Design of ITER vacuum vessel in-wall shielding

被引：9

作者：

Wang, X. ^{[1
]}

Ioki, K. ^{[1
]}

Morimoto, M. ^{[2
]}

Choi, C. H. ^{[1
]}

Utin, Y. ^{[1
]}

Sborchia, C. ^{[1
]}

TaiLhardat, O. ^{[3
]}

Mille, B. ^{[1
]}

Terasawa, A. ^{[1
]}

Gribov, Y. ^{[1
]}

Barabash, V. ^{[1
]}

Polunovskiy, E. ^{[1
]}

Dani, S. ^{[1
]}

Pathak, H. ^{[4
]}

Raval, J. ^{[4
]}

Liu, S. ^{[5
]}

Lu, M. ^{[5
]}

Du, S. ^{[5
]}

机构：

[1] ITER Org, F-13115 St Paul Les Durance, France

[2] Mitsubishi Heavy Ind Co Ltd, Hyogo Ku, Kobe, Hyogo, Japan

[3] ZAC ST MARTIN, Assyst EOS, F-84120 Pertuis, France

[4] ITER India, Inst Plasma Res, Gandhinagar 382025, India

[5] Chinese Acad Sci, Inst Plasma Phys, Hefei, Peoples R China

来源：

FUSION ENGINEERING AND DESIGN | 2014年 / 89卷 / 7-8期

关键词：

ITER; Vacuum vessel; In-wall shielding; Design;

D O I：

10.1016/j.fusengdes.2014.03.026

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 vacuum vessel is a torus-shaped, double wall structure. The space between the double walls of the VV is filled with in-wall shielding (IWS) and cooling water. The main purpose of the in-wall shielding is to provide neutron shielding together with the blanket and VV shells and water during ITER plasma operation and to reduce the ripple of the Toroidal magnetic field. Based on ITER vacuum vessel structure and related requirements, in-wall shielding are designed as about 8900 individual blocks with different sizes and several different materials distributed over nine vessel sectors and nine field joints of vessel sectors. This paper presents the design of the IWS, considering loads, structural stresses and assembly method, and also shows neutron shielding effect and TF ripple reduced by the IWS. (C) 2014 Elsevier B.V. All rights reserved.

引用

页码：1814 / 1819

页数：6

共 50 条

[31] FW/Blanket and vacuum vessel for RTO/RC ITER
Ioki, K
Barabash, V
Cardella, A
Elio, F
Iida, H
Johnson, G
Kalinin, G
Miki, N
Onozuka, M
Sannazzaro, G
Utin, Y
Yamada, M
FUSION ENGINEERING AND DESIGN, 2000, 49-50 : 467 - 475
[32] Structural and fracture mechanics analysis of ITER vacuum vessel
Iguchi, Masahide
Saito, Masakatsu
FUSION ENGINEERING AND DESIGN, 2007, 82 (15-24) : 2029 - 2034
[33] Design progress of the vacuum vessel sectors and ports towards the ITER construction
Utin, Yu.
Loki, K.
Bachmann, Ch.
Barabash, V.
Federici, G.
Jones, L.
Kim, B. C.
Kuzmin, E.
Morimoto, M.
Nakahira, M.
Sannazzaro, G.
FUSION ENGINEERING AND DESIGN, 2008, 83 (10-12) : 1565 - 1570
[34] Technical code issues of ITER vacuum vessel and their resolutions
Nakahira, M. (nakahirm@fusion.naka.jaeri.go.jp), 1600, Atomic Energy Society of Japan (40): : 687 - 694
[35] Design and thermal/hydraulic characteristics of the ITER-FEAT vacuum vessel
Onozuka, M
Ioki, K
Sannazzaro, G
Utin, Y
Yoshimura, H
FUSION ENGINEERING AND DESIGN, 2001, 58-59 : 857 - 861
[36] Computational models for electromagnetic transients in ITER vacuum vessel, cryostat and thermal shield
Alekseev, A.
Arslanova, D.
Belov, A.
Belyakov, V.
Gapionok, E.
Gornikel, I.
Gribov, Y.
Ioki, K.
Kukhtin, V.
Lamzin, E.
Sugihara, M.
Sychevsky, S.
Terasawa, A.
Utin, Y.
FUSION ENGINEERING AND DESIGN, 2013, 88 (9-10) : 1904 - 1907
[37] Design of the European DEMO vacuum vessel inboard wall
Mozzillo, Rocco
Bachmann, Christian
Aiello, Giacomo
Marzullo, Domenico
FUSION ENGINEERING AND DESIGN, 2020, 160
[38] Analyses of the ITER vacuum vessel with the use of a new modelling technique
Rozov, V
D'Agata, E
Ioki, K
Morimoto, M
Sannazzaro, G
FUSION ENGINEERING AND DESIGN, 2005, 75-79 : 547 - 552
[39] Towards advanced welding methods for the ITER vacuum vessel sectors
Jones, LP
Aubert, P
Avilov, V
Coste, F
Daenner, WF
Jokinen, T
Nightingale, KR
Wykes, M
FUSION ENGINEERING AND DESIGN, 2003, 69 (1-4) : 215 - 220
[40] Three Dimensional Tolerance Investigations on Assembly of ITER Vacuum Vessel
Reich, J.
Cordier, J-J.
Macklin, B.
Giraud, B.
Wilson, D.
Levesy, B.
Gokhan, G.
2009 23RD IEEE/NPSS SYMPOSIUM ON FUSION ENGINEERING, 2009, : 170 - +

← 1 2 3 4 5 →