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HSR Hochschule für Technik Rapperswil

Country: Switzerland

HSR Hochschule für Technik Rapperswil

14 Projects, page 1 of 3
  • Funder: European Commission Project Code: 270596
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  • Funder: European Commission Project Code: 875091
    Overall Budget: 2,107,670 EURFunder Contribution: 2,107,670 EUR

    The new policies and the revised renewable energy Directive are fixing ambitious targets for 2030: renewable energy target of at least 32% and an energy efficiency target of at least 32.5%. When the policies are fully implemented, they will lead to a great reduction on emissions for the whole EU, around 45% by 2030 (relative to 1990 GHG emission). The EU framework towards GHG emissions reduction is based in six key areas of action, including the deployment of renewable energy production, decarbonising heating and cooling applications (which vastly relies on fossil fuels), and reducing the emissions on the transport sector. Therefore, the integrated energy markets in the EU shall allow important transformations to provide more flexibility and be better placed to integrate a greater share of renewable energies, allowing also a more independent energy system. In this context, Hydrogen can play a pivotal role as energy vector allowing coupling the energy sectors (produced by electrolysis) , and as an alternative fuel in hard to electrify sectors. To facilitate that a high amount of hydrogen is produced by RE, existent gas infrastructure could be a way of transporting hydrogen between production point and final use. Therefore, hydrogen injection into the gas grid could support gas-electricity sector coupling and opening the role of hydrogen as a way of decarbonising the gas usages. HIGGS project aims to pave the way to decarbonisation of the gas grid and its usage, by covering the gaps of knowledge of the impact that high levels of hydrogen could have on the gas infrastructure, its components and its management. To reach this goal, several activities, including mapping of technical, legal and regulatory barriers and enablers, testing and validation of systems and innovation, techno-economic modelling and the preparation of a set of conclusions as a pathway towards enabling the injection of hydrogen in high-pressure gas grids, are developed in the project.

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  • Funder: European Commission Project Code: 308792
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  • Funder: European Commission Project Code: 609666
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  • Funder: European Commission Project Code: 818012
    Overall Budget: 3,701,860 EURFunder Contribution: 3,362,670 EUR

    The Hybrid – BioVGE project has the primary objective of developing and demonstrating a highly integrated solar/biomass hybrid air conditioning system for space cooling and heating of residential and commercial buildings that is affordable, operating with improved efficiency and reduced need for maintenance. The proposed system will be driven by heat, using two renewable energy resources: solar thermal and biomass. Only a small amount of electricity will be needed for the circulation pumps and the control system (less than 5% of the total needs). Thus, it is expected that 95% of the building thermal load will be satisfied by renewable energy. The Hybrid-BioVGE project is a cooperation of seven key research institutions and companies of the required trans-disciplinary approach. The proposed system will be composed by a number of major components, including solar collector field, biomass boiler, thermal energy storage unit using PCM, thermally driven variable geometry ejector chiller, heat distribution and intelligent integrated control system. The Hybrid – BioVGE system represents innovative solutions at both component and system levels. Component level innovations include e.g. the application low cost solar collectors, high performance variable geometry ejector chiller, multi-fuel biomass boiler. At the system level, innovation effort will be carried out in order to reduce system complexity and to develop an intelligent energy monitoring and control unit that will lead to efficient operation of its components, with reduced cost and little need for interference by the end user. The potential of the proposed technology will be demonstrated by testing three small scale prototypes, adequate for residential and small commercial buildings, under different European climatic conditions: heating load dominated; balanced heating and cooling load; and cooling load dominated. A TRL of 7 for the Hybrid – BioVGE system will be achieved by the end of the project.

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