Status of the ITER electron cyclotron heating and current drive system

Caroline Darbos; Ferran Albajar; Tullio Bonicelli; Giuseppe Carannante; Mario Cavinato; Fabio Cismondi; Grigory Denisov; Daniela Farina; Mario Gagliardi; Franco Gandini; Thibault Gassmann; Timothy Goodman; Gregory Hanson; Mark A. Henderson; Ken Kajiwara; Karen McElhaney; Risto Nousiainen; Yasuhisa Oda; Toshimichi Omori; Alexander Oustinov; Darshankumar Parmar; Vladimir L. Popov; Dharmesh Purohit; Shambhu Laxmikanth Rao; David Rasmussen; Vipal Rathod; Dennis M.S. Ronden; Gabriella Saibene; Keishi Sakamoto; Filippo Sartori; Theo Scherer; Narinder Pal Singh; Dirk Strauß; Koji Takahashi

doi:10.1007/s10762-015-0211-3

Status of the ITER electron cyclotron heating and current drive system

Caroline Darbos
, Ferran Albajar
, Tullio Bonicelli
, Giuseppe Carannante
, Mario Cavinato
, Fabio Cismondi
, Grigory Denisov
, Daniela Farina
, Mario Gagliardi
, Franco Gandini
, Thibault Gassmann
, Timothy Goodman
, Gregory Hanson
, Mark A. Henderson
, Ken Kajiwara
, Karen McElhaney
, Risto Nousiainen
, Yasuhisa Oda
, Toshimichi Omori
, Alexander Oustinov

Darshankumar Parmar, Vladimir L. Popov, Dharmesh Purohit, Shambhu Laxmikanth Rao, David Rasmussen, Vipal Rathod, Dennis M.S. Ronden, Gabriella Saibene, Keishi Sakamoto, Filippo Sartori, Theo Scherer, Narinder Pal Singh, Dirk Strauß, Koji Takahashi

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

44 Scopus citations

Abstract

The electron cyclotron (EC) heating and current drive (H&CD) system developed for the ITER is made of 12 sets of high-voltage power supplies feeding 24 gyrotrons connected through 24 transmission lines (TL), to five launchers, four located in upper ports and one at the equatorial level. Nearly all procurements are in-kind, following general ITER philosophy, and will come from Europe, India, Japan, Russia and the USA. The full system is designed to couple to the plasma 20 MW among the 24 MW generated power, at the frequency of 170 GHz, for various physics applications such as plasma start-up, central H&CD and magnetohydrodynamic (MHD) activity control. The design takes present day technology and extends toward high-power continuous operation, which represents a large step forward as compared to the present state of the art. The ITER EC system will be a stepping stone to future EC systems for DEMO and beyond. The development of the EC system is facing significant challenges, which includes not only an advanced microwave system but also compliance with stringent requirements associated with nuclear safety as ITER became the first fusion device licensed as basic nuclear installations as of 9 November 2012. Since the conceptual design of the EC system was established in 2007, the EC system has progressed to a preliminary design stage in 2012 and is now moving forward toward a final design.

Original language	English
Pages (from-to)	4-20
Number of pages	17
Journal	Journal of Infrared, Millimeter, and Terahertz Waves
Volume	37
Issue number	1
DOIs	https://doi.org/10.1007/s10762-015-0211-3
State	Published - Jan 2016
Externally published	Yes

Keywords

ITER electron cyclotron heating current drive

Access to Document

10.1007/s10762-015-0211-3

Cite this

Darbos, C., Albajar, F., Bonicelli, T., Carannante, G., Cavinato, M., Cismondi, F., Denisov, G., Farina, D., Gagliardi, M., Gandini, F., Gassmann, T., Goodman, T., Hanson, G., Henderson, M. A., Kajiwara, K., McElhaney, K., Nousiainen, R., Oda, Y., Omori, T., ... Takahashi, K. (2016). Status of the ITER electron cyclotron heating and current drive system. Journal of Infrared, Millimeter, and Terahertz Waves, 37(1), 4-20. https://doi.org/10.1007/s10762-015-0211-3

@article{7d9559713f364e14a85546979d70e199,

title = "Status of the ITER electron cyclotron heating and current drive system",

abstract = "The electron cyclotron (EC) heating and current drive (H\&CD) system developed for the ITER is made of 12 sets of high-voltage power supplies feeding 24 gyrotrons connected through 24 transmission lines (TL), to five launchers, four located in upper ports and one at the equatorial level. Nearly all procurements are in-kind, following general ITER philosophy, and will come from Europe, India, Japan, Russia and the USA. The full system is designed to couple to the plasma 20 MW among the 24 MW generated power, at the frequency of 170 GHz, for various physics applications such as plasma start-up, central H\&CD and magnetohydrodynamic (MHD) activity control. The design takes present day technology and extends toward high-power continuous operation, which represents a large step forward as compared to the present state of the art. The ITER EC system will be a stepping stone to future EC systems for DEMO and beyond. The development of the EC system is facing significant challenges, which includes not only an advanced microwave system but also compliance with stringent requirements associated with nuclear safety as ITER became the first fusion device licensed as basic nuclear installations as of 9 November 2012. Since the conceptual design of the EC system was established in 2007, the EC system has progressed to a preliminary design stage in 2012 and is now moving forward toward a final design.",

keywords = "ITER electron cyclotron heating current drive",

author = "Caroline Darbos and Ferran Albajar and Tullio Bonicelli and Giuseppe Carannante and Mario Cavinato and Fabio Cismondi and Grigory Denisov and Daniela Farina and Mario Gagliardi and Franco Gandini and Thibault Gassmann and Timothy Goodman and Gregory Hanson and Henderson, \{Mark A.\} and Ken Kajiwara and Karen McElhaney and Risto Nousiainen and Yasuhisa Oda and Toshimichi Omori and Alexander Oustinov and Darshankumar Parmar and Popov, \{Vladimir L.\} and Dharmesh Purohit and Rao, \{Shambhu Laxmikanth\} and David Rasmussen and Vipal Rathod and Ronden, \{Dennis M.S.\} and Gabriella Saibene and Keishi Sakamoto and Filippo Sartori and Theo Scherer and Singh, \{Narinder Pal\} and Dirk Strau{\ss} and Koji Takahashi",

note = "Publisher Copyright: {\textcopyright} Springer Science+Business Media New York 2015.",

year = "2016",

month = jan,

doi = "10.1007/s10762-015-0211-3",

language = "English",

volume = "37",

pages = "4--20",

journal = "Journal of Infrared, Millimeter, and Terahertz Waves",

issn = "1866-6892",

publisher = "Springer",

number = "1",

}

Darbos, C, Albajar, F, Bonicelli, T, Carannante, G, Cavinato, M, Cismondi, F, Denisov, G, Farina, D, Gagliardi, M, Gandini, F, Gassmann, T, Goodman, T, Hanson, G, Henderson, MA, Kajiwara, K, McElhaney, K, Nousiainen, R, Oda, Y, Omori, T, Oustinov, A, Parmar, D, Popov, VL, Purohit, D, Rao, SL, Rasmussen, D, Rathod, V, Ronden, DMS, Saibene, G, Sakamoto, K, Sartori, F, Scherer, T, Singh, NP, Strauß, D & Takahashi, K 2016, 'Status of the ITER electron cyclotron heating and current drive system', Journal of Infrared, Millimeter, and Terahertz Waves, vol. 37, no. 1, pp. 4-20. https://doi.org/10.1007/s10762-015-0211-3

TY - JOUR

T1 - Status of the ITER electron cyclotron heating and current drive system

AU - Darbos, Caroline

AU - Albajar, Ferran

AU - Bonicelli, Tullio

AU - Carannante, Giuseppe

AU - Cavinato, Mario

AU - Cismondi, Fabio

AU - Denisov, Grigory

AU - Farina, Daniela

AU - Gagliardi, Mario

AU - Gandini, Franco

AU - Gassmann, Thibault

AU - Goodman, Timothy

AU - Hanson, Gregory

AU - Henderson, Mark A.

AU - Kajiwara, Ken

AU - McElhaney, Karen

AU - Nousiainen, Risto

AU - Oda, Yasuhisa

AU - Omori, Toshimichi

AU - Oustinov, Alexander

AU - Parmar, Darshankumar

AU - Popov, Vladimir L.

AU - Purohit, Dharmesh

AU - Rao, Shambhu Laxmikanth

AU - Rasmussen, David

AU - Rathod, Vipal

AU - Ronden, Dennis M.S.

AU - Saibene, Gabriella

AU - Sakamoto, Keishi

AU - Sartori, Filippo

AU - Scherer, Theo

AU - Singh, Narinder Pal

AU - Strauß, Dirk

AU - Takahashi, Koji

PY - 2016/1

Y1 - 2016/1

N2 - The electron cyclotron (EC) heating and current drive (H&CD) system developed for the ITER is made of 12 sets of high-voltage power supplies feeding 24 gyrotrons connected through 24 transmission lines (TL), to five launchers, four located in upper ports and one at the equatorial level. Nearly all procurements are in-kind, following general ITER philosophy, and will come from Europe, India, Japan, Russia and the USA. The full system is designed to couple to the plasma 20 MW among the 24 MW generated power, at the frequency of 170 GHz, for various physics applications such as plasma start-up, central H&CD and magnetohydrodynamic (MHD) activity control. The design takes present day technology and extends toward high-power continuous operation, which represents a large step forward as compared to the present state of the art. The ITER EC system will be a stepping stone to future EC systems for DEMO and beyond. The development of the EC system is facing significant challenges, which includes not only an advanced microwave system but also compliance with stringent requirements associated with nuclear safety as ITER became the first fusion device licensed as basic nuclear installations as of 9 November 2012. Since the conceptual design of the EC system was established in 2007, the EC system has progressed to a preliminary design stage in 2012 and is now moving forward toward a final design.

AB - The electron cyclotron (EC) heating and current drive (H&CD) system developed for the ITER is made of 12 sets of high-voltage power supplies feeding 24 gyrotrons connected through 24 transmission lines (TL), to five launchers, four located in upper ports and one at the equatorial level. Nearly all procurements are in-kind, following general ITER philosophy, and will come from Europe, India, Japan, Russia and the USA. The full system is designed to couple to the plasma 20 MW among the 24 MW generated power, at the frequency of 170 GHz, for various physics applications such as plasma start-up, central H&CD and magnetohydrodynamic (MHD) activity control. The design takes present day technology and extends toward high-power continuous operation, which represents a large step forward as compared to the present state of the art. The ITER EC system will be a stepping stone to future EC systems for DEMO and beyond. The development of the EC system is facing significant challenges, which includes not only an advanced microwave system but also compliance with stringent requirements associated with nuclear safety as ITER became the first fusion device licensed as basic nuclear installations as of 9 November 2012. Since the conceptual design of the EC system was established in 2007, the EC system has progressed to a preliminary design stage in 2012 and is now moving forward toward a final design.

KW - ITER electron cyclotron heating current drive

UR - https://www.scopus.com/pages/publications/84992685536

U2 - 10.1007/s10762-015-0211-3

DO - 10.1007/s10762-015-0211-3

M3 - Article

AN - SCOPUS:84992685536

SN - 1866-6892

VL - 37

SP - 4

EP - 20

JO - Journal of Infrared, Millimeter, and Terahertz Waves

JF - Journal of Infrared, Millimeter, and Terahertz Waves

IS - 1

ER -

Status of the ITER electron cyclotron heating and current drive system

Abstract

Keywords

Access to Document

Other files and links

Fingerprint

Cite this