ITER Central Solenoid Insert Test Results

Nicolai Martovetsky; Takaaki Isono; Denis Bessette; Yoshikazu Takahashi; Yoshihiko Nunoya; Yoshihiro Nabara; Hidemasa Ozeki; Katsumi Kawano; Toru Saito; Tomone Suwa; Kiyoshi Okuno; Arnaud Devred; Florent Gauthier; Neil Mitchell; Roberto Zanino; Laura Savoldi; Roberto Bonifetto; Marco Breschi; Daniel Ciazynski; Wayne Reiersen; Alexandre Smirnov; Andrei Khodak; Pierluigi Bruzzone; Igor Rodin; Vladimir Tronza; Alexandre Torre; Sylvie Nicollet; Louis Zani; Alexandre Louzguiti; Jean Luc Duchateau

doi:10.1109/TASC.2016.2517322

ITER Central Solenoid Insert Test Results

Nicolai Martovetsky, Takaaki Isono, Denis Bessette, Yoshikazu Takahashi, Yoshihiko Nunoya, Yoshihiro Nabara, Hidemasa Ozeki, Katsumi Kawano, Toru Saito, Tomone Suwa, Kiyoshi Okuno, Arnaud Devred, Florent Gauthier, Neil Mitchell, Roberto Zanino, Laura Savoldi, Roberto Bonifetto, Marco Breschi, Daniel Ciazynski, Wayne ReiersenAlexandre Smirnov, Andrei Khodak, Pierluigi Bruzzone, Igor Rodin, Vladimir Tronza, Alexandre Torre, Sylvie Nicollet, Louis Zani, Alexandre Louzguiti, Jean Luc Duchateau

PPPL Engineering

Research output: Contribution to journal › Article › peer-review

37 Scopus citations

Abstract

The ITER central solenoid (CS) is a highly stressed magnet that must provide 30 000 plasma cycles under the ITER prescribed maximum operating conditions. To verify the performance of the ITER CS conductor in conditions close to those for the ITER CS, the CS insert was built under a USA-Japan collaboration. The insert was tested in the aperture of the CSMC facility in Naka, Japan, during the first half of 2015. A magnetic field of up to 13 T and a transport current of up to 60 kA provided a wide range of parameters to characterize the conductor. The CS insert has been tested under direct and reverse charges, which allowed a wide range of strain variation and provided valuable data for characterization of the CS conductor performance at different strain levels. The CS insert test program had several important goals as follows. 1) Measure the temperature margin of the CS conductor at the relevant ITER CS operational conditions. 2) Study the effects of electromagnetic forces and strain in the cable on the CS conductor performance. 3) Study the effects of the warmup and cooldown cycles on the CS conductor performance. 4) Compare the conductor performance in the CS insert with the performance of the CS conductor in a straight hairpin configuration (hoop strain free) tested in the SULTAN facility. 5) Measure the maximum temperature rise of the cable as a result of quench. The main results of the CS insert testing are presented and discussed.

Original language	English (US)
Article number	7384711
Journal	IEEE Transactions on Applied Superconductivity
Volume	26
Issue number	4
DOIs	https://doi.org/10.1109/TASC.2016.2517322
State	Published - Jun 2016

All Science Journal Classification (ASJC) codes

Electronic, Optical and Magnetic Materials
Condensed Matter Physics
Electrical and Electronic Engineering

Keywords

loss measurement
Superconducting magnets
voltage measurement

Access to Document

10.1109/TASC.2016.2517322

Cite this

Martovetsky, N., Isono, T., Bessette, D., Takahashi, Y., Nunoya, Y., Nabara, Y., Ozeki, H., Kawano, K., Saito, T., Suwa, T., Okuno, K., Devred, A., Gauthier, F., Mitchell, N., Zanino, R., Savoldi, L., Bonifetto, R., Breschi, M., Ciazynski, D., ... Duchateau, J. L. (2016). ITER Central Solenoid Insert Test Results. IEEE Transactions on Applied Superconductivity, 26(4), Article 7384711. https://doi.org/10.1109/TASC.2016.2517322

@article{dbbb91e61e4949b39d81d17720544acd,

title = "ITER Central Solenoid Insert Test Results",

abstract = "The ITER central solenoid (CS) is a highly stressed magnet that must provide 30 000 plasma cycles under the ITER prescribed maximum operating conditions. To verify the performance of the ITER CS conductor in conditions close to those for the ITER CS, the CS insert was built under a USA-Japan collaboration. The insert was tested in the aperture of the CSMC facility in Naka, Japan, during the first half of 2015. A magnetic field of up to 13 T and a transport current of up to 60 kA provided a wide range of parameters to characterize the conductor. The CS insert has been tested under direct and reverse charges, which allowed a wide range of strain variation and provided valuable data for characterization of the CS conductor performance at different strain levels. The CS insert test program had several important goals as follows. 1) Measure the temperature margin of the CS conductor at the relevant ITER CS operational conditions. 2) Study the effects of electromagnetic forces and strain in the cable on the CS conductor performance. 3) Study the effects of the warmup and cooldown cycles on the CS conductor performance. 4) Compare the conductor performance in the CS insert with the performance of the CS conductor in a straight hairpin configuration (hoop strain free) tested in the SULTAN facility. 5) Measure the maximum temperature rise of the cable as a result of quench. The main results of the CS insert testing are presented and discussed.",

keywords = "loss measurement, Superconducting magnets, voltage measurement",

author = "Nicolai Martovetsky and Takaaki Isono and Denis Bessette and Yoshikazu Takahashi and Yoshihiko Nunoya and Yoshihiro Nabara and Hidemasa Ozeki and Katsumi Kawano and Toru Saito and Tomone Suwa and Kiyoshi Okuno and Arnaud Devred and Florent Gauthier and Neil Mitchell and Roberto Zanino and Laura Savoldi and Roberto Bonifetto and Marco Breschi and Daniel Ciazynski and Wayne Reiersen and Alexandre Smirnov and Andrei Khodak and Pierluigi Bruzzone and Igor Rodin and Vladimir Tronza and Alexandre Torre and Sylvie Nicollet and Louis Zani and Alexandre Louzguiti and Duchateau, \{Jean Luc\}",

note = "Publisher Copyright: {\textcopyright} 2016 IEEE.",

year = "2016",

month = jun,

doi = "10.1109/TASC.2016.2517322",

language = "English (US)",

volume = "26",

journal = "IEEE Transactions on Applied Superconductivity",

issn = "1051-8223",

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Martovetsky, N, Isono, T, Bessette, D, Takahashi, Y, Nunoya, Y, Nabara, Y, Ozeki, H, Kawano, K, Saito, T, Suwa, T, Okuno, K, Devred, A, Gauthier, F, Mitchell, N, Zanino, R, Savoldi, L, Bonifetto, R, Breschi, M, Ciazynski, D, Reiersen, W, Smirnov, A, Khodak, A, Bruzzone, P, Rodin, I, Tronza, V, Torre, A, Nicollet, S, Zani, L, Louzguiti, A & Duchateau, JL 2016, 'ITER Central Solenoid Insert Test Results', IEEE Transactions on Applied Superconductivity, vol. 26, no. 4, 7384711. https://doi.org/10.1109/TASC.2016.2517322

TY - JOUR

T1 - ITER Central Solenoid Insert Test Results

AU - Martovetsky, Nicolai

AU - Isono, Takaaki

AU - Bessette, Denis

AU - Takahashi, Yoshikazu

AU - Nunoya, Yoshihiko

AU - Nabara, Yoshihiro

AU - Ozeki, Hidemasa

AU - Kawano, Katsumi

AU - Saito, Toru

AU - Suwa, Tomone

AU - Okuno, Kiyoshi

AU - Devred, Arnaud

AU - Gauthier, Florent

AU - Mitchell, Neil

AU - Zanino, Roberto

AU - Savoldi, Laura

AU - Bonifetto, Roberto

AU - Breschi, Marco

AU - Ciazynski, Daniel

AU - Reiersen, Wayne

AU - Smirnov, Alexandre

AU - Khodak, Andrei

AU - Bruzzone, Pierluigi

AU - Rodin, Igor

AU - Tronza, Vladimir

AU - Torre, Alexandre

AU - Nicollet, Sylvie

AU - Zani, Louis

AU - Louzguiti, Alexandre

AU - Duchateau, Jean Luc

PY - 2016/6

Y1 - 2016/6

N2 - The ITER central solenoid (CS) is a highly stressed magnet that must provide 30 000 plasma cycles under the ITER prescribed maximum operating conditions. To verify the performance of the ITER CS conductor in conditions close to those for the ITER CS, the CS insert was built under a USA-Japan collaboration. The insert was tested in the aperture of the CSMC facility in Naka, Japan, during the first half of 2015. A magnetic field of up to 13 T and a transport current of up to 60 kA provided a wide range of parameters to characterize the conductor. The CS insert has been tested under direct and reverse charges, which allowed a wide range of strain variation and provided valuable data for characterization of the CS conductor performance at different strain levels. The CS insert test program had several important goals as follows. 1) Measure the temperature margin of the CS conductor at the relevant ITER CS operational conditions. 2) Study the effects of electromagnetic forces and strain in the cable on the CS conductor performance. 3) Study the effects of the warmup and cooldown cycles on the CS conductor performance. 4) Compare the conductor performance in the CS insert with the performance of the CS conductor in a straight hairpin configuration (hoop strain free) tested in the SULTAN facility. 5) Measure the maximum temperature rise of the cable as a result of quench. The main results of the CS insert testing are presented and discussed.

AB - The ITER central solenoid (CS) is a highly stressed magnet that must provide 30 000 plasma cycles under the ITER prescribed maximum operating conditions. To verify the performance of the ITER CS conductor in conditions close to those for the ITER CS, the CS insert was built under a USA-Japan collaboration. The insert was tested in the aperture of the CSMC facility in Naka, Japan, during the first half of 2015. A magnetic field of up to 13 T and a transport current of up to 60 kA provided a wide range of parameters to characterize the conductor. The CS insert has been tested under direct and reverse charges, which allowed a wide range of strain variation and provided valuable data for characterization of the CS conductor performance at different strain levels. The CS insert test program had several important goals as follows. 1) Measure the temperature margin of the CS conductor at the relevant ITER CS operational conditions. 2) Study the effects of electromagnetic forces and strain in the cable on the CS conductor performance. 3) Study the effects of the warmup and cooldown cycles on the CS conductor performance. 4) Compare the conductor performance in the CS insert with the performance of the CS conductor in a straight hairpin configuration (hoop strain free) tested in the SULTAN facility. 5) Measure the maximum temperature rise of the cable as a result of quench. The main results of the CS insert testing are presented and discussed.

KW - loss measurement

KW - Superconducting magnets

KW - voltage measurement

UR - https://www.scopus.com/pages/publications/84962449918

UR - https://www.scopus.com/inward/citedby.url?scp=84962449918&partnerID=8YFLogxK

U2 - 10.1109/TASC.2016.2517322

DO - 10.1109/TASC.2016.2517322

M3 - Article

AN - SCOPUS:84962449918

SN - 1051-8223

VL - 26

JO - IEEE Transactions on Applied Superconductivity

JF - IEEE Transactions on Applied Superconductivity

IS - 4

M1 - 7384711

ER -

ITER Central Solenoid Insert Test Results

Abstract

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Keywords

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