Application of proton-conducting ceramics and polymer permeable membranes for gaseous tritium recovery

被引:21
|
作者
Asakura, Y
Sugiyama, T
Kawano, T
Uda, T
Tanaka, M
Tsuji, N
Katahira, K
Iwahara, H
机构
[1] Natl Inst Fus Sci, Gifu 5095292, Japan
[2] Nippon Kucho Serv Co Ltd, Meitou Ku, Nagoya, Aichi 4650042, Japan
[3] TYK Co Ltd, Gifu 5078607, Japan
[4] Nagoya Univ, Moriyama Ku, Nagoya, Aichi 4648607, Japan
来源
JOURNAL OF NUCLEAR SCIENCE AND TECHNOLOGY | 2004年 / 41卷 / 08期
关键词
tritium; tritium separation; tritium monitoring; proton-conducting ceramic; hydrogen pump; membrane filter; membrane dehumidifier; tritium recovery system; Large Helical Device;
D O I
10.3327/jnst.41.863
中图分类号
TL [原子能技术]; O571 [原子核物理学];
学科分类号
0827 ; 082701 ;
摘要
In order to carry out deuterium plasma experiments on the Large Helical Device (LHD), the National Institute for Fusion Science (NIFS) is planning to install a system for the recovery of tritium from exhaust gas and effluent liquid. As well as adopting proven conventional tritium recovery systems, NIFS is planning to apply the latest technologies such as proton-conducting ceramics and membrane-type dehumidifiers in an overall strategy to ensure minimal risk in the tritium recovery process. Application of these new technologies to the tritium recovery system for the LHD deuterium plasma experiment is evaluated quantitatively using recent experimental data.
引用
收藏
页码:863 / 870
页数:8
相关论文
共 50 条
  • [31] Complex impedance studies of S-SEBS block polymer proton-conducting membranes
    Edmondson, CA
    Fontanella, JJ
    Chung, SH
    Greenbaum, SG
    Wnek, GE
    ELECTROCHIMICA ACTA, 2001, 46 (10-11) : 1623 - 1628
  • [32] Effects of γ-ray and neutron irradiation on electrical characteristic of proton-conducting polymer electrolyte membranes
    Adachi, T
    Nagata, S
    Ohtsu, N
    Tsuchiya, B
    Toh, K
    Morishita, N
    Yamauchi, M
    Nishitani, N
    Shikama, T
    JOURNAL OF NUCLEAR MATERIALS, 2004, 329 : 1499 - 1502
  • [33] Construction of unimpeded proton-conducting pathways in solution-processed nanoporous polymer membranes
    Tang, Xiaohui
    Ma, Nattapol
    Xu, Hong
    Zhang, Huanhuan
    Zhang, Qinglei
    Cai, Linkun
    Otake, Ken-ichi
    Yin, Panchao
    Kitagawa, Susumu
    Horike, Satoshi
    Gu, Cheng
    MATERIALS HORIZONS, 2021, 8 (11) : 3088 - 3095
  • [34] Proton-conducting membranes based on protic ionic liquids
    Fernicola, Alessandra
    Panero, Stefania
    Scrosati, Bruno
    JOURNAL OF POWER SOURCES, 2008, 178 (02) : 591 - 595
  • [35] PROTON-CONDUCTING MEMBRANES ON THE BASE OF POLYNAPHTHALENE IMIDOSULFONIC ACIDS
    SOLOMIN, VA
    LYAKH, YN
    ZHUBANOV, BA
    VYSOKOMOLEKULYARNYE SOEDINENIYA SERIYA A, 1992, 34 (03): : 139 - 142
  • [36] Proton-conducting membranes for PEM fuel cells Preface
    Di Vona, M. L.
    Knauth, P.
    Alberti, G.
    JOURNAL OF POWER SOURCES, 2010, 195 (23) : 7719 - 7719
  • [37] The application of acrylic monomers with acidic groups to the synthesis of proton-conducting polymer gels
    Zukowska, G
    Williams, J
    Stevens, JR
    Jeffrey, KR
    Lewera, A
    Kulesza, PJ
    SOLID STATE IONICS, 2004, 167 (1-2) : 123 - 130
  • [38] Sulfophenylation of polysulfones for proton-conducting fuel cell membranes
    Lafitte, B
    Karlsson, LE
    Jannasch, P
    MACROMOLECULAR RAPID COMMUNICATIONS, 2002, 23 (15) : 896 - 900
  • [39] High proton-conducting monolithic phosphosilicate glass membranes
    Li, Haibin
    Jin, Dongliang
    Kong, Xiangyang
    Tu, Hengyong
    Yu, Qingchun
    Jiang, Fengjing
    MICROPOROUS AND MESOPOROUS MATERIALS, 2011, 138 (1-3) : 63 - 67
  • [40] Evaluation of methanol crossover in proton-conducting polyphosphazene membranes
    Fedkin, MV
    Zhou, XY
    Hofmann, MA
    Chalkova, E
    Weston, JA
    Allcock, HR
    Lvov, SN
    MATERIALS LETTERS, 2002, 52 (03) : 192 - 196
12345