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FRENCH RESEARCH STRATEGY TO USE NUCLEAR REACTORS FOR HYDROGEN PRODUCTION References Borgard, J.M., D. Doizi (2009), “Energy Analysis of the CuCl Hybrid Cycle”, these proceedings. Brown, L.C., G.E. Besenbruch, R.D. Lentsch, et al. (2003), High Efficiency Generation of Hydrogen Fuels Using Nuclear Power, Final technical report for the period 1 August 1999 through 30 September 2002 from General Atomics Corp. to US DOE, GA-A24285, June. Doenitz, W., R. Schmidberger (1982), “Concepts and Design for Scaling-up High-temperature Water Vapor Electrolysis”, Int. J. Hydrogen Energy, 7, pp. 321-330. Doenitz, W., E. Erdle (1985), “High-temperature Electrolysis of Water Vapor Status of Development and Perspective for Application”, Int. J. Hydrogen Energy, 10, pp. 291-295. Doenitz, W., et al. (1988), “Electrochemical High Temperature Technology for Hydrogen Production or Direct Electricity Generation”, Int. J. Hydrogen Energy, 13, pp. 283-287. Doenitz, W., et al. (1988), “Recent Advances in the Development of High-temperature Electrolysis Technology in Germany”, Proceedings of the 7 th World Hydrogen Energy Conference, Moscow, pp. 65-73. Doenitz, W., E. Erdle, R. Streicher (1990), Electrochemical Hydrogen Technologies., H. Wendt (Ed.), Elsevier, p. 213. Doizi, D., et al. (2007), “Total and Partial Pressure Measurements for the Sulphur-iodine Thermochemical Cycle”, Int. J. Hydrogen Energy, 32 (9), 1183-1191. Doizi, D., et al. (2009), “Experimental Study of the Vapour-liquid Equilibria of HI-I2-H2O Ternary Mixtures. Part 1: Experimental Results Around the Atmospheric Pressure”, Int. J. Hydrogen Energy, forthcoming. Doizi, D., et al. (2009a), “Optical Study of the Hydrolysis Reaction of the CuCl Thermochemical Cycle”, these proceedings. Floch, P.H., et al. (2007), “On the Production of Hydrogen via Alkaline Electrolysis During Off-peak Periods”, Int. J. Hydrogen Energy, 32, 4641-4647. Goldstein, S., J.M. Borgard, X. Vitart (2005), “Upper Bound and Best Estimate of the Efficiency of the Iodine Sulphur Cycle”, Int. J. Hydrogen Energy, 30, 619-626. Kubo, S., et al. (2004), “A Pilot Test Plan of the Thermochemical Water-splitting Iodine-Sulfur Process”, Nuclear Engineering and Design, 233 (1-3), 355-362. Larousse, B., et al. (2009), “Experimental Study of the Vapour-liquid Equilibria of HI-I2-H2O Ternary Mixtures, Part 2: Experimental Results at High Temperature and Pressure”, Int. J. Hydrogen Energy, forthcoming. Le Naour, F., P. Baurens, C. Mansilla (2009), “High Temperature Steam Electrolysis for Nuclear Hydrogen: Production Interest, Technological Breakthrough and CEA’s Strategy”, Proceedings IAEA TM on Non-electric Applications of Nuclear Energy, Daejeon, Korea, 3-6 March. Moore, R., et al. (2008), Proceedings HTR 2008, Washington, 28 September-1 October. O’Keefe, D.R., et al. (1982), “Preliminary Results from Bench-scale Testing of Sulphur-iodine Thermochemical Water-splitting Cycle”, Int. J. Hydrogen Energy, 7 (5), 381-92. Rivera-Tinoco, R., C. Mansilla, C. Bouallou (2008), “Techno-economic Study of the High Temperature Steam Electrolysis Process Coupled with a Sodium Nuclear Reactor”, WHEC 2008, Brisbane, June. Westinghouse Electric Corporation (1980), A Study on the Electrolysis of Sulfur Dioxide and Water for the Sulfur Cycle Hydrogen Production Process, AESD-TME-3043, July. 46 NUCLEAR PRODUCTION OF HYDROGEN – © OECD/NEA 2010
PRESENT STATUS OF HTGR AND HYDROGEN PRODUCTION DEVELOPMENT IN JAEA Present status of HTGR and hydrogen production development in JAEA Masuro Ogawa, Ryutaro Hino, Yoshiyuki Inagaki, Kazuhiko Kunitomi, Kaoru Onuki, Hiroaki Takegami Japan Atomic Energy Agency, Japan Abstract The high temperature gas-cooled reactor (HTGR), which is graphite-moderated and helium-cooled, is particularly attractive due to its unique capability of producing high temperature helium gas in addition to its fully inherent and passive safety characteristics. The HTGR-based production of hydrogen, the energy carrier for an emerging hydrogen economy, is expected to be among the most promising applications to solve the current environmental issues of CO 2 emission. With this understanding the development studies of HTGR cogeneration system including hydrogen production have been carried out in Japan. This paper presents the 2100 vision of JAEA on future perspective of energy supply, especially on HTGR utilisation in the field of iron manufacturing, chemical industries, oil refineries, etc. In addition, this paper presents the present status of the HTTR Project including research and development activities of HTGR reactor technology, hydrogen production technology with the thermochemical water-splitting IS process, and the commercial HTGR plant design. NUCLEAR PRODUCTION OF HYDROGEN – © OECD/NEA 2010 47
Page 1: Nuclear Science 2010 Nuclear Produc
Page 4 and 5: ORGANISATION FOR ECONOMIC CO-OPERAT
Page 7 and 8: TABLE OF CONTENTS Table of contents
Page 9 and 10: TABLE OF CONTENTS Y. Gong, E. Chalk
Page 11 and 12: EXECUTIVE SUMMARY Executive summary
Page 13 and 14: EXECUTIVE SUMMARY steam turbine, in
Page 15 and 16: EXECUTIVE SUMMARY sulphur depositio
Page 17 and 18: EXECUTIVE SUMMARY affords saving 35
Page 19 and 20: EXECUTIVE SUMMARY safety assessment
Page 21: EXECUTIVE SUMMARY The question was
Page 24 and 25: CHANGING THE WORLD WITH HYDROGEN AN
Page 35 and 36: NUCLEAR HYDROGEN PRODUCTION PROGRAM
Page 37 and 38: NUCLEAR HYDROGEN PRODUCTION PROGRAM
Page 39 and 40: FRENCH RESEARCH STRATEGY TO USE NUC
Page 47: FRENCH RESEARCH STRATEGY TO USE NUC
Page 51 and 52: PRESENT STATUS OF HTGR AND HYDROGEN
Page 61 and 62: STATUS OF THE KOREAN NUCLEAR HYDROG
Page 69 and 70: THE CONCEPT OF NUCLEAR HYDROGEN PRO
Page 77: THE CONCEPT OF NUCLEAR HYDROGEN PRO
Page 80 and 81: CANADIAN NUCLEAR HYDROGEN R&D PROGR
Page 90 and 91: APPLICATION OF NUCLEAR-PRODUCED HYD
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APPLICATION OF NUCLEAR-PRODUCED HYD
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APPLICATION OF NUCLEAR-PRODUCED HYD
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STATUS OF THE INL HIGH-TEMPERATURE
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HIGH-TEMPERATURE STEAM ELECTROLYSIS
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MATERIALS DEVELOPMENT FOR SOEC Mate
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A METALLIC SEAL FOR HIGH-TEMPERATUR
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DEGRADATION MECHANISMS IN SOLID OXI
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CAUSES OF DEGRADATION IN A SOLID OX
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70 μm CAUSES OF DEGRADATION IN A S
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NUCLEAR HYDROGEN USING HIGH TEMPERA
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SESSION III: THERMOCHEMICAL SULPHUR
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CEA ASSESSMENT OF THE SULPHUR-IODIN
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STATUS OF THE INERI SULPHUR-IODINE
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INFLUENCE OF HTR CORE INLET AND OUT
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EXPERIMENTAL STUDY OF THE VAPOUR-LI
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DEVELOPMENT OF HI DECOMPOSITION PRO
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SOUTH AFRICA’S NUCLEAR HYDROGEN P
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INTEGRATED LABORATORY SCALE DEMONST
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DEVELOPMENT STATUS OF THE HYBRID SU
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RECENT CANADIAN ADVANCES IN THE THE
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AN OVERVIEW OF R&D ACTIVITIES FOR T
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STUDY OF THE HYDROLYSIS REACTION OF
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DEVELOPMENT OF CuCl-HCl ELECTROLYSI
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EXERGY ANALYSIS OF THE Cu-Cl CYCLE
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CaBr 2 HYDROLYSIS FOR HBr PRODUCTIO
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SESSION V: ECONOMICS AND MARKET ANA
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DEVELOPMENT OF THE HYDROGEN ECONOMI
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NUCLEAR H 2 PRODUCTION - A UTILITY
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ALKALINE AND HIGH-TEMPERATURE ELECT
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THE PRODUCT OF HYDROGEN BY NUCLEAR
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SUSTAINABLE ELECTRICITY SUPPLY IN T
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PROHYTEC, THE FRENCH INDUSTRIAL PLA
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NHI ECONOMIC ANALYSIS OF CANDIDATE
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MARKET VIABILITY OF NUCLEAR HYDROGE
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POSSIBILITY OF ACTIVE CARBON RECYCL
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NUCLEAR SAFETY AND REGULATORY CONSI
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TRANSIENT MODELLING OF S-I CYCLE TH
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PROPOSED CHEMICAL PLANT INITIATED A
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CONCEPTUAL DESIGN OF THE HTTR-IS NU
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USE OF PSA FOR DESIGN OF EMERGENCY
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HEAT PUMP CYCLE BY HYDROGEN-ABSORBI
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HEAT EXCHANGER TEMPERATURE RESPONSE
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ALTERNATE VHTR/HTE INTERFACE FOR MI
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POSTER SESSION CONTRIBUTIONS Poster
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ACTIVITIES OF NUCLEAR RESEARCH INST
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ACTIVITIES OF NUCLEAR RESEARCH INST
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A URANIUM THERMOCHEMICAL CYCLE FOR
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A URANIUM THERMOCHEMICAL CYCLE FOR
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MEETING ORGANISATION Annex 1: Meeti
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LIST OF PARTICIPANTS REYTIER, Magal
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LIST OF PARTICIPANTS BROWN, Nichola
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LIST OF PARTICIPANTS SINK, Carl US
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