Tritium pumps for ITER roughing system

被引:10
|
作者
Antipenkov, A
Day, C
Lässer, R
Mack, A
Wagner, R
机构
[1] Forschungszentrum Karlsruhe, Inst Tech Phys, D-76021 Karlsruhe, Germany
[2] Forschungszentrum Karlsruhe, Tritium Lab, D-76021 Karlsruhe, Germany
[3] European Fus Dev Agreement, Garching Close Support Unit, D-85748 Garching, Germany
来源
FUSION SCIENCE AND TECHNOLOGY | 2005年 / 48卷 / 01期
关键词
D O I
10.13182/FST48-47
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
The ITER roughing system provides for both the initial pump-down of the vessel itself and the regular Pump-out of the batch-regenerating cryopumps. This system must have a large pumping speed and cope with the radioactive gas tritium at the same time. The present paper shall highlight the results of the ITER roughing train optimization, discuss the modification of a Roots pump for tritium, and present the results of a ferrofluidic seal test and the first tests of a tailor-made tritium-proof Roots pump with inactive gases.
引用
收藏
页码:47 / 50
页数:4
相关论文
共 50 条
  • [41] Tritium inventory assessment for ITER using TRIMO
    Cristescu, IR
    Cristescu, I
    Murdoch, D
    Dörr, L
    Glugla, M
    FUSION ENGINEERING AND DESIGN, 2006, 81 (1-7) : 763 - 769
  • [42] Iter dynamic tritium inventory modeling code
    Cristescu, IR
    Dörr, L
    Busigin, A
    Murdoch, D
    FUSION SCIENCE AND TECHNOLOGY, 2005, 48 (01) : 343 - 348
  • [43] In-vessel tritium retention and removal in ITER
    Federici, G.
    Anderl, R.A.
    Andrew, P.
    Brooks, J.N.
    Causey, R.A.
    Coad, J.P.
    Cowgill, D.
    Doerner, R.P.
    Haasz, A.A.
    Janeschitz, G.
    Jacob, W.
    Longhurst, G.R.
    Nygren, R.
    Peacock, A.
    Pick, M.A.
    Philipps, V.
    Roth, J.
    Skinner, C.H.
    Wampler, W.R.
    Journal of Nuclear Materials, 1999, 266 : 14 - 29
  • [44] STATUS OF ITER TRITIUM PLANT-DESIGN
    HAANGE, R
    YOSHIDA, H
    KVETON, O
    KOONCE, J
    HORIKIRI, H
    FUSION TECHNOLOGY, 1995, 28 (03): : 491 - 495
  • [45] The tritium fuel cycle of ITER-FEAT
    Glugla, M
    Busigin, A
    Dörr, L
    Haange, R
    Hayashi, T
    Kveton, O
    Lässer, R
    Murdoch, DK
    Nishi, M
    Penzhorn, RD
    Yoshida, H
    FUSION ENGINEERING AND DESIGN, 2001, 58-59 (58-59) : 349 - 353
  • [46] Tritium control techniques in ITER by ammonia injection
    Tabares, F. L.
    Ferreira, J. A.
    Ramos, A.
    Alegre, D.
    van Rooij, G.
    Westerhout, J.
    Al, R.
    Rapp, J.
    Drenik, A.
    Mozetic, M.
    JOURNAL OF NUCLEAR MATERIALS, 2011, 415 (01) : S793 - S796
  • [47] TRITIUM MODELING FOR ITER TEST BLANKET MODULE
    Zucchetti, M.
    Nicolotti, I.
    Ying, A.
    Abdou, M.
    FUSION SCIENCE AND TECHNOLOGY, 2015, 68 (03) : 644 - 647
  • [48] In-vessel tritium retention and removal in ITER
    Federici, G
    Anderl, RA
    Andrew, P
    Brooks, JN
    Causey, RA
    Coad, JP
    Cowgill, D
    Doerner, RP
    Haasz, AA
    Janeschitz, G
    Jacob, W
    Longhurst, GR
    Nygren, R
    Peacock, A
    Pick, MA
    Philipps, V
    Roth, J
    Skinner, CH
    Wampler, WR
    JOURNAL OF NUCLEAR MATERIALS, 1999, 266 : 14 - 29
  • [49] Korea's progress on the ITER tritium systems
    Chung, Hongsuk
    Shim, Myunghwa
    Yoshida, Hiroshi
    Jin, Haksu
    Lee, Jongkuk
    Ahn, Do-Hee
    Kim, Kyung-Ku
    Song, Kyu-Min
    Kim, Duk Jin
    Chang, Min Ho
    Kang, Hyun-Goo
    Yun, Sei-Hun
    Cho, Seungyon
    FUSION ENGINEERING AND DESIGN, 2009, 84 (2-6) : 599 - 603
  • [50] Impact assessment of tritium in an ITER hot cell
    Kim, Sung-Kyun
    Ji, Young-Yong
    Lee, Kune-Woo
    Moon, Jei-Kwon
    Na, Byung-Chan
    Song, Ohseop
    ANNALS OF NUCLEAR ENERGY, 2012, 42 : 63 - 70
12345