Dynamic response of the ITER vacuum vessel to electromagnetic loads during VDEs

2009 23rd IEEE/NPSS Symposium on Fusion Engineering Pub Date : 2009-06-01 DOI:10.1109/FUSION.2009.5226477

C. Bachmann, G. Sannazzaro, M. Sugihara, Y. Gribov, K. Ioki, V. Riccardo, A. Belov, E. Lamzin

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引用次数: 6

Abstract

During vertical displacement events (VDEs) plasma halo currents can flow partly through the passive structure. Additionally induced currents occur in the passive structure. Due to these electrical currents, major electromagnetic forces act on the passive structures and hence on the vacuum vessel (VV). As these forces change in time the vessel response is dynamic. This response determines important design drivers such as the reaction forces at the vessel supports, the vessel displacements and stress levels in the vessel structure, and it affects all components attached to the vessel. It is expected that the most severe dynamic response of the vessel occurs during asymmetric VDEs with slow current quench. Experiments on existing tokamak machines have shown that asymmetric loads can rotate around the vertical machine axis. This possible rotation is considered here. Using the finite element (FE) method the dynamic response of the vessel was analyzed in full transient dynamic analyses for the worst case VDEs according to the ITER VV load specification [2]. A 360° FE model of the VV is used since the loads are partly asymmetric. One major difficulty in this assessment was to predict how the sideways load is shared between three simultaneously acting support types. Attention was therefore given to the modeling of the VV supports including the coupling effect with the toroidal magnetic field.

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vde过程中ITER真空容器对电磁载荷的动态响应

在垂直位移事件(VDEs)中，等离子体晕电流可以部分流过被动结构。另外，感应电流发生在被动结构中。由于这些电流，主要的电磁力作用于被动结构，从而作用于真空容器(VV)。由于这些力随时间变化，容器的响应是动态的。这种响应决定了重要的设计驱动因素，如容器支架处的反作用力、容器位移和容器结构中的应力水平，并影响到附着在容器上的所有部件。在非对称vde中，当电流淬灭缓慢时，容器的动态响应最为剧烈。在现有托卡马克机器上的实验表明，不对称载荷可以绕垂直机器轴旋转。这里考虑了这种可能的旋转。根据ITER VV载荷规范[2]，采用有限元法对最坏情况下的vde进行了全瞬态动力分析。由于载荷部分不对称，使用了VV的360°有限元模型。该评估的一个主要困难是预测横向载荷如何在三种同时起作用的支撑类型之间分担。因此，对包括环向磁场耦合效应在内的VV支承的建模给予了关注。

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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2009 23rd IEEE/NPSS Symposium on Fusion Engineering

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