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Objective: The idea of intelligent vehicles that cope with safety requirements and adapt their energy needs is a long-term strategy. We have started our work with successive European research projects in the last years by starting with the development of a drive-by-wire platform, but the combustion engine is still a drawback. eFuture wants to prepare the next generation of electric vehicle based on our first prototype by creating a platform which minimises its energy needs but can still optimise dynamically its decision between safety and energy efficiency. Our key issues will be the optimisation of this energy usage and its influence on the vehicle/driver. We have already seen that optimising each component separately is not enough, an overall concept is mandatory to look at the interactions between the components. The strategies to control the actuators will be integrated for safety issues, comfort driving and energy efficiency and the management of the transitions between these controllers. Second ADAS functions will be re-worked to manage these different aspects and a decision unit will base on the proposed time horizon to pre-compensate the transition between modes for energy optimisation. Beside the technical developments, a major aim of the project is to look at the driver who will be confronted with dynamical properties as this energy management will have a high impact on driving. At the end eFuture will be ready with a static (right configuration of components) and a dynamic (software based synchronization of command and execution layer) optimisations. Transitions between different vehicle behaviours (safety, performance, efficiency) will be designed and a strategy set for the priorities in terms of energy needs during requests collision will be developed. In addition the acceptance of the driver to this dynamical behaviour will be investigated.
Objective: The overall objective of the project is to develop new Nano-materials with New Production Technologies and to fabricate silicon quantum dot tandem solar cells to achieve increased efficiencies. The understanding of electrical transport and recombination mechanisms in these newly developed nano-materials will enable us to design new tandem solar cell structures - based on Si thin-film or wafer solar cells - that help to overcome the efficiency limits of these conventional concepts. In order to reach our goals, considerable R+D work has to be performed on semiconductor bulk materials, thin layers and hetero-structures for such solar cells. These topics have not yet or only in parts been investigated and are also of high scientific interest for novel photonic and charge storage devices incorporating Si nano-crystals embedded in Si alloys. The consortium of this project, also including two companies, merges the scientific and technological competences that are necessary to find answers to these questions. Another objective is the compatibility of the newly developed technologies with high-throughput processing to ensure further cost-reduction. The expected significant jump in the solar cell and processing evolution will lead to higher efficiencies for solar cells and to ongoing cost-reduction also with a long-term perspective and will help to strengthening the European leadership in PV technologies. Thus it will also have a positive impact on the acceptance of photo-voltaics by the public and by politics. Moreover, since energy efficiency is a big subject in the public discussion, photo-voltaics will be an example of one of the highest electricity production efficiencies that have been achieved of all power generators. To sum up, we believe that this project will have a direct and positive impact on the European PV industry and its status in material science and it will contribute to the very ambitious goals of the EU commission in CO2 reduction in general.
Objective: The aim of Wingy-Pro is to demonstrate the first ever large size transversal flux generator in an existing wind turbine. A determining factor for increasing the profitability of an offshore wind farm is the installation of wind turbines with a significantly high power capacity and low weight. Until now, the designs of large capacity turbines for offshore applications have been an up scaling of the existing smaller models. This has led to the construction of wind turbines with huge physical dimensions (e.g.: The E-112 has a hub height of 124 m and a rotor diameter of 114 m). Consequently, the weight of the turbines has increased considerably and the material-resistance of the blades, has been taken almost to its limits (rotor blades can reach a length of up to 61 m). These large dimension and weight have a negative influence on the economic efficiency of those offshore applications, because of the high costs for the foundation, transport and installation of the wind turbines. The objective of the project is to carry out the design and development of an improved generator technique through the transverse flux generator (TFG) with permanent magnets in the rotor. There are single-, two- or multi-phase machines, depending on the number of independent stator windings, which are mounted axially on the machine shaft. This technique has been known in the electro-field for years, but due to its strong vibrations and high noise emissions, it has been hardly used. Nowadays however, thanks to new and innovative manufacturing methods and to the development in modern micro-processing controls, the TFG can be used in practical applications.
Objective: IPCC climate change scenarios have a global perspective and need to be scaled down to the local level, where decision makers have to balance risks and investment costs. Very high investments might be a waste of money and too little investment could result in unacceptable risk for the local community. PREPARED is industry driven, 12 city utilities are involved in the project and the RDT carried out is based on the impacts of climate change the water supply and sanitation industry has identified as a challenge for the years to come. The result of PREPARED will be an infrastructure for waste water, drinking water and storm water management that will not only be able better cope with new scenarios on climate change but that is also managed in a optimal way. We will have complexes monitoring and sensor systems, better integration and handling of complex data, better exploitation of existing infrastructures through improved real time control, new design concepts and guidelines for more flexible and more robust infrastructures. PREPARED will involve the local community in problem identification and in jointly finding acceptable system solutions, that are supported by all, through active learning processes. Activities and solutions in PREPARED will be based on a risk assessment and risk management approach for the whole urban water cycle, through the development of innovative Water Cycle Safety Plans. Other innovations are sensors and models that will enable faster and better actions on changes and new design rules for more resilient design. We will combine European knowledge with valuable knowledge from Australia and the USA, to make the European Water sector more competitive. This to enable our industrial partners to export the products developed in PREPARED to other regions of the world, thus contributing to the Lisbon Goals but also to the MDGs. To ensure this exploitation the PREPARED consortium consist of more than 50% industrial partners and is demand driven.
Objective: The main objective of CASTOR is to integrate an innovative distributed propulsion system on fully electrical vehicles. Future electrical propulsion concepts demand more efficiency and less complexity with great functionality, high robustness and light weight and need to run in a wide ambient temperature range. CASTOR is aimed at: -Energy saving of 10 - 20Prozent in respect to present propulsion systems -Cost reduction of about 25Prozent (TBD) respect to present propulsion systems -Increasing the safety due to traction properties and improved integration into drive applications -Mileage improvement of 15 -20Prozent due to higher efficiency and less weight. How these goals will be achieved: -Advancements in efficiency and safety by implementing a multi propulsion power train enabling novel driving functionalities based on the holistic understanding of propulsion and related energy conversion needs. -Integration of the energy storage with the propulsion unit advancing the current state-of-the-art. -Novel conversion topologies like direct power conversion and battery to motor phase alignments reducing the amount of active switching elements -Application of high efficiency control structures and modules in automotive technology ensuring robustness, reliability, drastically reduced maintenance and architectural simplicity -Distribution and delocalization of distributed propulsion systems in order to minimize energy consumption assuring the maximum safety of the vehicle -Development of smart electric system controls in order to improve propulsion and energy management and create an intelligent network on-board vehicle -Simplification of production chain for distributed propulsion systems through a drastic simplification of system architecture. The research need is not only based on the integration of the component functionalities but also considering a holistic approach for the thermal management especially related to the restricted operation temp. of Li-Ion batteries.
Objective: The objective of the ID4EV project is to develop energy efficient and safe brake and chassis systems for the needs of fully electric vehicles and the improvement of active safety and comfort for a faster introduction of fully electric vehicles. These systems will be optimized to the requirements for FEVs. Beside the development and optimization of the most relevant sub-systems of a vehicle with regard to active safety and comfort, the brake and the chassis system, optimization on vehicle level will done with a new approach of a network system as well as new HMI concepts for FEVs. Electrified auxiliaries like the brake systems and the chassis will lead to new possibilities to vehicle control and a better cooperative interaction between these distributed systems. For a fast introduction of fully electric vehicles these systems have to be safe and must have a defined fail safe concept. The aim is to provide absolute safe electrified brake and chassis systems that lead to a high user/customer acceptance. To reach this safety approach the target is to adapt existing systems to the requirements of fully electric vehicles. The project will concentrate on the topics of energy efficiency, safety and the interaction between the vehicle, the optimized systems and the driver. To address both possibilities of drive-train concepts of fully electric vehicles, both concepts will take into account and their impact of the adapted systems will be analysed and solutions presented. To reach a significant breakthrough of fully electric vehicles the adapted systems will be tested on test benches and under real world conditions in demonstrator vehicles to ensure the functionality and to prove the safety.
The purpose of SuperGreen is to promote the development of European freight logistics in an environmentally friendly manner. Environmental factors play an increasing role in all transport modes, and holistic approaches are needed to identify win-win solutions. SuperGreen will evaluate a series of green corridors covering some representative regions and main transport routes throughout Europe. The selected corridors will be benchmarked based on parameters and key performance indicators covering all aspects related to transport operations and infrastructure. Environmental issues and emissions, external-, infrastructure- and internal costs will be covered to get an overall and realistic picture. Based on this benchmarking, areas and candidates for improvement will be identified (i.e. bottlenecks). The next step will be to evaluate how green technologies may support improving the identified bottlenecks. Among the green technologies considered may be novel propulsion systems, alternative fuels, cargo handling technologies, new terminal technologies or novel concepts relevant for the multimodal green corridors. The benchmarking issue is an iterative process. Next, a similar process needs to be accomplished taking into consideration smarter utilisation of available information in the multimodal chain (ICT-flows). An analysis will be made on how this information can be utilised to achieve greener logistics along the green corridors (e.g. e-freight, Supply Chain Management (SCM), smarter planning, scheduling and tracking & tracing). Based on these iterative benchmarks and evaluations, new R&D within specific topics may be needed to improve the identified bottlenecks. Recommendations for future calls for R&D proposals will be made. Last but not least, the project will review and assess the implications of alternative policy measures for green corridors, both at the local and the European level. Prime Contractor: National Technical University of Athens; Zografou; Hellas.
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.
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