Status of the ITER Divertor IVT procurement

被引：5

作者：

Gavila, Pierre ^{[1
]}

Amoros, Jordi ^{[1
]}

Grattarola, Marco ^{[2
]}

Palermo, Massimiliano ^{[2
]}

Visca, Eliseo ^{[3
]}

Roccella, Selanna ^{[3
]}

Kuznetcov, Vladimir ^{[4
]}

Volodin, Andrew ^{[4
]}

Malyshev, Aleksei ^{[4
]}

Riccardi, Bruno ^{[1
]}

Durocher, Alain ^{[5
]}

Fedosov, Andrey ^{[5
]}

机构：

[1] F4E, C Josep Pla 2,Edificio B3, Barcelona 08019, Spain

[2] Ansaldo Nucl, Cso Perrone 25, I-16152 Genoa, Italy

[3] ENEA CR Frascati, Via E Fermi 45, I-00044 Frascati, Italy

[4] DV Efremov Sci Res Inst Electrophys Apparatus, 3 Doroga Metallostroy, St Petersburg 196641, Russia

[5] ITER Org, Route Vinon Sur Verdon,CS 90 046, F-13067 St Paul Les Durance, France

来源：

FUSION ENGINEERING AND DESIGN | 2020年 / 160卷

关键词：

ITER; Divertor; Inner vertical target; Hot radial pressing; NDT; TUNGSTEN MONOBLOCK;

D O I：

10.1016/j.fusengdes.2020.111973

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 Ansaldo Nucleare (ANN) Prototype manufacturing is under completion. The stainless steel support structure was manufactured by Walter Tosto (Italy) and the Plasma Facing Units (PFUs) were manufactured by ENEA (Italy) by diffusion bonding between the CuCrZr pipe and the W monoblocks equipped with a pure Cu compliance layer (Hot Radial Pressing, HRP). This paper presents some of the learnings of the Inner Vertical Target (IVT) Prototype manufacturing and provides the main results of the dimensional control tests. The outcomes of the PFUs High Heat Flux (HHF) testing performed in the ITER Divertor Test Facility (IDTF) in Efremov institute, Saint Petersburg (Russia) are presented as well.

引用

页数：6

共 50 条

[31] Characteristics of divertor detachment for ITER conditions
Kukushkin, A. S.
Pacher, H. D.
Pitts, R. A.
[J]. JOURNAL OF NUCLEAR MATERIALS, 2015, 463 : 586 - 590
[32] Divertor issues on ITER and extrapolation to reactors
Kukushkin, AS
Pacher, HD
Federici, G
Janeschitz, G
Loarte, A
Pacher, GW
[J]. FUSION ENGINEERING AND DESIGN, 2003, 65 (03) : 355 - 366
[33] Divertor design and its integration into ITER
Janeschitz, G
Antipenkov, A
Federici, G
Ibbott, C
Kukushkin, A
Ladd, P
Martin, E
Tivey, R
[J]. NUCLEAR FUSION, 2002, 42 (01) : 14 - 20
[34] Control pathway for an advanced divertor on ITER
Wai, J. T.
Vail, P. J.
Kolemen, E.
[J]. FUSION ENGINEERING AND DESIGN, 2020, 159 (159)
[35] JET DIVERTOR RESEARCH IN SUPPORT OF ITER
WATKINS, ML
[J]. PLASMA PHYSICS AND CONTROLLED FUSION, 1994, 36 (12B) : B241 - B251
[36] Gallium cooled ITER divertor cassette
Muraviev, EV
Romanov, PV
Petrov, VS
Shpansky, Y
Klischenko, AV
Khripunov, VI
[J]. PLASMA DEVICES AND OPERATIONS, 1998, 6 (1-3): : 73 - 82
[37] Power Balance in the ITER Plasma and Divertor
Post, D. E.
Braams, B.
Mandrekas, J.
Stacey, W.
[J]. Contributions to Plasma Physics, 36 (2-3):
[38] Power balance in the ITER plasma and divertor
Post, DE
Braams, B
Mandrekas, J
Stacey, W
Putvinskaya, N
[J]. CONTRIBUTIONS TO PLASMA PHYSICS, 1996, 36 (2-3) : 240 - 244
[39] Development of divertor cassette transporters for ITER
Takeda, N
Akou, K
Kakudate, S
Takiguchi, Y
Tada, E
Burgess, T
Shibanuma, K
Haange, R
[J]. 17TH IEEE/NPSS SYMPOSIUM ON FUSION ENGINEERING, VOLS 1 AND 2, 1998, : 925 - 928
[40] REGIMES WITH RECOMBINING PLASMA IN THE ITER DIVERTOR
KRASHENINNIKOV, SI
SIGMAR, D
SOBOLEVA, TK
KUKUSHKIN, AB
BATISCHEV, OV
SIGOV, YS
[J]. CONTRIBUTIONS TO PLASMA PHYSICS, 1994, 34 (2-3) : 442 - 447

← 1 2 3 4 5 →