外覆绝缘材料的高压开关柜接头温度监测技术

doi:10.16628/j.cnki.2095-8188.2021.04.009

摘要/Abstract

摘要：

外覆绝缘材料的高压开关柜接头温度测量一直是电力设计所关注的主要问题,针对绝缘件环氧树脂浇注埋覆传感器预定位困难、内部磁场干扰、传感器引线影响爬电距离等问题,提出了以绝缘层外壁和本体空间环境温度为参考因素,间接计算导体接头温度的方案。用Ansys对高压柜电缆接头建模,获得了接头处的温度场分布。研究了接头温度与外覆绝缘材料外壁温度和环境温度的关系,并且利用绝缘材料外壁温度和环境温度通过支持向量机和神经网络算法对导体接头温度进行了计算。结果表明神经网络算法具有较高的精度,可以用于外覆绝缘材料的高压开关柜接头温度的在线监测,对相关工程应用具有一定的参考意义。

关键词: 高压开关柜, 导体接头, 温度测量, 在线监测, 神经网络

Abstract:

The temperature measurement of the high voltage switchgear joints covered with insulating materials has always been the main concern of power design.For the problems such as difficulty in pre-positioning of the insulator epoxy resin casting buried sensor,internal magnetic field interference,and the creepage distance of the sensor lead,it is proposed the scheme that take the outer wall of the insulation layer and the ambient temperature of the body space as reference factors to indirectly calculate the conductor joint temperature.The cable joints of the high voltage cabinet are modeled by Ansys,and the temperature field distribution at the joints is obtained.The relationship between the joint temperature and the outer wall temperature of the insulating material and the ambient temperature is studied,and the conductor joint temperature is calculated by the support vector machine and neural network algorithm by using the outer wall temperature of the insulating material and the ambient temperature.The results show that the neural network algorithm has high accuracy and can be used for on-line monitoring of the joint temperature of high voltage switchgear covered with insulating materials,which has certain reference significance for related engineering applications.

Key words: high voltage switchgear, conductor joint, temperature measurement, on-line monitoring, neural network

中图分类号:

TM591

周文文. 外覆绝缘材料的高压开关柜接头温度监测技术[J]. 电器与能效管理技术, 2021, 0(4): 46-51.

ZHOU Wenwen. Joint Temperature Monitoring Technology of High Voltage Switchgear Covered with Insulation Materials[J]. LOW VOLTAGE APPARATUS, 2021, 0(4): 46-51.

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绝缘层外壁温度/℃	环境温度/℃	电缆接头温度/℃			绝对误差/%
绝缘层外壁温度/℃	环境温度/℃	仿真值	模拟测量值		绝对误差/%
24.6	16.0	32.2		31.4	2.5
38.5	18.2	47.5		48.5	2.1
42.9	24.3	52.5		51.4	2.1
43.3	20.4	53.6		55.4	3.2
47.1	16.4	60.8		61.5	1.1
50.6	27.6	61.6		63.3	2.7
55.4	25.6	68.8		69.6	1.2
57.8	30.5	76.8		79.0	2.9
64.7	34.7	82.9		84.5	1.9
65.1	22.7	84.1		86.4	2.7
67.2	32.4	83.9		85.3	1.6
67.6	28.7	85.0		87.2	2.5

绝缘层外壁温度/℃	环境温度 /℃	电缆接头温度/℃			绝对误差/%
				SVM	BP神经网络	模拟测量值	SVM	BP 网络
		24.6	16.0	30.9	31.1	31.4	1.6	0.9
38.5	18.2	47.8	49.4	48.5	1.4	1.8
42.9	24.3	52.2	51.6	51.4	1.6	0.3
43.3	20.4	56.3	54.1	55.4	1.6	2.3
47.1	16.4	60.2	60.8	61.5	2.1	1.1
50.6	27.6	61.3	61.7	63.3	3.2	2.5
55.4	25.6	67.9	68.3	69.6	2.4	1.9
57.8	30.5	79.7	78.9	79.0	0.9	0.1
64.7	34.7	86.0	82.7	84.5	1.7	2.1
65.1	22.7	87.4	86.7	86.4	1.2	0.3
67.2	32.4	84.1	84.8	85.3	1.4	0.5
67.6	28.7	88.3	877	87.2	1.3	0.2