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The aim of the EK200-AWESOME project is to bring the EK200 to market - an integrated 100 kW container based airborne wind energy (AWE) converter and storage solution catering to off-grid applications and mobile end-uses. The EK200 can be deployed stand-alone or in arrays. The EK200 could also shape the future for AWE and provide basis and principles for up-scaled MW units Motivation The EK200 will add to renewables’ part of the energy-mix and support off-grid micro-grids providing distributed and diverse power sources for geographically remote communities or industrial activities Solution The physical height of conventional wind turbines is limited by the enormous stresses on the structure and by mechanical resonance phenomena. The EK200 will replace the most effective part of a conventional wind turbine, the tip of the rotor blade, by a tethered kite - operating economically even at low-wind onshore locations. USPs: * Low Cost of Secure Energy: Ultra high capacity factors, yielding > 5,000 full load hours pa * Portability and minimal interference: Less than 5% of the material resources used in a conventional wind mill with the same yield * Uninterrupted Power Supply: Tapping into stable and abundant high altitude winds * Ease of Maintenance: Least amount of moving airborne parts in the industry * Flexibility in Operation: Portable units. Smart control technology Project Outputs Commercialization of the EK200 is a high risk/high reward action. As a result we are conducting a Feasibility Study, resulting in a complete Business Plan, taking a into account end-user needs, market analysis, cost assessment, IP validation, pilot design and risk assessment - all feeding into our go-to-market strategy Opportunity High power reliability level and the need for an effective demand-response load management present a conducive ecosystem for off-grid to flourish. We seek to capture a share in this attractive market valued at EURbn 2.8 in 2014, growing to EURbn 6.3 in 2019

The research responds to the unprecedented emergence of global environmental norms intended to reconcile natural resource management with poverty alleviation. Prominent examples of such norms are the social safeguards included in global conventions and the human rights-based rulings of international courts. The norms possess the potential to transform development practice in the future, so long as they effectively support poor people's claims on natural resources and rights to sustainable livelihoods. The increasing significance of global environmental norms challenges research to develop new theory on the dynamics of environment and development that attends to cross-scale relationships between local environmental struggles, environmental mobilizations and global norms. This research employs an environmental justice lens to examine the effects of global environmental norms on poverty alleviation in the Global South through explorations of forests and water. The proposed research expands the political ecology approach through attention to notions of environmental justice and cross-scale environmental politics. Notions of justice are at the core of many environmental struggles, as they inform people's claims and practices in relation to natural resources. Justice conceptions are also an integral component of international environmental politics and global environmental norms. Thus ideas about justice are an integral element of environmental politics across scales, connecting local struggles to mobilizations at national and international levels as well as the conceptions informing global norms - or causing dissonances between them. Research in stage 1 proceeded by way of four case studies from Nepal, Sudan and Uganda on how marginalized people's struggles in reaction to carbon forestry and hydropower projects are, or are not taken up in environmental mobilizations, and how this uptake does, or does not contribute to increases in wellbeing. The particular objectives guiding the research in stage 2 are to: (1) Generate empirical insights on the resonance of global norms and international mobilisations with environmental struggles by examining international politics of justice on carbon forestry and hydropower. (2) Combine the empirical insights from stage 1 and 2 to develop new theory on cross-scale dynamics of environment and development. (3) Support practitioners involved in environmental mobilisations in generating impact in low-income countries through novel forms of engagement. Research in stage 2 will trace references to the struggles examined in our stage 1 research in negotiations over the so-called Safeguards on Reducing Emissions from Deforestation and Forest Degradation (REDD+) under the UN Framework Convention on Climate Change and international court cases dealing with hydropower projects in the South. The research team will synthesize their findings in a theoretical and two case-based journal articles. In addition, the insights from stage 1 and stage 2 will inform the development of a theoretical paper on cross-scale dynamics of environment and development. The project team will also expand the cooperation with environmental activists on the basis of the insights gained in stage 1 research, using think tanks and workshops to create new forums for engaging activists, professionals and government officials. Such forums facilitate involved actors to develop shared ideas about justice and apply them to the REDD+ Safeguards and international water law.

Small scale horizontal axis wind turbines and vertical axis wind turbines are unable to handle high winds or turbulent conditions. At very high speeds wind turbines shut down. Existing designs focus on external mechanical and electrical systems to reduce the output rather than exploit the attributes of low and high wind conditions. Turbines with static blades cannot effectively capture the direct wind energy for all the blades. Existing designs rely on a small proportion of the total blade area and typically feature a symmetrical profile (equal profile each side). Existing vertical axis machines have an inherent inefficiency because while one blade is working well, other blades are effectively pulling in the wrong direction- causing them to behave as a brake. Vertogen has identified a gap in the market for a variable pitch VAWT.

This project will combine a Soltropy freeze tolerant solar thermal system with heat storage capability. This will make the overall system more effective and expand the use of solar thermal by making the it more cost effective. The project's main focus is to - 1. Reduce the cost of the system for installations where space heating is required. 2. Reduce the cost of the system for installations where there is no existing hot water tank. 3. Increase the performance of the system.

The objective of the innovation project is to demonstrate our low-cost and efficient thermal energy storage technology, and introduce the technology to the market. Similar to how electric energy is stored in a battery, inside an EnergyNest storage, thermal energy is stored in a state-of-the-art concrete-like storage medium which is named HEATCRETE® at temperatures of 425 °C or more. In the project, the goal is to demonstrate storing energy from waste heat/power from industrial applications, surplus or curtailed wind energy, and to return the energy as either heat (process steam), electricity or a combination of both (combined heat and power – CHP). The feasibility study (phase 1) is aiming to get an agreement established with at least one commercial partner to build a first demonstrator. Our technology is unique as it is purely based on commodity materials, has a lifetime of over 50 years and can be built anywhere. Most of the components can be sourced locally which reduces the CO2 emissions due to transport. The used materials are non-hazardous and recyclable (steel, concrete and insulation material). Our solution helps to make renewable power generation economically more attractive by better utilizing wind assets through avoiding to waste or curtail energy. This will help to promote growth of renewable energy and to reduce base-load capacity provided by conventional power plants. Our approach is to store and reuse waste heat to produce electricity, process steam or district heating when the demand is not matching the supply.

PROBLEM: 1.1 billion people, most of whom live in developing regions of Asia and Africa, lack access to electricity. The primary light source for them are kerosene lamps, which are not only costly, but also has negative impact on human health, resulting in illness and even mortalities. Existing solar-powered products are too expensive for households with a $20 monthly income. Booming trends of mobile subscriptions and smartphone adoption in developing countries mean there is also a growing need to charge the phones. SOLUTION: Solet Technics has developed a prototype of a mobile solar power generator, PAWAME which offers a cheap and reliable access to electricity for off-grid households. The company is planning to distribute PAWAME solution using local agents, and infrastructure, payment system and brand recognition of Telcos, which enables fast market uptake and scaling of the product. It will also be easy and convenient for the user to pay for electricity via phone. The ‘rent-to-own’ model makes the product accessible to low income households: no upfront investments needed. User-friendly and unique product design enables simple usage for the end-user. Customer can login to see his payment plan information, usage data, etc. Unique product features also include theft protection – PAWAME sends its location and if somebody tries to force to open it, it is remotely notified and can be tracked and traced all the time. The device has been tailored to fit to the needs of both end-user and Telcos. NEXT STEPS: Thorough market analysis and an elaboration of a business plan is needed in order to define strategic commercialization. This feasibility study will be a crucial step towards commercialization of Solarize. Further in the future, Solet Technics plans to bring PAWAME to industrial readiness and maturity for introduction to the global market, providing solar electricity to more than 200 thousand households and generating profit of 3 million euros by the year 2020

Awaiting Public Project Summary

The main objective of the project is the organization of the international conference “SET Plan 2016 - Central European Energy Conference X” during the presidency of the Slovak Republic in the second half of 2016. The SET Plan 2016 conference will be conjoined with the 10th annual Central European Energy Conference (CEEC X). The conference will aim to examine the process of accelerating the development and deployment of low-carbon technologies and creating the European Energy Union, focusing on the research and innovation strategy. Its ambition is to improve the visibility of the Strategic Energy Technology Plan and Energy Union, to identify policy options and priorities and to plan future actions. Based on that, the proposal stipulate these the main objectives of the SET Plan 2016 – Central European Energy Conference X: to examine achievements in the implementation of the Energy Union with a special focus on the role of its Research & Innovation dimension; to assess progress and evaluate the role of Central European member states in the implementation of the goals of the Energy Union within the other four priority dimensions of the Energy Union, including security of supply, creation of an integrated energy market, improving energy efficiency and reduction of emissions; to create a platform for a discussion, dialogue and networking for member states, civil society, business, science and academia, regional and local authorities and other stakeholders in the area of strategic energy technologies; to foster visibility and understanding of the Energy Union and the topic of Strategic Energy Technologies, and to disseminate information. Planned activities include plenaries and panel discussions with international keynote speaker, parallel thematic dinner sessions, side events, poster session and social events.

The aim of the project is to integrate Soltropy’s patented freeze tolerance solution, developed for vacuum tube solar thermal collectors, with AES Ltd’s (AES Solar) flat plate solar thermal collectors. This will help to significantly reduce the installed cost of their solar thermal systems. Most solar thermal systems in the UK do not run water directly through the collector panels as it can cause freeze damage. Instead they run an antifreeze fluid through the collector which means that when a new solar thermal system is installed a perfectly good tank is replaced by a new hot water tank with a heat exchanger. This can double the price of the installed system due to the new tank and additional labour costs. A new tank is not required with Soltropy’s solution which allows water to be used directly in the system. It works by using a compressible tube inside the copper piping which takes up the expanded volume of the water if/when it freezes. The cost savings made from not needing a new hot water cylinder and from the reduced installation time will lead to a steep reduction in the installed cost of solar thermal systems