大地电导率和线路长度对10kV架空线路雷电感应电压的影响

为了对架空线雷电感应电压特性进行系统深入的研究,以10kV单/双回架空线为研究对象进行了数值计算。分析大地电导率(σ)、导线排布方式和线路长度(L_l)3个因素对雷电感应电压峰值沿线分布和时域波形的影响。计算结果表明,感应电压脉冲极性改变的位置随L_l增大明显向导线中部移动,电压最高峰值并非位于距回击通道最近杆塔。感应电压幅值和波形整体受σ影响明显,但距回击通道越近,受影响越弱。相同条件时,σ越低、导线数越多,电压波形"畸变"越严重。感应电压脉冲幅值和上升时间随L_l增大呈不同的非线性增长,但均在L_l≤6km范围内存在明显"饱和"现象,半峰值宽度在L_l整个取值区间内有较明显地增长。排除架设高度因素,导线排布方式对感应电压影响很弱。

架空单导线雷电感应电压特性

为了深入研究架空线雷电感应电压特性,对架空单导线雷电感应电压进行数值计算。采用时域有限差分方法计算地闪回击电磁脉冲,采用Agrawal耦合模型求解场线耦合电路,分析了线路长度、架设高度和边界条件3个因素对架空单导线雷电感应电压峰值沿线分布和时域波形的影响。研究发现:感应电压幅值随架设高度增大接近等比线性提高;感应电压幅值和脉冲宽度均随导线长度增大而非线性提高;受水平电场作用效果的影响,距回击通道最近点感应电压幅值不一定最高;端接电阻值增大引起感应电压脉冲宽度减小和'过零'幅度增大,导线两端点电压幅值和波形受其影响尤为明显,导线中部电压幅值不受端接电阻影响。研究结果为架空配电线路的雷电感应电压防护工作提供了理论参考。

Distribution laws of abutment pressure around fully mechanized top-coal caving face by in-situ measurement

In order to obtain the distribution rules of abutment pressure around the 1151 （3） fully mechanized top-coal caving （FMTC） face of Xieqiao Colliery, the KSE-II-1 type bore-hole stress gauges were installed in the tailentry and headentry to measure the mining-induced stress. The distribution rules of the front and side abutment pressure were demonstrated. The results show that distribution rules of stress are obviously different in the vicinity of the face and entries. The peak value of abutment pressure in the protective coal pillar and face are located commonly in front of the working face along the strike, and they are located at the stress-decreased zone near the face. There is no stress peak value in the lateral coal mass beside the headentry in front of the face on the strike, and the peak value of abutment pressure appears at the rear area of the face. There are stress peak values both in the protective coal pillar and in the lateral coal mass beside the headentry to the dip.