Study on the Lightning Strike Discharge Characteristics of Air Gap at Low Air Pressure Condition

Li Jin, Zhu Xinhan, Wang Qiang, Zhang Zhijin, J. Xingliang
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Abstract

The average altitude of Qinghai Tibet railway is 4000m. The correct and reasonable design of air gap of electrical insulation is the technical bottleneck to determine the clearance height of Qinghai Tibet railway tunnel and the design of overhead contact system insulation structure. However, it costs a lot to carry out the typical air gap true type test in the actual site with an average altitude of 4000m and above. Therefore, it is necessary to establish tunnel model by using the large-scale multi-functional artificial climate chamber of Chongqing University, to test and study the insulation characteristics of typical air gap under different applied voltages. According to the actual parameters of the tunnel, the stainless steel ceiling is built. Since the Golmud - Lhasa section of Qinghai Tibet railway is in single line operation, the vertical plane where the highest line of ceiling is located is taken as the measurement datum of catenary. The constant voltage rise and fall method and uniform voltage rise method recommended by IEC60507, GB / t4585, DL / t859 and other standards are used to test the breakdown characteristics of air gap. The 50% breakdown voltage under lightning impulse voltage is obtained by constant voltage rise and fall method, and the breakdown voltage under AC power supply is obtained by uniform voltage rise method. The altitude parameters are classified according to 500m, and the atmospheric parameters of 3500∼5500m are simulated. The altitude correction methods based on (d, P, h) and (d, $\delta$, h) are respectively used to fit the test data to obtain the lightning impulse discharge voltage correction formula of the air insulation gap. The test results show that the error between the calculation results and the test results is less than 5.0%, which means that the test and fitting meet the engineering requirements. The calculation results show that: (1) The lightning impulse voltage of the air gap at high altitude is a function of air pressure, temperature and absolute humidity. (2) Taking the gap distance of 1000m above sea level as the reference value (di), in order to maintain the same electrical strength, a correction factor should be added to check the gap distance (dH) at high altitude.
低气压条件下气隙雷击放电特性研究
青藏铁路平均海拔4000米。电气绝缘气隙的正确合理设计是青藏铁路隧道间隙高度确定和架空接触系统绝缘结构设计的技术瓶颈。但在平均海拔4000米及以上的实际场地进行典型气隙真型试验,成本较高。因此,有必要利用重庆大学大型多功能人工气候室建立隧道模型,测试研究不同外加电压下典型气隙的绝缘特性。根据隧道的实际参数,建造不锈钢吊顶。由于青藏铁路格尔木-拉萨段为单线运营,因此取吊顶最高线所在的垂平面作为接触网的测量基准面。采用IEC60507、GB / t4585、DL / t859等标准推荐的恒压升降法和均匀升压法测试气隙击穿特性。雷击电压下50%击穿电压采用恒升压法,交流电源下50%击穿电压采用均匀升压法。海拔参数按500m分类,模拟3500 ~ 5500m的大气参数。分别采用基于(d, P, h)和(d, $\delta$, h)的高度校正方法对试验数据进行拟合,得到空气绝缘间隙雷击放电电压校正公式。试验结果表明,计算结果与试验结果误差小于5.0%,试验拟合符合工程要求。计算结果表明:(1)高空气隙雷击电压是气压、温度和绝对湿度的函数。(2)以海拔1000m的间隙距离(di)为参考值,为保持相同的电气强度,应加校正系数对高空间隙距离(dH)进行校核。
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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