Plasma Control in Tokamaks

Q3 Engineering Advances in Systems Science and Applications Pub Date : 2020-06-30 DOI:10.25728/ASSA.2020.20.2.892

Y. Mitrishkin, N. Kartsev, A. Konkov, M. Patrov

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Abstract

The plasma magnetic control systems for ITER (International Thermonuclear Experimental Reactor) are presented. The systems comprise original engineering solutions for plasma position, current and shape control for the two versions of ITER: ITER-1 and ITER-2, including those designed in V. A. Trapeznikov Institute of Control Sciences of the RAS. It is noted that in ITER-1 the plasma position and shape were controlled by all PF-coils and robust H∞-controllers, while to decrease peaks of control power for suppressing minor disruptions the additional nonlinear circuit was used without significant changes in displacements of the gaps between the plasma separatrix and the first wall. In ITER-2 the special circuit with a fast voltage rectifier was used for plasma vertical speed stabilization about zero, while for plasma current and shape control the special cascade control systems were designed with and without the control channels decoupling, with robust H∞-controllers and predictive model, and with adaptive stabilization of the plasma vertical position as well. To increase the plasma controllability region in the vertical direction the additional horizontal field coils were introduced into the ITER-2 vacuum vessel and the capabilities of the system with the new circuits to control the plasma vertical position at the noise presence were investigated.

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托卡马克的等离子体控制

介绍了国际热核实验堆(ITER)的等离子体磁控制系统。这些系统包括两个版本的ITER: ITER-1和ITER-2的等离子体位置、电流和形状控制的原始工程解决方案，包括由RAS的V. A. Trapeznikov控制科学研究所设计的那些。值得注意的是，在ITER-1中，等离子体的位置和形状由所有pf线圈和鲁棒H∞控制器控制，而为了降低控制功率的峰值以抑制轻微的中断，使用了额外的非线性电路，而等离子体分离矩阵和第一壁之间的间隙位移没有明显变化。在ITER-2中，采用带快速电压整流器的特殊电路对等离子体垂直速度进行零左右的稳定，而在等离子体电流和形状控制方面，设计了具有控制通道解耦和不具有控制通道解耦、鲁棒H∞控制器和预测模型以及等离子体垂直位置自适应稳定的特殊串级控制系统。为了增加等离子体在垂直方向上的可控范围，在ITER-2真空容器中引入了额外的水平场线圈，并研究了新电路在存在噪声的情况下对等离子体垂直位置的控制能力。

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

Advances in Systems Science and Applications Engineering-Engineering (all)

CiteScore

1.20

自引率

0.00%

发文量

期刊介绍： Advances in Systems Science and Applications (ASSA) is an international peer-reviewed open-source online academic journal. Its scope covers all major aspects of systems (and processes) analysis, modeling, simulation, and control, ranging from theoretical and methodological developments to a large variety of application areas. Survey articles and innovative results are also welcome. ASSA is aimed at the audience of scientists, engineers and researchers working in the framework of these problems. ASSA should be a platform on which researchers will be able to communicate and discuss both their specialized issues and interdisciplinary problems of systems analysis and its applications in science and industry, including data science, artificial intelligence, material science, manufacturing, transportation, power and energy, ecology, corporate management, public governance, finance, and many others.