Determination of particle trajectory in gas insulated bus duct by Monte-Carlo technique

1999 Annual Report Conference on Electrical Insulation and Dielectric Phenomena (Cat. No.99CH36319) Pub Date : 1999-10-17 DOI:10.1109/CEIDP.1999.804672

J. Amarnath, Bikram Pal Singh, S. Kamaksaiah, C. Radhakrishna

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引用次数: 10

Abstract

A method based on particle motion is proposed to determine the particle trajectory in Gas Insulated Substation (GIS) or Gas Insulated Busduct (GIB). In order to determine the movement of a particle in a GIB, an inner electrode diameter of 55 mm and outer enclosure diameter of 152 mm was considered. Aluminium and copper wires of 0.5 mm/10 mm were considered to be present on the enclosure surface. The motion of the wire (particle) was simulated using the charge acquired by the particles, the macroscopic field at the particle site, the drag coefficient, Reynold's number and coefficient of restitution. The distance travelled by the particle, calculated using the appropriate equations, is found to be in good agreement with the published work for a given set of parameters. The results are also presented for other set of parameters. In order to determine the random behaviour of moving particles, the calculation of movement in axial and radial directions was done at every time step using rectangular random numbers. Typically for Aluminium wire for a bus duct voltage of 100 kV RMS, the movement of the particle (0.5 mm/10 mm) for 2 sec was computed to be 26.02 mm in axial and 1002.3 mm in radial directions. Similar calculation is extended for a typical 220 kV (RMS) Gas Insulated Busduct.

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用蒙特卡罗技术测定气体绝缘母线管道内粒子轨迹

提出了一种基于粒子运动的气体绝缘变电站或气体绝缘管道中粒子运动轨迹的确定方法。为了确定颗粒在GIB中的运动，考虑了内电极直径为55 mm，外罩直径为152 mm。0.5 mm/10 mm的铝线和铜线被认为存在于外壳表面。利用粒子获得的电荷、粒子所在位置的宏观场、阻力系数、雷诺数和恢复系数对导线(粒子)的运动进行了模拟。在给定一组参数下，用适当的方程计算出的粒子移动的距离与已发表的研究结果非常吻合。对其他参数组也给出了计算结果。为了确定运动粒子的随机行为，采用矩形随机数计算每个时间步的轴向和径向运动。对于母线管道电压为100 kV RMS的铝线，粒子(0.5 mm/10 mm)在2秒内的移动计算为轴向26.02 mm和径向1002.3 mm。对典型的220千伏(RMS)气体绝缘管道进行了类似的计算。

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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1999 Annual Report Conference on Electrical Insulation and Dielectric Phenomena (Cat. No.99CH36319)

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