Development of a high field solenoid magnet for the MAST Spherical Tokamak

IF 0.3 1区艺术学 0 MUSIC

NINETEENTH CENTURY MUSIC Pub Date : 2002-11-07 DOI:10.1109/FUSION.2002.1027724

G. Voss, E. Ciattaglia

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引用次数: 2

Abstract

The Mega Amp Spherical Tokamak (MAST) is an experimental fusion device currently operating at the Culham Science Centre. The low aspect ratio of the spherical tokamak combined with the need to develop a high flux swing from its central solenoid leads to high forces on the conductors that form the centre column. This column consists of a compact solenoid wound around the inner limbs of the toroidal field coils. In order to achieve the nominal plasma parameters, the dimensions of the centre column were optimised to make best possible use of the space available. The most critical region of the solenoid magnet design is the end turn and tail section where complex 3D magnetic fields interact with the current in the end turn conductors giving an asymmetric stress distribution. The hoop load in this end turn is particularly troublesome since it must be reacted across a bonded joint, which inevitably generates tensile and shear stresses within it. This paper describes how this problem has been solved for the new MAST centre column by the use of compact quadrupole tails formed close to the main coil and connected to it by tight bends formed in the water cooled copper conductor. A test coil employing these features and fitted with engineering diagnostics has been manufactured and tested at Culham to the maximum design current. This coil not only demonstrated the manufacturing processes involved but also provided test data, which compares well with engineering analysis.

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MAST球形托卡马克用高磁场电磁磁铁的研制

Mega Amp球形托卡马克(MAST)是目前在Culham科学中心运行的实验性聚变装置。球形托卡马克的低长径比，加上需要从其中心螺线管发展高通量摆动，导致形成中心柱的导体受到高力。该柱由一个紧凑的螺线管组成，绕在环形场线圈的内肢上。为了达到标称等离子体参数，中心柱的尺寸进行了优化，以最大限度地利用可用空间。螺线管磁体设计中最关键的区域是端匝和尾部部分，复杂的三维磁场与端匝导体中的电流相互作用，产生不对称的应力分布。在这个末端转弯的环向载荷特别麻烦，因为它必须在一个粘合的关节上反应，这不可避免地在它内部产生拉伸和剪切应力。本文介绍了在新型桅杆中心柱上如何解决这一问题，即采用紧靠主线圈的紧凑型四极杆尾部，并通过水冷铜导体内形成的紧弯与主线圈相连。采用这些特性并配备工程诊断的测试线圈已在Culham制造并测试到最大设计电流。该线圈不仅演示了所涉及的制造过程，还提供了测试数据，与工程分析相比效果很好。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

NINETEENTH CENTURY MUSIC MUSIC-

CiteScore

0.40

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0.00%

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期刊介绍： 19th-Century Music covers all aspects of Western art music between the mid-eighteenth and mid-twentieth centuries. We welcome--in no particular order--considerations of composers and compositions, styles, performance, historical watersheds, cultural formations, critical methods, musical institutions, ideas, and topics not named on this list. Our aim is to publish contributions to ongoing conversations at the leading edge of musical and multidisciplinary scholarship.