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H2FC European Infrastructure
Mission statementIntegrating European Infrastructure to support science and development of Hydrogen- and Fuel Cell Technologies towards European Strategy for Sustainable, Competitive and Secure Energy
Commercial?Science and develeopement support project
Type of projectCorporation governed by public law
ProductsServices
LocationEurope
FounderEuropean Comission
Key peopleDr. Olaf Jedicke (Karlsruhe Institute of Technology)
Established1 November 2011 (2011-11-01)
Disestablished31 October 2015 (2015-10-31)
StatusActive
Websiteh2fc.eu



H2FC European Infrastructure

File:LogoH2FC
Emblem of the H2FC European Infrastructure

H2FC was a European Research Infrastructure project running in the 7th Framework Programme of European Commission under Capacities. "H2FC" appears as an acronym for the extensive title of the project: Integrating European Infrastructure to support science and development of Hydrogen- and Fuel Cell Technologies towards European Strategy for Sustainable Competitive and Secure Energy. The focus of the project was set on supporting research and development in fuel cells and hydrogen technology. The runtime of H2FC was 48 months, covered a budget of 10.217.426, 00 € and was composed by 19 leading European research organisations. H2FC was structured as a typical "Integrating Activity" which consists out of three main pillars to support specific necessities in the thematic priority areas. These main pillars are "Joint Research Activities" to improve and modify technical installations and measurements systems according scientific demands, "Networking Activities" to team, exercise and educate engineers and scientists from the different communities and "Access Activities" to support science and development by offering experimental facilities and test benches for scientific investigations, free of charge for external users. In this regard, H2FC executed more than eighty user projects distributed in three generic topical categories of hydrogen technology. These categories were: fuel cells in general, hydrogen production and storage and hydrogen safety related issues. The scientific work done within the project generated more than 250 different publications and conference contributions (status June 2015).
Current information can be found in the latest e-journal, even after the end of the project new e-journals will be published.
There are also some events about Hydrogen and Fuel Cell Technologies.


Project History

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One of the most important challenges of humanity is the continuous provision of energy. Different concepts based on renewable energy got created to fulfil the growing world energy demand, while geological resources decreasing. Apart from other concepts, concepts using hydrogen as an energy carrier are most promising. Meanwhile an adequate technical status became achieved and several unique demo projects like to demonstrate the usability of so called “hydrogen technology” including also hydrogen driven fuel cells. However, a widely expanded implementation of this technology within daily life is still missing and just several special applications are visible based on demo projects.

Concept and project objective

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General Setting

Because of the continuous decarbonisation of energy vectors, the need for efficient conversion processes and flexible energy storage the usage of hydrogen and fuel cell technologies will increasingly be favoured. The broader utilization of otherwise lost renewable energy, for example wind- and sun-energy, is supported by the adoption of hydrogen and fuel cell technologies. On top this expectation is also supported by most of the accepted strategic documents. Therefore the European Strategy Forum on Research Infrastructures (ESFRI), recognizes in its European Road map for Research Infrastructures that

"in the near future, hydrogen, as an energy carrier derived from a number of other fuels, and fuel cells, as energy transformers, are expected to play a major role, for both mobile and stationary applications"

— European Strategy Forum on Research Infrastructures, Report 2006


Overview of H2FC European Infrastructure

The broad market introduction of hydrogen technologies, including fuel cells, is currently not possible because they do not reach the required cost and performance targets. To reach this aim, some safety and the puplic acceptance need to be increased, e.g. by more consistens information. The Fuel Cells and Hydrogen Joint Undertaking (FCH JU), which supports the demonstration of the currently available hydrogen technologies, addressed numerious of these issues. A positively stimulation of the greater involvement of industry and commerce in the field is expected by the implied rearrangement of the European funding strategy. Major open issues which require further investigation are still unsolved even if the current state shows huge efforts. Therefore additional research work on the fundamental and applied levels needs to be done. This R&D enables commercial sucess of hydrogen technologies in the future. H2FC European Infrastructure aims at filling this gap and supporting the necessary research work by providing the required world class research infrastructure. In brief, H2FC European Infrastructure complements the JU activities and facilitates tackling major R&D bottlenecks in the field by making available the necessary advanced infrastructures to the European research community. [1]

H2FC European Infrastructure addresses the topic INFRA-2011-1.1.16 Research Infrastructures for Hydrogen and Fuel Cells Facilities and the related energy-chains, by bringing together, for the first time in Europe, the leading European research institutions of the hydrogen community together with those of the fuel cell community, covering the entire life-cycle of hydrogen and fuel cells, i.e. hydrogen production, storage, distribution, and final use in fuel cells. A limited number of organizations, mainly national research centres, maintain a range of significant, partially unique test and analysis equipment, ranging from high stability fuel cell test rigs suitable for long-term durability testing, neutron beam and synchrotron devices, to facilities capable of assessing the risk of fire or explosion for hydrogen fuelled devices, components and systems. All these facilities have been developed and installed on the basis of significant investment. Their operation and maintenance incur considerable costs. For the academic teams from universities or small spin-offs - the typical drivers of new innovative hydrogen and fuel cell solutions - there is neither coordinated nor affordable access to this dispersed research infrastructure. So it is not surprising that virtually none of the new fuel cell materials that are published in academic journals are subjected to long-term durability testing on qualified test rigs. Similarly, without the appropriate advanced safety testing due to the limited access to suitable facilities, investment in the development of materials and components has been lost in several cases. On the other hand the steady flow of innovation in this new field of research needs continuous adaptation to new directions, new materials and new solutions. With the current fragmentation of the European research infrastructure and the uncoordinated approaches, the demand for effective support for the technology developers cannot be satisfied. Therefore this proposal is built in order to integrate the European research community around rare and/or unique infrastructural elements that will facilitate and significantly enhance the research outcome.

Since the hydrogen and fuel cell community is scattered in terms of degree of maturity or industrial relationship, the first step to integrate this community and enhance the overall performance is to create a virtual infrastructure around the participating national research centres and to invite researchers in SMEs, large industry and universities to use this infrastructure. Bridging national research centres and university research through joint access to the best European infrastructure is in line with the “European Research Area: New Perspectives, Green Paper 04.04.2007” underpinning this interaction of the European Research Area and the European Higher Education Area. Although some preliminary integration of safety research has been provided by the FP6 NoE HySafe, the bridging of the so far disjoint groups, dealing with hydrogen technologies on one side and fuel cells on the other, will further the understanding of the research requirements on both sides and help to install a worldwide leading, unique community and infrastructure respectively.
To generate a structured and integrated alliance based on complementary, state-of-the-art, or even beyond state-of-the-art unique infrastructures to serve the demands of the scientific hydrogen and fuel cells community and facilitate future research are the main topics of H2FC European Infrastructure. General aims of H2FC European Infrastructure can be summarised as:

  • To accommodate hydrogen and fuel cell communities’ test and analysis facilities a single integrated virtual infrastructure will be provided
  • Providing transnational access to member state infrastructures for the hydrogen and fuel cell research communities
  • To enhance work at the provided facilities and to seek more general coordination in safety, performance and durability a number of expert working groups is created
  • Providing central databases/libraries of safety, performance and durability data, modelling codes
  • Coordinating test and assessment facilities, relevant education and trainings, use and maintenance of hydrogen and fuel cell research, pertinent to the set-up
  • Improving and integrating the existing infrastructure
  • Coordinating actions with (inter-)national bodies, with industry and academic demands

[2]

Project Partners

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Name of the Organisation Location
Karlsruhe Institute of Technology (KIT) Karlsruhe,  Germany
Alternative Energies and Atomic Energy Comission (CEA) Saclay, Cadarache, Grenoble,  France
University of Ulster (UU) Coleraine, Belfast, Jordanstown, Derry,  Northern Ireland
Institute for Energy Technology (IFE) Kjeller,  Norway
Health and Safety Laboratory (HSL) Buxton,  England
European Commission, Directorate-General Joint Research Centre, Institute for Energy and Transport (JRC) Petten,  Netherlands
Jülich Research Centre Jülich,  Germany
Paul Scherrer Institute (PSI) Villigen, Würenlingen,  Switzerland
Natinal Center for Scientific research "Demokritos" (NCSRD) Athens,  Greece
University of Perugia Perugia,  Italy
Italian National Agency for New Technologies, Energy and Sustainable Economic Development (ENEA) Bologna, Brindisi, Rome, Naples, Vercelli, La Spezia, Matera,  Italy
Federal Institute for Materials Research and Testing (BAM) Berlin,  Germany
Tecnalia Research & Innovation Donostia-San Sebastián,  Spain
University of Pisa Pisa,  Italy
Pro-Science (ENEA) Ettlingen,  Germany
National Physical Laboratory (NPL) Teddington,  England
Stiftelsen for industriell og teknisk forskning (SINTEF) Trondheim,  Norway
Technical Research Centre of Finland (VTT) Espoo,  Finland
Swiss Federal Laboratories for Materials Science and Technology (EMPA) Dübendorf, St. Gallen, Thun,  Switzerland

[3]

Progress beyond the state of the art

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File:LogoHysafe
Emblem of Hysafe

The state of the art concerning safety related hardware research infrastructure has been defined in the EC NoE HySafe. The integration of the experimental facilities for hydrogen safety research has been one of main activities within this network. The process aimed at creating a common experience and knowledge on hydrogen safety in Europe via the common use and harmonisation of the fragmented research base. The creation of a set of specialised research facilities enabled the network to jointly define, rank and perform test series for investigation of relevant phenomena, for testing devices and concepts as well as for validation of numerical models. An overview of about 100 European large facilities is given online.
The facilities address most of the applications defining the horizontal topics of the HySafe activity matrix:

  • hydrogen production
  • transport
  • refuelling stations
  • storage
  • vehicles
  • tunnels, public parking and private garage
  • utilisation
  • portable and stationary applications

[4]
The following phenomena, vertical topics respectively, are accounted for:

  • hydrogen release, mixing and distribution
  • fires, ignition and explosions
  • mitigation techniques
  • safety assessment and risk analysis
  • standardisation and legal requirements

[4]
Measurement techniques for dispersion phenomena consist of optical measurements, laser application, Schlieren techniques and concentration sensors. The measurement procedures for the reactive properties of homogeneous, single phase hydrogen / air gas mixtures are standardised. Pressure measurement is cheap and fast, thermal measurements are usually done with thermocouples, IR cameras, or special pyrometers.
In the case of fuel cell testing, efforts to define harmonized test procedures were undertaken in the Fuel Cell Testing and Standardization Network FCTESTNET and Fuel Cell Systems Testing, Safety and Quality Assurance FCTES QA projects, what defines the state-of-the-art in this field. In the work proposed, the state defined by FCTESTNET and FCTES QA will be expanded by addressing intercomparison of testing equipment and testing protocols as well as interoperability of hardware. [5] [6]
The state-of-the art concerning infrastructure and development of hydrogen storage materials is that several instrumental facilities are available at different partners in Europe. Most of them have already been used in various European projects such as StorHy, NESSHy, and NANOHy. These facilities have, however, not been used in or enabled for a targeted approach towards general development of methodology for a general and sound qualification of hydrogen storage materials or [[hydrogen tank|tanks]. In most cases, single aspects were addressed and an overall qualification has not been possible so far because an appropriate methodology is not available. Hence, it is necessary to address missing parts in this methodology and to combine cycling properties of hydrogen storage materials not only with structural aspects but also with safety-relevant features of the material comprising exposure tests up to tank tests in suitable test rigs. [7] [8] [9]

Pogress by Integration

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Members of the hydrogen and fuel cell community are numerous, ranging from basic research laboratories, e.g. in the case of solid hydrogen storage or intermediate temperature fuel cells, to industry in the case of hydrogen production and transport, liquid hydrogen properties or fuel cell system integration and optimization. Moreover, historically there has been no commonly organised access to test and analysis facilities owned by national research centre type organisations (including high profile universities) in respect to hydrogen and fuel cell development. This state-of-the-art sets the basis for designing and actually developing an integrated hydrogen and fuel cell research infrastructure, which defines the main objective of the H2FC European Infrastructure project. The coordinated building up and providing access to an integrated, high capacity and quality research infrastructure evidently is a significant improvement.
It is in fact the first time that the formerly separate expert groups from fuel cell research and hydrogen research are working on a common program. Thereby H2FC European Infrastructure offers a unique opportunity where both sides will benefit from the close cooperation, improve understanding of the problems and challenges of the other group, and learn how to use better the existing and future capacities.
While EU actions supporting the european research area (ERA) concept in the specific area of hydrogen and fuel cell research exist (e.g. Marie-Curie actions, Networking activities), and while there is an increasing number of demonstration projects in hydrogen and fuel cells, there is no action for the integration of the research, testing and assessment infrastructures used in this area. The structure proposed in H2FC European Infrastructure would realize an alliance of the EU scientific community for serving the needs of the scientific community itself. Specifically, EU national research centres and universities with unique infrastructures will provide access to the hydrogen and fuel cell scientific community, with particular attention to provide access to researchers located in member states and candidate countries where a reduced number of infrastructures are available. On the other side the project will account for industry needs. The industry perspective will be specified by the advisory council and confirmed in those dissemination activities, which link the infrastructure to the industry driven Fuel Cells and Hydrogen Joint Undertaking and European Hydrogen Association.

Pogress by Networking

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None of the European institutions in hydrogen and fuel cell research has the critical mass of human resources and facilities to secure leadership in the global market in the broad range of interconnected hydrogen and fuel cell technologies and their applications. Only joint efforts of European countries through building and development of contemporary H2FC European Infrastructure could guarantee the leadership and competitiveness of Europe’s intellectual and commercial products in the field. The key role to achieve successfully this goal and overcome existing fragmentation of hydrogen and fuel cell research in Europe belongs to Networking Activities, one of three cornerstones of the proposal along with Transnational Access and Joint Research Activities (JRA).
Networking activities will enhance the services provided by the best H2FC European Infrastructure in many ways:

  • Providing straightforward procedures and easy access for European stakeholders to the H2FC European Infrastructure staring from online application (entry point) through to on-site supervision and support
  • Sharing of knowledge, data, methods, protocols and technologies across the whole network of European stakeholders through different communication channels, including but not limited to the web portal to be maintained beyond the project end, various scientific gatherings, etc.
  • Developing complementarities and synergies between leading European institutions in terms of facilities performance and coherent planning/operation to provide the best research infrastructure and its access for European users undertaking research in basic and applied problems in the field
  • Creation of a unique virtual Cyber-Laboratory, distributed throughout the Europe, to assist users in modelling and simulation of processes relevant to hydrogen and fuel cell technologies, including pre-test simulations to make experiments more cost-effective and less time consuming
  • Enhancement of European cadre potential in the field through comprehensive education and training of both project partners and other European users of the H2FC European Infrastructure in the state-of-the-art experimental, theoretical and analytical methods in this multi-disciplinary field of ERA
  • Collaboration with similar facilities in third countries through different channels, including but not limited to technical school, road mapping and foresight
  • Cross-fertilization of knowledge and skills of partners through the exchange programme aiming to enhance quality of transnational access and relevant services for European users of the H2FC European Infrastructure


They will foster a culture of cooperation between the participants and the scientific communities benefiting from the use of the state-of-the-art facilities of project partners through:

  • Joint participation in annual meetings of European Panel on Hydrogen and Fuel Cells to indentify and prioritise bottlenecks in basic and applied research in the field, as well as solution mining
  • Participation of both partners and users in the proceedings of the technical school, including work-in-progress sessions, round-table discussions, advanced research workshops, instrumentation workshops, CFD seminars
  • Information exchange and coordination of national, European and international research activities, projects and organizations (Fuel Cells and Hydrogen Joint Undertaking (FCH-JU), International Partnership for Hydrogen and Fuel Cells in the Economy (IPHE), International Energy Agency Hydrogen Implementing Agreement(IEA HIA), United States Department of Energy (DoE)), including shaping of European and global research agenda in the field, through different NA activities where stakeholders from outside the project take an active part
  • Support of new emerging centres of excellence in hydrogen and fuel cell research in Europe through their engagement in open to all stakeholders activities within NA, e.g. schools and panels, and TA, e.g. specific calls, of the project
  • Establishing and working together in editorial boards for publishing journals and handbooks in the field during the project and beyond 2015 thus building together the future of the H2FC European Infrastructure


Special attention will be paid in networking activities to attract female researchers for the benefit of gender equality within the H2FC European Infrastructure during the project and beyond.

Progress by Joint Research

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With regard to research capabilities and capacities the advances that H2FC European Infrastructure will provide via the common research activities represent the essential progress beyond the state-of-the art. The members of the consortium have been selected to provide state-of-the-art testing and analysis facilities and capabilities. The Joint Research Activities, however, are designed to improve the quality and quantity of the scientific services beyond the current status, to provide a world leading sustainable infrastructure to European researchers and industry. The Joint Research is organised in four different work packages:

  • addressing bottlenecks in the field of basic phenomena
  • component and system evaluation
  • protocols and round robin testing (RRT)
  • and all related numerical simulation.


Thus software and hardware infrastructures are addressed in a concerted way.
The gaps realised in the HySafecommunity and by its international advisory board are mainly related to general sensor performance, to the spatial and temporal resolution of concentration and temperature measurements, to the applicability of measurement technologies to large scale scenarios, to liquid hydrogen with its cryogenic temperatures. Another weak point is that there are no facilities for providing well specified gradient mixtures, those encountered in real accident scenarios. Whereas calibration methods for experimental and safety sensors are established no standard for the performance of sensors in real applications is available. Well defined and agreed test strategies for solid storage material and tank systems are lacking. Most of these required improvements are addressed in the H2FC European Infrastructure research program. The successful implementation of the work is supported by a close collaboration with the NoE HySafe follow-up, the International Association for Hydrogen Safety and will be continuously reviewed and refined- by the road-mapping and foresight activity.
In the case of fuel cell testing, efforts to define harmonized test procedures were undertaken in the Fuel Cell Testing and Standardization Network (FCTESTNET) and Fuel Cell Systems Testing, Safety and Quality Assurance (FCTES QA) projects, which define the state-of-the-art in this field. In the work proposed, the state defined by FCTESTNET and FCTES QA will be expanded by addressing intercomparison of testing equipment and testing protocols as well as interoperability of hardware, in particular for new fuel cell developments characterised for instance by high power densities. In addition, new experimental methods have been developed for non-standardized testing of fuel cell performance. Such new experimental methods prove spatially resolved signals or consist of a combination of experimental techniques. Within the JRA improved instruments with enhanced spatial and temporal resolution of signals from fuel cell testing and analysis will be developed thus allowing deeper insight into the processes going on during operation of a fuel cell. The improvement work will be carried out making use of the advice from the European expert networks. The improved instruments will be developed to study one of the most challenging issues, which is degradation and prediction of lifetime. The results of this Joint Research Activities (JRA) will be beneficial for other existing projects such as DECODE which is addressing degradation issues in PEFC. The objectives of the JRA are exceeding the scope of these existing projects by including aspects of high temperature fuel cells as well as hydrogen embrittlement into account.
Yet another important aspect of fuel cell testing and operation is the quality of the hydrogen fuel. Activities in China, the U.S. and Japan as well as in SAE or other international standard developing organisations are under way to investigate the influence of fuel and oxidant quality on the performance and endurance of fuel cells. Networking with these International Partnership for Hydrogen and Fuel Cells in the Economy (IPHE) endorsed activities will support the progress in the EU based H2FC European Infrastructure and avoid duplication of work on an international scale. The related work proposed in the JRA will go beyond the state of the art by analyzing and improving reference methods and measurement techniques for fuel quality characterisation. Validation of the findings on reference stacks will define a new state of the art related to hydrogen fuel quality measurement.
An important contribution by the joint efforts in this project is the combination of various infrastructures in order to develop a methodology to test hydrogen storage materials with respect to a later use in a hydrogen storage system. The proposed work aims at combining structural properties with cycling behaviour and includes safety-relevant features such as time-dependent heat of reaction in various environments of the material. Moreover, the storage material will not only be cycle-tested but system relevant properties of tanks will be assessed in appropriate test rigs including safety tests. The goal of this activity is a harmonization of methods and information in order to tackle in an integrated way the controversy over measured storage capacities on different types of materials and the lack of reliable safety and performance (life cycle) assessment of solid-state storage materials and components.

Progress Regarding Software Infrastructure

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One problem addressed in the Cyber-Laboratory work package 10 (WP 10) is the lack of orientation caused by a large number of poorly evaluated models and CFD tools that are in principle available to simulate and/or evaluate experiments. Selecting, evaluating and integrating appropriate models and tools will form a unique software infrastructure to analyse also the risk of real world H2 applications. These codes include both, “in house” research developments and commercial software. Several examples indicate that the predictive capabilities of these codes vary significantly, even for relatively simple problems. Reasons for this unacceptable spread in numerical predictions include the utilisation of obsolete or generally restricted models, and quite frequently the application of models outside their validity range. An integration of the expertise of H2FC European Infrastructure partners in the frame of WP 10 has the potential to synthesise the subcritical fragmented efforts into a coordinated strong activity, thus to eliminate the described problems and to bring CFD simulation for modelling of complex phenomena like accidental combustion of H2, hydrogen behaviour in storage materials, thermal management in storage tanks or fuel cell modelling to a much higher level of quality and reliability.
Earlier European Commission funded work directly related to the software infrastructure was performed during the Framework Program 5 - European integrated hydrogen project (FP5-EIHP2) and Network of Excellence (FP6 NoE) HySafe projects. The work in EIHP2 included computational investigation of small hydrogen releases in a bus maintenance facility and concluded that the various issues related to H2 releases in vehicle support facilities need to be addressed in a broader and more systematic way. The simulations in HySafe were focussed on the “research headlines”, namely releases in partially confined areas like private garages and tunnels and addressed benchmarking and pre-test calculations. Risk assessment benchmarking was only initiated in HySafe, while large scale releases to an open environment and thermal and pressure effects of consequent combustion were not considered. Draft recommendations for the use of H2 in confined spaces was summarised in the InsHyde final report.
WP 10 aspires to comprise a platform for the identification of appropriate models and computational tools and their ranges of applicability. One of the final objectives of the WP 10 is to provide guidelines for the correct utilisation of the available and new CFD models and in its work plan it will address the problems specific to hydrogen safety issues, e.g. the choice of turbulence models for hydrogen dispersion, the choice of combustion models for different explosion events, the choice of flow models suitable for large-scale complex geometries, etc. The proposed JRA will organise an effective exchange of information concerning the models and the codes and will perform intensive RRT on a number of carefully selected cases. It will identify gaps and carry out the necessary experiments to obtain missing critical data for the model and code validation. It will finally result in an open library of appropriately verified models and software modules, for use by the scientific community with specific guidelines as to their range of applicability and specific predictive features.

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Finally, the proposed transnational access and research services have been selected on the basis of high quality facilities and the expertise of the operational staff. They have also been selected because they address current bottlenecks in the hydrogen and fuel cell energy chain development in the two major domains of “Safety and risk evaluation” and “Performance and Durability".
The primary risk with hydrogen as a fuel is that of fire/explosion. Explosion testing and analysis activities require state-of-the-art facilities. Those explosion test facilities being offered by the H2FC European Infrastructure are widely recognised as being amongst the best in the world. They draw on the experience and capabilities mainly of German, French and British national research and test facilities – themselves deriving from nuclear, gas, military and transport testing requirements. In addition to being able to carry out physical tests, these facilities offer extensive measurement and analytical capabilities. The teams working with these installations provide additional unique expertise in the assessment of gas diffusion issues and the risks of explosion resulting from system or transport leakage.
In the case of “Durability and Performance” the H2FC European Infrastructure project has selected high quality installations covering materials and component performance and durability testing, as well as associated support for providing rapid prototyping services and post mortem characterisation. The main criteria for choosing facilities to make available in the H2FC European Infrastructure project were based on the major development bottlenecks to be addressed and the excellence of the facilities. This is, for example, the case with CEA’s unique ability to reconstitute the water profile through the Membrane Electrode Assembly (MEA), a key issue in polymer based fuel cells, in the EDIP installation operated under neutron beam. It is also the case for the full complement of mechanical testing facilities, including the ability to carry out tests under stationary or cycling conditions under severe fuel atmospheres and temperature ranges of up to 2000°C. The same approach has been followed also in the field of hydrogen detection and hydrogen storage and distribution, with facilities able to test in real operative conditions any type of safety sensors and high-pressure components. In addition, as a support to these sophisticated experiments, rapid prototyping facilities are also provided allowing, for example, an academic laboratory developing a new electrode material to integrate in a few weeks that material into a cell for testing. Moreover, these rapid prototyping facilities automatically produce cells of the correct dimensions and geometry that allow standardised performance and durability testing directly comparable to the state-of-the-art fuel cells. Prima facie some of the facilities offer standardised fuel cell test rigs, which are not rare or even unusual, but, in addition to the “rare or unique” instrumented test it appears of most interest to be able to ensure the reliability, accuracy and repeatability of measurements thanks to qualified testing.
Improvement for the European hydrogen and fuel cell community is clearly achieved by providing a previously non-existent coordinated access to these facilities and a continuous improvement of the related services by the specially targeted Research Activities and by the educational efforts contained in the Networking Activities.
The progress beyond the state of the art that H2FC European Infrastructure would bring about is only partially visible from the single work package or activity, if considered one by one. The real progress beyond the state of the art, offered by H2FC European Infrastructure is provided by its unique structure, where all these activities interact with each other with the ultimate goal of integrating the EU hydrogen and fuel cell research infrastructure.

Scientific/Technical Methodology and associated work plan

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The main objective of H2FC European Infrastructure is to generate a coordinated and integrated alliance based on complementary, state-of-the-art, or even beyond state-of-the-art unique infrastructures to serve the needs of the scientific hydrogen and fuel cells community and facilitate world class research. The current key research topics identified are:

Thematic Structure of H2FC European Infrastructure
  1. Reducing degradation and increasing performance of electrolysers, hydrogen storage systems and fuel cells
  2. Assessing and reducing hazards and risks associated with the use of hydrogen or hydrogen blended fuels and thereby ensuring the appropriate safety level of systems.
  3. Improving current storage technologies, in particular through advanced materials research.


The three pillars the H2FC European Infrastructure is built on are networking, transnational access and joint research, sub-structured in work packages (WP) and again in tasks. All activities are strongly interrelated and oriented along the bottlenecks listed in Joint Research Activities below.

Networking
The integration activities of the networking constitute as general services the backbone of the networking and, in fact, of the whole project. This activity block accommodates the central entry point, networking work package WP 2, which coordinates the transnational access and a road-mapping and foresight activity, which steers the joint research activities. The latter two activity blocks will be motivated as follows.
The integration shall be based on procedures for intense communication, procedures to screen the field for new developments and periodically update the joint research activities, procedures to monitor opportunities for additional funding for the further development of the infrastructure and common research, and procedures for regularly disseminating the services and results. Rotational visits to the partners’ labs and short term exchange of technical staff and researchers will promote knowledge transfer of the capabilities of the partners. In workshops measurement technologies will be discussed and good practice will be disseminated both internally and externally. Industry focussed seminars, academic courses and a special journal will spread the knowledge openly and will document the capabilities to the external community. A WEB 2.0 based internet website will serve as central database server, as a collaboration and information tool and will support the daily management and dissemination efforts.

Transnational Access
Removing the national access barriers alone is unlikely to provide the required integrated and coordinated high performance infrastructure, as the most sophisticated facilities are not located in a single member state, and many member states simply do not possess national resources of this type at all. Therefore we propose a strong “Transnational Access” element in the project. As such H2FC European Infrastructure presents itself as an ideal candidate for FP7 support under the Capacities programme.

Joint Research Activities
The H2FC European Infrastructure gathers facilities with a high level of measurement capability and the ability to carry out measurement under all H2 and Fuel Cell relevant conditions to maintain the European level of competitiveness. However, continuing progress in the field results in the necessity of updating the existing instrumentation and methodologies in order to have them best adapted to the operating conditions found to be relevant in respect of new hydrogen technologies applications.
It is the main purpose of the proposed Joint Research Activities (JRAs) to improve the competitiveness of European research infrastructure for the whole hydrogen energy chain and fuel cell technologies with a major emphasis given to the development of all kind of characterisation methods, instrumentation, protocols, experimental chambers etc. liable to improve the study, analysis and understanding of the current H2 and FC technology bottlenecks.
As such the JRAs are expected to strongly support the deployment of hydrogen and fuel cell technologies by enhancing the capability of existing high level research infrastructures and their services. This in turn is expected to enhance fundamental research activities in the field and to help overcome current bottlenecks limiting hydrogen and fuel cell market entry. Since these are essentially due to material properties and component durability in the presence of hydrogen the JRAs are organised in the following four work packages. The first two are addressing more specifically safety and risk assessment related to hydrogen public deployment, and durability of material, components and systems at economically relevant performance levels.

Technology Portfolio

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Mapping of some key facilities of H2FC European Infrastructure

The consortium capabilities cover the entire life cycle of hydrogen technologies and fuel cells, from material issues in bipolar plates, electrodes, catalysts, electrolytes, piping and pressure vessels, hydrogen production, through storage, distribution and finally to power conversion in fuel cells or combustion engines. Research on cross-cutting issues, in particular hazards, risks and safety, is perfectly accommodated in the consortium’s facilities, which have proven to be worldwide leading, in particular with regard to hydrogen release and combustion analysis and with regard to sensor evaluation and calibration. The consortium has a unique position concerning the development and in particular the evaluation of solid storage materials, which need further research for approaching market entry. Other outstanding capabilities and capacities with respect to cross-cutting items concern the software tools and educational and training infrastructures.










References

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  1. ^ [1], Hompage of H2FC
  2. ^ [2], Hompage of H2FC
  3. ^ [3], Hompage of H2FC
  4. ^ a b [4], Hompage of Hysafe
  5. ^ [5], Hompage of European Commission - Institute for Energy and Transport - FCTESQA
  6. ^ [6], Hompage of European Commission - Institute for Energy and Transport - FCTESTNET
  7. ^ [7], Hompage of StorHy
  8. ^ [8], Hompage of NESSHy
  9. ^ [9], Hompage of NANOHy