrate 42% TEPL efficiency compared to an ideal-PV. The challenge in this PoC is to demonstrate photon recycling, photon management, and thermal management, where the maximum of the PL is converted to electricity in an operating PV. We also performed a detailed breakdown of the costs related to TEPL based device. Based on our cost analysis, achieving 32% total conversion efficiency without a cooling system supports LCOE of 0.025 [€/kWh], which will significantly accelerate the usage of renewable energy.

The GEMex project is a complementary effort of a European consortium with a corresponding consortium from Mexico, who submitted an equivalent proposal for cooperation. The joint effort is based on three pillars: 1 – Resource assessment at two unconventional geothermal sites, for EGS development at Acoculco and for a super-hot resource near Los Humeros. This part will focus on understanding the tectonic evolution, the fracture distribution and hydrogeology of the respective region, and on predicting in-situ stresses and temperatures at depth. 2 – Reservoir characterization using techniques and approaches developed at conventional geothermal sites, including novel geophysical and geological methods to be tested and refined for their application at the two project sites: passive seismic data will be used to apply ambient noise correlation methods, and to study anisotropy by coupling surface and volume waves; newly collected electromagnetic data will be used for joint inversion with the seismic data. For the interpretation of these data, high-pressure/ high-temperature laboratory experiments will be performed to derive the parameters determined on rock samples from Mexico or equivalent materials. 3 – Concepts for Site Development: all existing and newly collected information will be applied to define drill paths, to recommend a design for well completion including suitable material selection, and to investigate optimum stimulation and operation procedures for safe and economic exploitation with control of undesired side effects. These steps will include appropriate measures and recommendations for public acceptance and outreach as well as for the monitoring and control of environmental impact. The consortium was formed from the EERA joint programme of geothermal energy in regular and long-time communication with the partners from Mexico. That way a close interaction of the two consortia is guaranteed and will continue beyond the duration of the project.

The Shockley Queisser (SQ) limits the efficiency of single junction photovoltaic (PV) cells and sets the maximum efficiency for Si PV at about 30%. This is because of two constraints: i. The energy PV generates at each conversion event is set by its bandgap, irrespective of the photon’s energy. Thus, energetic photons lose most of their energy to heat. ii. PV cannot harness photons at lower energy than its bandgap. Therefore, splitting energetic photons, and fusing two photons each below the Si bandgap to generate one higher-energy photon that match the PV, push the potential efficiency above the Shockley Queisser limit. Nonlinear optics (NLO) offers efficient frequency conversion, yet it is inefficient at the intensity and the coherence level of solar and thermal radiation. Here I propose new thermodynamic concepts for frequency conversion of partially incoherent light aiming to overcome the SQ limit for single junction PVs. Specifically, I propose entropy driven up-conversion of low energy photons such as in thermal radiation to emission that matches Si PV cell. This concept is based on coupling "hot phonons" to Near-IR emitters, while the bulk remains at low temperature. As preliminary results we experimentally demonstrate entropy-driven ten-fold up-conversion of 10.6m excitation to 1m at internal efficiency of 27% and total efficiency of 10%. This is more efficient by orders of magnitude from any prior art, and opens the way for efficient up-conversion of thermal radiation. We continue by applying similar thermodynamic ideas for harvesting the otherwise lost thermalization in single junction PVs and present the concept of "optical refrigeration for ultra-efficient PV" with theoretical efficiencies as high as 69%. We support the theory by experimental validation, showing enhancement in photon energy of 107% and orders of magnitude enhancement in the number of accessible photons for high-bandgap PV. This opens the way for disruptive innovation in photovoltaics

Waste heat recovery systems can offer significant energy savings and substantial greenhouse gas emission reductions. The waste heat recovery market is projected to exceed €45,0 billion by 2018, but for this projection to materialise and for the European manufacturing and user industry to benefit from these developments, technological improvements and innovations should take place aimed at improving the energy efficiency of heat recovery equipment and reducing installed costs. The overall aim of the project is to develop and demonstrate technologies and processes for efficient and cost effective heat recovery from industrial facilities in the temperature range 70°C to 1000°C and the optimum integration of these technologies with the existing energy system or for over the fence export of recovered heat and generated electricity if appropriate. To achieve this challenging aim, and ensure wide application of the technologies and approaches developed, the project brings together a very strong consortium comprising of RTD providers, technology providers and more importantly large and SME users who will provide demonstration sites for the technologies. The project will focus on two-phase innovative heat transfer technologies (heat pipes-HP) for the recovery of heat from medium and low temperature sources and the use of this heat for; a) within the same facility or export over the fence; b) for generation of electrical power; or a combination of (a) and (b) depending on the needs. For power generation the project will develop and demonstrate at industrial sites the Trilateral Flash System (TFC) for low temperature waste heat sources, 70°C to 200°C and the Supercritical Carbon Dioxide System (sCO2) for temperatures above 200°C. It is projected that these technologies used alone or in combination with the HP technologies will lead to energy and GHG emission savings well in excess of 15% and attractive economic performance with payback periods of less than 3,0 years.

In the face of the increasing global consumption of fossil resources, photosynthetic organisms offer an attractive alternative that could meet our rising future needs as clean, renewable, sources of energy and for the production of fine chemicals. Key to the efficient exploitation of these organisms is to optimise the conversion of Solar Energy into Biomass (SE2B). The SE2B network deals with this optimisation in an interdisciplinary approach including molecular biology, biochemistry, biophysics and biotechnology. Regulation processes at the level of the photosynthetic membranes, integrating molecular processes within individual proteins up to flexible re-arrangements of the membranes, will be analysed as a dynamic network of interacting regulations. SE2B will yield information about the similarities and differences between cyanobacteria, green algae, diatoms and higher plants, the organisms most commonly employed in biotechnological approaches exploiting photosynthetic organisms, as well as in agriculture. The knowledge gained from understanding these phenomena will be directly transferred to increase the productivity of algal mass cultures for valuable products, and for the development of sophisticated analytic devices that are used to optimise this production. In future, the knowledge created can also be applicable to the design of synthetic cell factories with efficient light harvesting and energy conversion systems. The SE2B network will train young researchers to work at the forefront of innovations that shape the bio-based economy. SE2B will develop a training program based on individual and network-wide training on key research and transferable skills, and will furthermore disseminate these results by open online courses prepared by the young researchers themselves.

The CREATE project aims to tackle the thermal energy storage challenge for the built environment by developing a compact heat storage. This heat battery allows for better use of available renewables in two ways: 1) bridging the gap between supply and demand of renewables and 2) increasing the efficiency in the energy grid by converting electricity peaks into stored heat to be used later, increasing the energy grid flexibility and giving options for tradability and economic benefits. The main aim of CREATE is to develop and demonstrate a heat battery, ie an advanced thermal storage system based on Thermo-Chemical Materials, that enables economically affordable, compact and loss-free storage of heat in existing buildings. The CREATE concept is to develop stabilized storage materials with high storage density, improved stability and low price, and package them in optimized heat exchangers, using optimized storage modules. Full scale demonstration will be done in a real building, with regulatory/normative, economic and market boundaries taken into account. To ensure successful exploitation, the full knowledge, value, and supply chain are mobilized in the present consortium. It will be the game changer in the transformation of our existing building stock towards near-zero energy buildings. WP1 Management,WP2 Cost Analysis and planning for future commercial products cost,WP3 System definition,design and simulation,WP4 Thermal storage materials optimization (key breakthroughs),WP5 Critical storage components and technology development (key breakthroughs),WP6 Thermal storage reactor design, implementation and test,WP7 System integration, experiments and optimization,WP8 Building integration and full scale demonstration,WP9 Dissemination and exploitation of results. CREATE will create viable supply chain by bringing together multiple scientific disciplines and industry. In other words, CREATE envisions a multi-scale, multi-disciplinary and multi-stakeholder approach.

The aim of SUNRISE is to make sustainable fuels and commodity chemicals at affordable costs of materials and Earth surface, using sunlight as the only energy source. This includes nitrogen fixation and the conversion of atmospheric CO2 into products, which will be a game changer in the fight against climate change. The CSA SUNRISE gathers the scientific and industrial communities that will develop radically new technologies to harvest solar energy and enable the foundation of a global circular economy. SUNRISE targets three synergistic S&T approaches: (i) electrochemical conversion with renewable power, direct conversion via (ii) photoelectrochemical and (iii) biological and biohybrid systems. These will be implemented with the crucial support of novel material design via high performance computing, advanced biomimicry, and synthetic biology. Ultimately, the novel solar-to-chemical technologies will be integrated into the global industrial system. In 10 years, SUNRISE will bring renewable fuel production to TRL 9 at a cost of 0.4 €/L and atmospheric CO2 photoconversion at TRL 7. The ambition is to convert up to 2500 tons of CO2 and produce > 100 tons of commodity chemicals (per ha per year), realizing a 300% energy gain over present best practices and deploying devices on the 1000 ha scale. This requires new solutions for absorbing >90% of light and storing >80% of the photogenerated electrons in fuels/chemicals produced in large-scale solar energy converters, in close interaction with social and environmental sciences to optimize their deployment. SUNRISE will make Europe the leading hub of disruptive technologies, closing the carbon cycle and providing a solar dimension to the chemical industry, with enormous economical, societal and environmental benefits. SUNRISE is an intrinsically flagship enterprise that has obtained explicit commitment from top organisations, both from industry and academia across Europe, to set the stage for the next steps of the action.