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Objective: Solar thermal power plants represent today's most economic systems to generate electricity from solar insulation in them-range in regions like the Mediterranean area. By demonstrating the feasibility of direct steam generation in the absorber pipes European industry and research institutions have gained a leading position in this technology area. A key element foray successful market penetration is the availability of storage systems to reduce the dependence on the course of solarinsolation. The most important benefits result from -reduced internal costs due to increased efficiency and extended utilisation of the power block-facilitating the integration of a solar power plant into an electrical grid-adoption of electricity production to the demand thus increasing revenues Efficient storage systems for steam power plants demand transfer of energy during the charging/discharging process at constant temperatures. The DISTOR project focuses on the development of systems using phase change materials (PCM) as storage media. In order to accelerate the development, the DISTOR project is based on parallel research on three different storage concepts. These concepts include innovative aspects like encapsulated PCM, evaporation heat transfer and new design concepts. This parallel approach takes advantage of synergy effects and will enable the identification of the most promising storage concept. A consortium covering the various aspects of design and manufacturing has been formed from manufacturers, engineering companies and research institutions experienced in solar thermal power plants and PCM technology. The project will provide advanced storage material based on PCM for the temperature range of 200-300 C adapted to the needs of Direct Steam generation thus expanding Europe's strong position in solar thermal power plants.
Ohne einen kurzfristigen erheblichen Fortschritt wird die Welt das Hygieneziel der Jahrtausendentwicklungsziele (MDG) um eine halbe Milliarde Menschen verfehlen. Betrachtet man etwa die subsaharischen Länder Afrikas, dann hat fast zweidrittel der Bevölkerung (64 Prozent) keine ausreichende Versorgung mit Sanitärenanlagen. In den afrikanischen Ländern schwankt die Menge der Wohnungen und Häuser mit Sanitäreinrichtungen zwischen 84 Prozent in den städtischen Gebieten und 45 Prozent in den ländlichen Gebieten. Um bis 2015 das Ziel einer flächendeckenden Wasserversorgung zu gewährleisten, müssen in den nächsten 15 Jahren für 210 Millionen (194 in den ländlichen Gebieten) Menschen zusätzliche sanitäre Einrichtungen gebaut werden. Das Ziel dieser Koordinierungsmaßnahme ist der Aufbau einer multilateralen, interdisziplinären Interessengruppe von subsaharischen und europäischen Fachleuten für die nachhaltige Entwicklung von Sanitäranlagen. NETSSAF fördert internationale Zusammenarbeit zwischen Forschungsinstitutionen, Verbänden, Universitäten sowie Gesellschafts- und Regierungsinteressengruppe in einem europäischen und subsaharischen Zusammenhang mit einer speziellen Ausrichtung auf die Westafrikanischen Länder. Eine beständige Plattform für Experten und Forschung im Sanitärsektor und ein Sachverständigennetzwerk werden eingerichtet, um nutzbringende Forschung und strategische Aktivitäten zu koordinieren, zu bestimmen und zu leiten, mit dem Ziel einerseits ein optimales Verfahren, Wissenslücken und Grenzen für das weitere Vorgehen zu bestimmen und andererseits Vorschläge für die Richtung zukünftiger Forschungen zu unterbreiten. Das Ziel des vorgeschlagenen Netzwerkes ist es ein Vielfalt an innovativen, anwendbaren und wiederholbaren Ansätzen für eine nachhaltige Sanitärentwicklung zu liefern, welche preiswerten Technologien mit einem auf der Kommune basierendem Management und den unterschiedlichen in den Regionen Afrikas vorherrschenden Bedingungen verbindet. Das Hauptergebnis wird die Entwicklung eines partizipativen Hygiene-Management-Unterstützungsinstruments für mehrere Benutzer sein, das für die Endbenutzer darauf abgezielt, sie in die Lage zu versetzen groß angelegte Hygienekonzepte und Technologien anzuwenden und sie den unterschiedlichen Bedingungen, die in Afrika vorherrschen, anzupassen.
Objective: HyApproval is a STREP to develop a Handbook (HB) facilitating the approval of hydrogen refuelling sta-tions (HRS). The project will be performed over 24 months by a balanced partnership including 25 partners from industry, SMEs and institutes which ensure the critical mass and required know how for obtaining the identified project goals. Most partners have extensive expertise from HRS projects. Key partners from China/ Japan / USA provide an additional liaison to international regulations, codes & stand ards activities. The project goals are to finalise the HRS technical guideline started under EIHP2 and to contribute to the international standard under development at ISO TC197 and in first line to provide a HB which assists com-panies and organisations i n the implementation and operation of HRS. The HB will be based on best prac-tices reflecting the existing technical know-how and regulatory environment, but also includes the flexibility to allow new technologies and design to be introduced at a later sta ge. In order to meet these goals, best practises will be developed from project experience (CUTE, ECTOS, EIHP1&2, HySafe, CEP, ZERO REGIO) and partner activities. In 5 EU countries (F/D/I/E/NL) and in China, Japan and the USA the HyApproval process wil l include a HB review by country authorities to pursue 'broad agreement' and to define 'approval routes'. After finalising the HB process the developed requirements and procedures to get 'Approval in Principle' shall be suffi-ciently advanced to seek appro val in any European country without major modifications. Not only infra-structure companies, HRS operators/owners and local authorities but also the EC will profit from the HB that is deemed to contribute to the safe implementation of a hydrogen infrastruc ture. The project complies with EU's R&D and energy policies, which aims at the introduction of 5Prozent hydrogen as motor fuel by 2020. The HB will put Europe in a position to maintain and extend its leading position
Objective: The aim of this project is to turn 4 core communities (Germany, Austria, Luxemburg, Poland) with clearly defined system borders and 14 - 20.000 inhabitants each into CONCERTO communities. A mix of different EE and RES demonstrations (including refurbishment of old buildings, eco-buildings and polygeneration, all underpinned with complete business plans) will allow to avoid about 300 GWh/yr end energy from fossil sources, thus avoiding 94.000 tons CO2/yr, and saving 22.9 mio Euro/yr of disbursements for extra-communal electricity and heat deliveries. The application of the Decentralised Energy Management System (DEMS) will allow for local and inter-communal operation, monitoring and control of energy consumption, storage and generation units and grids, including DSM and LCP, thereby exploring a EE potential of at least 5Prozent. The target in RES coverage for 2010 is of resp. 39 to 62Prozent of the then remaining electricity and heat demand. EnerMAS, a low-threshold version of the European environmental management system.
Objective: The project aims to develop highly integrated solar heating and cooling systems for small and medium capacity applications which are easily installed and economically and socially sustainable. The envisioned applications are residential houses, small office buildings and hotels. The goal is to use the excess solar heat in summer to power a thermally driven cooling process in order to provide cooling for air-conditioning. In the heating season the solar system is used to provide direct heating. The proposed project therefore aims to demonstrate the technical feasibility, reliability and cost effectiveness of these systems, specially conceived as integrated systems to be offered on the market as complete packages which will make better use of the available solar radiation as present systems.
Die Projektgebiete liegen in Deutschland, Italien und Spanien. Deutschland: Scharnhauser Park: In Ostfildern am südlichen Rand von Stuttgart entsteht auf einem ehemaligen amerikanischen Militärgelände der Stadtteil Scharnhauser Park für rund 10.000 Bewohner und mit etwa 2.500 Arbeitsplätzen. Zu rund 80 Prozent soll der Energiebedarf aus erneuerbarer Energie gedeckt werden. Kern des Energiekonzeptes für den Stadtteil ist ein Biomasse-Blockheizkraftwerk mit 1 MW elektrischer und 6 MW thermischer Leistung. Die Anlage wird optimiert, eine Ist-Analyse ist bereits erstellt worden. Mit der im Sommer ungenutzten Wärmeenergie soll künftig Kälte für die Klimatisierung von Gewerbebauten erzeugt werden. Neben der ganzjährigen Nutzung erneuerbarer Energien für die Kraft-Wärme-Kältekopplung ist auch Energiespeicherung (zentral und dezentral) und ein kommunales Energiemanagementsystem auf der Basis modernster Informationstechnologien vorgesehen. Das zafh.net liefert Know-how der simulationsgestützten Regelung von Anlagen und setzt betriebsbegleitende Simulationen ein. In Echtzeit soll aus den klimatischen Randbedingungen der optimale Betriebszustand berechnet und mit den real gemessenen Werten verglichen werden. Als Basis ist ein Geoinformationssystem entwickelt worden, mit dem die Energiedaten der Gebäude erfasst und ausgewertet werden können. Die Gebäude unterliegen einem hohen Dämmstandard (25 Prozent unter den in der Wärmeschutzverordnung 1995 geforderten Werten). Bei den im Projekt neu dazukommenden Wohn- und Gewerbebauten wird der Transmissionswärmeverlust um weitere 20-30 Prozent gesenkt. Die ersten Wohnbauten wurden im Herbst 2005 vom Siedlungswerk Stuttgart erstellt. Mit Argon gefüllte Fenster mit erhöhter Rahmendämmungund Kunststoff-Abstandhaltern erreichen einen Gesamt-Wärmedurchgangskoeffizienten von 1,1 W m-2 K-1. In diesem ersten Bauabschnitt sind reine Abluftanlagen ohne Wärmerückgewinnung installiert worden, in späteren Bauabschnitten sollen Anlagen mit Wärmerückgewinnung einer Vergleichsanalyseunterzogen werden. Die Gebäudedichtigkeit wird mit Blower-Door-Tests experimentell untersucht. Der Energiestandard wird bei allen Bauten dokumentiert. Messgeräte für die Fernauslese und Auswertung (Smartbox) sind bereits installiert. ImGewerbegebiet wird im März 2006 ein erstes Demoprojekt zur innovativen Gebäudetechnologie (Heizung, Lüftung, Klima) mit etwa 4.000 m2 Nutzfläche erstellt. In der Ausführungsplanung enthalten sind: thermische Kühlung, Erdreichwärmetauscher, Betonkernaktivierung (zur Kühlung) ein Unterflurkonvektions-Heiz- und Kühlsystem, ein Tageslicht-Lenksystem. Nicht nur das Biomassekraftwerk liefert Strom, sondern auch gebäudeintegrierte PV-Anlagen. Ziel ist eine Leistung von insgesamt 70 kWp. Zudem wird die kinetische Energie des Wassers genutzt: Das aus den Hochbehältern ins Netz abfließende Trinkwasser treibt eine 80-kW-Entspannungsturbine an.
Objective: The project focuses on the demonstration of an innovative and sustainable CHP concept using residues from olive oil production (olive wastes) as fuel. A first plant based on the new concept will be realised in Greece. The main objective of the project is to demonstrate a closed cycle concept able to reduce landfill problems and emissions and to promote the use of renewable electricity production in Southern Europe. The project will be based on an approach integrating the whole chain (fuel logistics and preparation, energy production, by-product utilisation). An optimised fuel logistic concept will guarantee for a secured fuel supply over the whole year. The fuel will not only be dewatered and dried but also a marketable by-product will be produced. By this means a better fuel quality can be achieved and solid wastes as well as waste- water can be omitted. The development and design of the combustion unit focuses on a technology tailored to the special characteristics of the olive waste.
Objective: The main objective of the proposed Network of Excellence (NoE) DER-Lab is to support the sustainable integration of renewable energy sources (RES) and distributed energy resources (DER) in the electricity supply by developing common requirements, quality criteria, as well as proposing test and certification procedures concerning connection, safety, operation and communication of DER-components and systems. DER-Lab intends to strengthen the EC domestic market and to protect European interests on the international standardisation level. A major objective is to establish a durable European DER-Lab Network that will be a world player in this field. The NoE will bring together a group of organisations for the development of certification procedures for DER- components for electricity grids. The NoE will act as a platform to exchange the current state of knowledge between the different European institutes and other groups. The scattered, but high quality research and test facilities will be combined with great benefit for the European research infrastructure DER-Lab will contribute by developing new concepts for control and supervision of electricity supply and distribution and will bundle at European level specific aspects concerning the integration of RES technologies. The absence of European and international standards for the quality and certification of components and systems for DER is a hindrance to the growth of the European market and for European penetration of the world market. It is within the aims of the proposed NoE to reduce these barriers and to work towards common certification procedures for DER components that will be accepted throughout Europe and the world. Obviously this work cannot be done on a national basis. The results of the project and afterwards the output of the network will be a significant contribution to the European standardisation activities and will contribute to the harmonisation of the different national standards.
The proposed regulation concerning the registration, evaluation, authorisation and restriction of chemicals (REACH) requires demonstration of the safe manufacture of chemicals and their safe use throughout the supply chain. There is therefore a strong need to strengthen and advance human and environmental risk assessment knowledge and practices with regard to chemicals, in accord with the precautionary principle. The goal of the project OSIRIS is to develop integrated testing strategies (ITS) fit for REACH that enable to significantly increase the use of non-testing information for regulatory decision making, and thus minimise the need for animal testing. To this end, operational procedures will be developed, tested and disseminated that guide a transparent and scientifically sound evaluation of chemical substances in a risk-driven, context-specific and substance-tailored (RCS) manner. The envisaged decision theory framework includes alternative methods such as chemical and biological read-across, in vitro results, in vivo information on analogues, qualitative and quantitative structure-activity relationships, thresholds of toxicological concern and exposure-based waiving, and takes into account cost-benefit analyses as well as societal risk perception. It is based on the new REACH paradigm to move away from extensive standard testing to a more intelligent, substance-tailored approach. The work will be organised in five interlinked research pillars (chemical domain, biological domain, exposure, integration strategies and tools, case studies), with a particular focus on more complex, long-term and high-cost endpoints. Case studies will demonstrate the feasibility and effectiveness of the new ITS methodologies, and provide guidance in concrete form. To ensure optimal uptake of the results obtained in this project, end-users in industry and regulatory authorities will be closely involved in monitoring and in providing specific technical contributions to this project.
The ATTICA consortium offers to provide the European community with a coherent series of assessments of the impact of transport emissions on climate change and ozone depletion. Three assessments will cover the emissions of single transport sectors, viz. of aviation, shipping, and road and rail traffic. Another assessment deals with metrics that allow to describe, quantify, and compare in a fair way the effects of the transport emissions in the atmosphere. Finally, a synthesis of the foregoing assessments will be written that will provide the overview of the impacts of the emissions of all transport sectors on climate change and the ozone layer. For the first time, different modes of transport will be consistently assessed. The consistent assessment allows the interested citizen to estimate in principle their own contribution to environmental problems and to compare it to that of others. Apart from policy and decision makers, the synthesis assessment will help journalists, teachers, and others, to digest the results and to present them in public media, in schools and universities, ensuring wide spread of the results. The assessments and the synthesis report will inform the EU in developing its policy and will strengthen its position in international climate conventions and other international agreements. It will help finding emission reduction and mitigation strategies, and give advice for industry on design of future engines and vehicles, thereby strengthening the European position.
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