Magnetic analysis of the magnetic field reduction system of the ITER neutral beam injector

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• 作者：Germá ; n Barrera^a ; ^{german.barrera@ciemat.es" class="auth_mail" title="E-mail the corresponding author} ; Begoñ ; a Ahedo^a ; Javier Alonso^a ; Luis Rí ; os^a ; Julien Chareyre^b ; Anass El-Ouazzani^b ; Gilbert Agarici^c
• 关键词：ITER ; Magnetic field reduction system (MFRS) ; Neutral beam injectors (NBI) ; Passive magnetic shield (PMS) ; Active compensation/correction coils (ACCC) ; Magnetic analysis
• 刊名：Fusion Engineering and Design
• 出版年：2015
• 出版时间：October 2015
• 年：2015
• 卷：96-97
• 期：Complete
• 页码：400-404
• 全文大小：2962 K

文摘

The neutral beam system for ITER consists of two heating and current drive neutral beam injectors (HNB) and a diagnostic neutral beam (DNB) injector. The proposed physical plant layout allows a possible third HNB injector to be installed later. For the correct operation of the beam, the ion source and the ion path until it is neutralized must operate under a very low magnetic field environment. To prevent the stray ITER field from penetrating inside those mentioned critical areas, a magnetic field reduction system (MFRS) will envelop the beam vessels and the high voltage transmission lines to ion source. This system comprises the passive magnetic shield (PMS), a box like assembly of thick low carbon steel plates, and the Active Correction and Compensation Coils (ACCC), a set of coils carrying a current which depends on the tokamak stray field. This paper describes the magnetic model and analysis results presented at the PMS and ACCC preliminary design review held in ITER organization in April 2013. The paper focuses on the magnetic model description and on the description of the analysis results. The iterative process for obtaining optimized currents in the coils is presented. The set of coils currents chosen among the many possible solutions, the magnetic field results in the interest regions and the fulfillment of the magnetic field requirements are described.