Analysis of electromagnetic loads on an ITER divertor cassette

“…A transition between these two models can be provided in the following manner [4,[24][25][26][27][28][29]. All movable current loops describing plasma in the DINA model throughout all scenario are sorted by coordinates R, Z with a given value of interval : if co-ordinates of two loops satisfy to the condition |R 1 − R 2 | ≤ , |Z 1 − Z 2 | ≤ , these loops are assumed coincident.…”

“…Simulated flux variations in space and time are used as inputs for further eddy current computations. In 3D models, the toroidal magnetic flux induced by the plasma can be simulated by a flux of a virtual toroidal solenoid located in the middle of the vacuum vessel [30,31,[24][25][26][27]. In particular, for ITER the external radius of the virtual solenoid is taken as the radius of the plasma centre R = 6.2 m, the internal radius r is 1 m. The current variation law is given by the following formula:…”

Global computational models for analysis of electromagnetic transients to support ITER tokamak design and optimization

“…A transition between these two models can be provided in the following manner [4,[24][25][26][27][28][29]. All movable current loops describing plasma in the DINA model throughout all scenario are sorted by coordinates R, Z with a given value of interval : if co-ordinates of two loops satisfy to the condition |R 1 − R 2 | ≤ , |Z 1 − Z 2 | ≤ , these loops are assumed coincident.…”

“…Simulated flux variations in space and time are used as inputs for further eddy current computations. In 3D models, the toroidal magnetic flux induced by the plasma can be simulated by a flux of a virtual toroidal solenoid located in the middle of the vacuum vessel [30,31,[24][25][26][27]. In particular, for ITER the external radius of the virtual solenoid is taken as the radius of the plasma centre R = 6.2 m, the internal radius r is 1 m. The current variation law is given by the following formula:…”

Global computational models for analysis of electromagnetic transients to support ITER tokamak design and optimization

“…Для расчётов вих-ревых токов с использованием пространственных моделей авторам представляется более удобным исполь-зовать модель неподвижных витков с заданным законом изменения токов в них. Для перехода от одной модели к другой может использоваться следующий подход [4,[24][25][26][27][28][29]. Все витки, описывающие плазму в модели DINA на протяжении всего сценария, сортируются по координатам R, Z с заданным интервалом ζ: если координаты двух витков удовлетворяют условию 12 ζ, RR  12 ζ, ZZ  то эти витки считаются совпадающими.…”

“…Для зада-ния гало-тока (согласно предложенной авторами методике) в расчётную модель вводят специальные дополнительные проводящие области [24,25], которые моделируют зоны протекания этих токов вне проводников (в зоне внешней поверхности плазмы) во все моменты времени рассматриваемого сцена-рия. Алгоритмической особенностью является то, что в этих специальных проводящих областях не могут возникать вихревые токи в отличие от реально существующих и описываемых в глобальной мо-дели проводящих элементов.…”

Iter Global Computational Models for Em Transient Analysis and Design Optimization

“…Some commercially available FEM tools are often beneficial to relatively large-scale analyses, in practical point of view, to implement a numerical model based on the drawings of design model. Due to the presence of thick shield/breeding blankets, the design of a reactor-grade plasma device in the future, as much as ITER, will prefer solid mesh FEM tools to any shell model [6][7][8] which describes induced current solving set of Maxwell equations [7,8] or coupled circuit equation matrix on 2D surfaces [9], in spite the shell is likely to be applicable to the design of present-day tokamaks due to the small width of conducting structures compared with characteristic dimension of a device. In addition, the commercial software such as ANSYS-EM TM [10] also can be applied to an integrated analysis of EM loads and ensuing mechanical or thermo-hydraulic loads.…”

An efficient modeling of fine air-gaps in tokamak in-vessel components for electromagnetic analyses