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Objective: The overall objective of the FlameSOFC project is the development of an innovative SOFC-based micro-CHP system capable to operate with different fuels and fulfilling all technological and market requirements at a European level. The main focus concerning t he multi-fuel flexibility lies on different natural gas qualities and LPG, but also on liquid fuels (diesel like heating oil, industrial gas oil IGO and renewables like FAME). The target nominal net electrical output is 2 kWel (stack electrical output ca. 2,5 kW), which is expected to represent the future mainstream high volume mass market for micro-CHPs. An advanced planar, compact SOFC-stack will be developed and combined with an innovative, compact and robust fuel processor, which will be able to process many different fuels without catalytic components, thus enabling the potential for a long lifetime of greater than 30.000 h. A simple, highly integrated and reliable system design will result via the integration of advanced peripheral components like the advanced T hermal Partial Oxidation reformer (T-POX), the multi-purpose off-gas burner, the compact heat exchangers, the cool flame vaporizer and the soot trap. Advanced control strategies will assure an optimal integration in an electrical network environment. The o verall efficiency targets are greater than 35 percent net electrical efficiency and greater than 90 percent total CHP efficiency, which will result in 2 tons of annual CO2 reduction per unit (compared to the combination of a condensing boiler and European electricity mix). The SOFC fuel cell technology will be applied because it is less sensitive to impurities and variations in the fuel composition than other fuel cell systems and has a better cost reduction potential than other fuel cell types. The high temperature level of the SOFC tec hnology gives also a better integration potential in co- or tri-generation applications. The main target application is a micro CHP system for single or two-family residential homes with electrical grid connection.
Objective: VIRTUE is an Integrated Project in response to the call on Virtual environment for an integrated fluid dynamic analysis in ship design; Objective 2 Advanced design and production techniques in the Sustainable Surface Transport of the workprogramme Sustainable Development, Global Change and Ecosystems. It constitutes an EU-wide initiative of leading marine CFD players to create a 'Virtual Basin' by integrating advanced numerical fluid analysis tools to tackle multi-criteria hydrodynamic performance optimisation of ships in a comprehensive and holistic approach, aiming to complement model testing in real basins and hence substantially enhance the provision of current services to the marine industry and to nurture development of innovative design techniques and concepts. This coherent and all-embracing hydrodynamic analysis system will help increase the competitiveness of the EU shipbuilding and shipping industries, promote a truly European co-operation with strong structuring and integration effects, strengthen SMEs through involvement in leading edge developments as a means to gaining and sustaining competitive advantage and leadership and enhance quality and safety in waterborne transportation. VIRTUE's scientific and technological objectives to achieve these ambitious goals include to: -improve hydrodynamic testing through improved reliability of CFD tools -Enhance existing CFD tools in terms of performance and accuracy and further validation -Formally integrate numerical tools, using proven approaches, into an environment for complete modelling and simulation of ship behaviour at sea- Provide smooth and versatile communication and data exchange link between marine CFD service providers, such as model basins, and the end user -Provide the means - CFD tools, integration platform and optimisation techniques -to cover the whole range of hydrodynamic problems and to facilitate and support multi-disciplinary design
Objective: The use of Solid Recovered Fuels (SRF) derived from mixed-/mono waste streams is expected to result in a significant contribution to the generation of sustainable energy. The demand for alternative waste treatment is addressed by production and direct co-combustion of SRF in pulverised fuel fired power plants as an environmentally friendly, energy efficient, short-term available and cost effective technical solution. The project assists the implementation of EU policies (energy, environmental, economic and social goals) by sustainable energy production, CO2 emission reduction, preservation of natural resources and abatement of hazardous impacts on the environment due to landfill. The proposed project comprises large-scale demonstration of SRF co-combustion at a 450MWth brown coal/lignite boiler of RWE Rheinbraun AG in a continuous period of at least 12 months with the scope of permanent and reliable operation. A thermal share of 10% is envisaged (25.000 - 50.000 Mg/a SRF) resulting in a direct environmental benefit up to 50.000 Mg/a CO2 by the efficient use of the renewable share of SRF. With successful demonstration the implementation of the SRF co-combustion technology at further comparable and larger units of RWE is envisaged. Operational problems arising during former short-term co-combustion tests with hard coal could be successfully solved by an improved fuel production and a reliable quality control system. The interaction between a reliable quality control, quality management system and the combustion technology makes this technology competitive in the liberalised energy market without any additional subsidy. To achieve the ambitious goals partners of industry and research centres with substantial expertise in the areas covering the whole waste-to-energy chain created a consortium.
The project aims on developing new combustion technologies for bio-residues. Innovative combustion technologies like flameless oxidation (FLOX (R)) and continuous air staging (COSTAIR) will be enhanced by re-burning and co-firing in order to meet this goal. Two basic types of BIO-PRO burners will be developed to meet this goal: - A pilot burner for gas and liquid fuels; - A pilot burner for solid fuels applying a pre-gasification step for the solids without gas cooling. The technology to be developed shall be able to self adjust to different fuel qualities (fuel moisture 10-50 percent). For emissions of the investigated fuels the upper limit for CO will be 30 mg/m3 (currently 50 mg/m are typical) and NOx will be reduced by 50 percent (starting point for dry wood chips in available combustion systems = 210 mg/m ). The prototypes of the new burners will be brought to pre-commercialisation level (two pilot scale burners and operation guidelines). The accompanying socio-economic assessment will assess the economic viability of the new technology (live cycle assessment) on the one hand and will show promising markets for a subsequent dissemination of the technology on the other hand (dissemination strategy). A successful development and application of the technology is expected to have following impact: - Increased use of bio-residues, increasing the utilisation of biomass in Europe by up to 50 percent (basis 54.175 toe in 1998). This will reduce CO2 emissions by 46 Mio t/a (basis: energy consumption 1998); - Improved European competitiveness in the global market, accounting for up to 15,000 new jobs; - NOx emissions from biomass combustion systems will be reduced within 10 years by approx. 76,500 t/a (basis: biomass consumption 1998).
The scale of influence of global change and the added value of co-ordinating the scientific activities of the EU and North American countries to assess, predict and mitigate the effects on marine ecosystems of the North Atlantic and their services is the justification for the development of the BASIN SSA. An important step towards such a co-ordinated approach is the development of an implementation plan where by jointly funded international projects can be supported. The development of such a plan is the first key goal of BASIN. The second goal of BASIN is to develop an integrated basin-scale North Atlantic research program, for submission to the EU 7th framework program, US NSF and Canadian NSERC for joint funding. Programmatic goals will be achieved in working groups including experts from both the EU and North America as well as delegates from funding organisations. As a prerequisite for the development of the research proposal, this SSA will (1) assess the status of climate related ecosystem research in the North Atlantic basin and associated shelf seas, (2) identify gaps in systematic observations and process understanding of atmospheric and oceanic parameters, (3) identify the potential for consolidation of long-term observations from EU and international databases for modelling and prediction. The BASIN research program will focus on: Resolving the natural variability, potential impacts and feedbacks of global change on the structure, function and dynamics of ecosystems; Improving the understanding of marine ecosystem functioning; Developing ecosystem based management strategies. Hence, BASIN will contribute significantly to the Global Earth Observation System of Systems (GEOSS) 10-Year Implementation Plan via the development of comprehensive, coordinated, and sustained observations of the Earth System, improved monitoring of the state of the Earth, increased understanding of Earth processes, and enhanced prediction.
Objective: For oil tankers to be more environmentally friendly along their life cycle, IMO has set forth a condition assessment scheme 'CAS' for single hull tankers and is now working to develop a similar type of codefor double hull tankers, which involve huge amounts of measurement information. Performing thoseinspections efficiently requires processing measurement information on a real time basis, resulting incost savings because fast assessment of the ship condition and decision-making could be done while theship is still in the dock for maintenance.Measurement information consists of thickness measurements, visual assessment of coating and cracksdetection. In the existing situation, because there is no standardization of data, it is recorded manuallyon ship drawings or tables, which are very difficult to handle. Measurement information takes a longtime to report and to analyse, leading to some repairs being performed at the next docking of the ship.The system to be developed in this project includes such innovative features as: development of a simplified andflexible ship electronic model which can be refined to fit the needs of inspections, addition of measurementinformation in this ship model, automatic updating of the measurement information in the ship model, integrationof robotics, easy handling of measurement information using virtual reality, immediate worldwide access. Systematic comparison and consistency checks of measurement campaigns will trigger electronic alerts. Repairdecisions and residual lifetime of the structure will be calculated with modern methods of risk based maintenance modelling, with the interesting feature that the model will be updated after each measurementcampaign. The system to be developed is applicable to any ship type, but, due to the current focus on tankers and bulkcarriers, these ships will be used as the main case studies.
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.
Two innovative integrated Fuel Cell Systems for automotive application will be developed within specific Technological Platforms (TPs): TP1 POWERTRAIN: development of a system for traction power by an 80 kW direct hydrogen PEM fuel cell system implemented on a passenger car. TP2 APU: development of 5 kW Auxiliary Power Unit for both light-duty and heavy-duty vehicles, including microstructured diesel oil steam reformer, clean-up reactors, an innovative reformate hydrogen stack and balance of plant components. These objectives will be reached via R&TD activities that will address the most critical technical bottlenecks which currently hamper wide market penetration of PEM fuel cell systems for road transport, while accounting some of the key market and policy drivers and barriers. Particularly, the following innovative components will be developed: A 80 kW direct hydrogen stack with strong weight and volume reduction, increased efficiency, durability and start-up time, with innovative MEAs embodying sealing layers (7-layers MEAs); A 5 kW reformate stack, including innovative electrocatalyst and MEA elements tolerant to very high CO concentrations and low-resisitivity bipolar plates; A highly efficient, clean and compact micro-structured diesel steam reformer and gas purification unit; Variable displacement compressors with reduced noise level; Innovative humidification/dehumidification apparatus; Heat exchanger and radiator customised for the different applications; Specific targets for both platforms will be achieved via a system approach leading to development and validation of the concepts (POWERTRAIN: in a passenger car; APU: dynamic test validation in bench) with high well-to-wheel efficiency (low fuel consumption), easy and optimised packaging and on-board integration.
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.
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