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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: Mobility Management (MM) and Travel Awareness (TA) have many advantages as soft policy strategies: they are flexible, adaptable, rapid to implement and offer value-for-money. Many sustainable transport research projects have covered MM and TA, but in isolated projects, limited to larger cities and pilot demonstrations. SUCCESS now offers the chance to link these two areas and exploit their synergies, based on its research areas: A Innovative Approaches in TA B Behaviour Change Models and Prospective Assessment C Quality Management and MM For Smaller Cities D Integrating Planning and MM. They will be linked via horizontal WPs: WP 1 State-of-the-art analysis WP 2 Conceptualisation and specification of research activities WP 3 Monitoring investigations and implementation WP 4 Compiling results WP 5 Dissemination and WP 0 Project Management, Quality Control and Evaluation run in parallel for the duration of the project. Organising the work in this way will deliver excellent results.
Objective: The project highSol aims at the transformation of innovative manufacturing concepts on a laboratory scale into the full industrial scale. The result will be the demonstration of technologies which will enable the mass manufacturing of Photovoltaic products with a serious reduction of manufacturing costs. The objectives are: - Demonstrating the automated manufacturing of Photovoltaic products based on thin wafers with a thickness of 150 micro m. - Increasing and maintaining the overall yield with the implementation of in-process quality control and feedback systems. - Demonstrating the manufacturing integration with the implementation of interfaces which will serve for future standards. The objectives will be reached by the following approach: Saving feedstock, by enabling manufacturing of 150Mikro m wafer with a wafer size of 210*210mm, will enable a direct cost reduction of 25%. As the envisaged cost reduction in Photovoltaic industry is 5% per year, this action alone will provide European Photovoltaic industry.
Objective: As consumption of psychoactive substances such as alcohol, drugs and certain medicines are likely to endanger the drivers aptitude and impaired driving is still one of the major causes for road accidents, some active steps have to be taken to reach the goal of a 50% reduction in the number of road deaths in the EU. The objective of DRUID is to give scientific support to the EU transport policy to reach the 2010th road safety target by establishing guidelines and measures to combat impaired driving. DRUID will - conduct reference studies of the impact on fitness to drive for alcohol, illicit drugs and medicines and give new insights to the real degree of impairment caused by psychoactive drugs and their actual impact on road safety - generate recommendations for the definition of analytical and risk thresholds - analyse the prevalence of drugs and medicines in accidents and in general driving, set up a comprehensive and efficient epidemiological database.
Project main goals: The main purpose of this project is to develop an innovative 400 kWth solar reformer for several applications such as Hydrogen production or electricity generation. Depending of the feed source for the reforming process CO2 emissions can be reduced significantly (up to 40 percent using NG), because the needed process heat for this highly endothermic reaction is provided by concentrated solar energy. A pre-design of a 1 MW prototype plant in Southern Italy and a conceptual layout of a commercial 50 MWth reforming plant complete this project. Key issues: The profitability decides if a new technology has a chance to come into the market. Therefore several modifications and improvements to the state-of-the-art solar reformer technology will be introduced before large scale and commercial system can be developed. These changes are primarily to the catalytic system, the reactor optimisation and operation procedures and the associated optics for concentrating the solar radiation. For the dissemination of solar reforming technology the regions targeted are in Southern Europe and Northern Africa. The potential markets and the impact of infrastructure and administrative restrictions will be assessed. The environmental, socio-economic and institutional impacts of solar reforming technology exploitation will be assessed with respect to sustainable development. The market potential of solar reforming technology in a liberalised European energy market will be evaluated. Detailed cost estimates for a 50 MWth commercial plant will be determined.
The HyFLEET:CUTE project involves the operation of 47 hydrogen powered buses in regular public transport service in 10 cities on three continents. The Project aims to diversify and reduce energy consumption in the transport system by developing new, fuel efficient hydrogen powered bus technology, and clean, efficient and safe ways of producing and distributing hydrogen fuel. Objectives: - Develop hydrogen powered bus technology in order to reduce the consumption of fuel and energy in the whole transportation system. - Develop efficient and environmentally 'friendly' ways to produce hydrogen. - Research the technology and development needs to establish a hydrogen refueling infrastructure. - Inform the community and key decision-makers about the potential advantages of a hydrogen-based transport system and how they can help to develop it.
Objective: HyLights is a CA facilitating the planning of HyCOM. Focus is an assessment of concluded/ongoing H2/FC demonstration projects and recommendations for the preparation of HyCOM/Lighthouse Projects LP. Although HyLights's assessment focuses on transport stationary and portable H2 applications will be considered if synergies become apparent. HyLights will comprise 3 phases of 12 months each. Phase I includes a methodology definition and assessment, Phase II gaps analysis and development of recommendations and Phase III continuous monitoring. HyLights will need to draw from a network of relevant experts. For this purpose a European Partnership for Hydrogen in Transport EPHT will be established to extend the reach of the European Hydrogen and Fuel Cells Platform HFP. An asset of EPHT will be to include the member states/regions view through a moderation process. Dissemination of the project results will supplement the activity, coherently presenting the European demonstration projects.
The overall objective of ERAP harm is to improve and complement existing knowledge and procedures for the environmental risk assessment (ERA) of human and veterinary pharmaceuticals. Based on EU regulatory frameworks on the ERA of pharmaceuticals and on the outcome of previous projects ERAP harm will address the following aspects: It will investigate previously unstudied major routes leading to exposure of the terrestrial and aquatic environment and subsequent fate of pharmaceuticals in surface water and sediment. Factors and processes affecting the behavior of pharmaceuticals in the environment will be studied on the laboratory, semi-field and fieldscale. A scenario-based exposure assessment system will be developed for predicting concentrations of pharmaceuticals in soils, surface waters and sediments and leaching to groundwater. It will be investigated if environmentally relevant concentrations of pharmaceuticals pose a risk to aquatic and terrestrial organisms. Pharmaceuticals and selected transformation products will be screened using in vitro and low complexity bioanalytical tests in order to provide a first hazard characterization and to target higher tier testing. Higher tier test methods will be improved and applied for detecting the effects of long-term, low-level exposure to pharmaceuticals on aquatic and terrestrial invertebrates and fish. It will be evaluated if information on pharmaco- and toxicodynamics in mammalian species can be used to predict effects of pharmaceuticals on environmental organisms. Moreover, the effects of antibiotics on microbial communities will be studied with a main focus on the spread of genetically encoded resistance. Based on the developed approaches recommendations will be provided on how to improve the ERA procedures for pharmaceuticals. A guidance document will be compiled that will be made available to regulators, industry and the scientific community.
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.
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
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