The Mediterranean Partner Countries of the European Union are confronted with a rapidly increasing energy demand caused by a growing population especially in cities and increasing living standards. The region has a great potential for the use of renewable energies, notably solar energy due to its high level of solar radiation. However, only a small variety of solar thermal technologies is used in the region. The state of technology and the political support mechanisms vary strongly across the region and in relation to the EU countries, where new solar thermal applications for water and space heating as well as cooling are developed. SOLATERM is an EU-funded project that brings together research institutions, energy agencies, authorities and enterprises from EU and the Southern Mediterranean partners. The project consortium with partners from eight Southern Mediterranean and five EU countries has the aim of promoting the application of a new generation of solar thermal systems in the Mediterranean partner countries. SOLATERM combines the technological know-how of EU research institutions with the specific experiences and knowledge of the Southern Mediterranean partners. The EU partners provide important experiences in developing a successful political framework to boost the use of renewable energy.
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.
Objective: The European PV market is developing rapidly, with new products and services, new actors and technologies emerging constantly while overall business grows by over 30Prozent a year. During such growth of market and industry it is of particular importance to lay a sound basis of understanding of the quality and performance of products and systems, harmonise procedures for their testing and labelling and disseminate this knowledge to all involved players. Customers, manufacturers and service providers today ask for increased transparency and increased confidence and planning reliability. And they will all benefit from a joint effort on pre-normative research on performance assessment of photovoltaics presented here. The PERFORMANCE project covers all pre-normative as pects from cell to system level and from instantaneous device characterisation and system measurement to their life-time performance prediction and assessment. The limitations of current indoor and outdoor calibration measurement technology will be investi gated and precision will be improved, covering current technologies as well as new and advanced cell and module concepts. Methods will be developed to connect from measurements of module power to module energy production. In a third pillar, methodologies f or the assessment of the life-time performance of PV modules will be developed. Based on all these work packages, a modelling and analysis programme will provide the analytical understanding of PV performance in the broad and systematic manner mentioned ab ove. Following this work programme, PERFORMANCE will produce a consistent set of measurement and modelling methodologies to create the transparency needed for the European market and industry. Next to this significant scientific effort, intense involvement of all European companies along the value chain will be organised systematically through feedback loops. Project results will be fed directly into standardisation processes on CENELEC and IEC level.
Objective: To develop the market for solid biofuels within the EU standards are urgently needed. Based on a mandate given by the EC, CEN TC 335 'Solid Biofuels' currently develops such standards based on the available knowledge. In the meantime several Technical Specifications (TS) (or pre-standards) are available. They have to be upgraded to European Standards (EN) within the next 3 years. Other TS's are on its way. But applications in industry have shown that additional information has to be integrated and/or considerable gaps in knowledge still exist. This makes it difficult to develop the still missing TS's and/or to upgrade the TS's to EN's. Against that background the goal of the BioNorm II project is it to support the ongoing standardi sation efforts especially for the development of improved solid biofuel specifications concerning - specifications given by the combustion unit, and - rules for conformity of the products with their specified requirements. To achieve this, the following aspects will be addressed within this project in detail: - development of sampling and sample reduction methods for further materials as well as sampling plans, - improvement of existing reference test methods, - development of new reference test methods, - development of rapid on-site test methods, - development of improved quality measures especially adapted to solid biofuels. Additionally the results of this pre-normative work will be transferred directly into the ongoing standardisation process to allow for the development of improved EN's and acceptable TS's.
Objective: In order for the commercial production of large CIGS modules on the multi-MW scale to be successful, the processes must still be streamlined and optimised taking considering both economical and ecological aspects. This project aims to support the developme nt of this material- and energy-saving thin-film technology so it can gain a foothold in the free PV market. Promising laboratory results will be transferred to large-scale production, where the availability of appropriate production equipment and very hig h material and process yields are of decisive importance. 4 universities, 2 research institutes, and 4 companies will work closely together in order to merge the physical understanding of the processes and the engineering know-how, which are necessary for up-scaling the CIGS technology to a marketable multi-megawatt production volume. We will focus on: (1) very high-quality modules manufactured by coevaporation of CIGS and applying cost-effective methods, ETA up to 14 Prozent on 0.7 m2; (2) the development of Cd-free buffer layers for Cd-free CIGS modules on an area of up to 0.7 m2, ETA up to 12 Prozent; (3) and the development of a mid-term alternative: electrodeposition of low-cost CIS modules with ETA above 10 Prozent (estimated cost about 0.8 E/Wp). We will transfer the Mo back contact sputtering know-how to a specialised European large-area glass coater to provide substrates for both the coevaporation and the electrodeposition approaches. All process developments such as modifications of the back contact, wet- or vacuum-deposited buffer layers, the multi-stage coevaporation of CIGS, or improved Ga incorporation in electrodeposited absorbers will first be tested and evaluated on the laboratory scale. Successful approaches will be up-scaled and transferred to three independ ent commercial CIGS pilot lines located in three different European countries. Novel process and quality control techniques must also be developed and applied to reach these ambitious goals.
Objective: The constitution of the common European market is accompanied by continuously increasing cross-border goods and passenger traffic. Road transportation is facing a rapidly increasing congestion whilein the contrary the available capacities in railway transportation as well as inland waterwaytransportation are being underutilised. A redistribution of the carriage of goods is urgently needed, but up to now the most important obstacles consists in the incompatible interfaces between the various carriers and the diversity of loading devices being used in the EU. Main objective of the project is the development of new intermodal loading units including devices (ISO-bulk container and Roll-off container), capable adaptors and mobile fixtures suitable for the trimodal transport of bulk and packaged goods at road, railway and inland waterways. Essential element of the project is the design and integration of innovative adaptors for lifting and shifting operations of the loading units. This will lead to an optimum on intermodal compatibility. The goals are in conformity with the aims of the Specific Programme 'Sustainable Surface Transport', research domain 3.16. 'Development of equipment for fast loading / unloading of intermodal transport units'. By application of the new loading units the logistic chain can be set up without changing the loading unit throughout the whole door-to-door transport process. The transhipping procedures do not require crane technology any more and the costs will be reduced substantially. The uniformity of the specialinternal features as well as the compliance with the ISO-container dimensions will contribute to the harmonisation of loading units. The projects includes the development of containers, adaptors and mobile units, test and demonstration of two prototypes and dissemination and exploitation of the results. The consortium consists of ten partner with six SMEs from five countries (G, HU, CH, A,CR)
Objective: ISTU STREP proposal intends to investigate, develop and demonstrate a cost effective integrated propulsion unit for individual self-driven container rail platform wagons for freight container transport between ports and cargo distribution centres. Although the proposal is an R&D project focussing on technical and innovative methods to integrate all main propulsion components like motor, power converter, cooling and embedded controllers in one unit, the project coordinator has defined clear demonstrator targets. In particular, the propulsion unit, with rated power of ca. 25 kais expected to deliver cost improvements of 30Prozent, efficiency improvements of 2Prozent (up to 96Prozent) and system availability improvement of 3Prozent (up to 98Prozent). A prototype integrated drive system will demonstrate these improvements. The project will aim at developing an integrated switched reluctance drive which uses integrated power electronic conversion modules and advanced direct torque digital control enabling the use of low cost sensors. Long-term approach of ISTU expects that this STREP project will lead to an IP project, integrating further the outer vehicle guidance control, i.e. a GSM telemetric system with vision capabilities, which would lead to an unmanned automatic piloted transport system able to be applied also as the self-propelled and self-guided container wagon to dense industrial areas in order to reduce road traffic, pollution and noise. As Objectives the ISTU STREP project will aim at: -developing an electrical integrated low-cost: propulsion and cooling systems, control and power electronic components, simple producible rail transportation motor - demonstrating the proposed low-cost propulsion system-designing and specifying all requirements for a direct freight logistic application, i.e. a container wagon. -Defining interfaces and showing implementation of such propulsion units and its interfaces for a self-guided self-propelled application.
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 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.
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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