土壤电阻率的负温特性及冻土对接地极冲击响应的影响

doi:10.19595/j.cnki.1000-6753.tces.222233

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摘要西藏地区由于独特的气候与地理环境,在其冻土地区存在雷电与低温共存现象。低温下冻土作为含冰复杂体系,其在雷击下的冲击散流性能仍不明晰,因此该文就冻土电阻率的负温特性以及接地极的冲击特性开展研究。首先研究了不同含水量、含盐量的土壤电阻率随温度的变化规律;然后在冲击电流作用下,以永冻土试品的表层土壤融化厚度和季节性冻土试品的表层土壤冻结厚度为变量,探究了其对相应冻土中垂直接地极暂态电位的影响规律;最后结合冻结条件下土壤冲击放电的形貌特征与地中电场强度和电流密度的分布特性,探讨了负温下接地极暂态电位变化的本质原因。试验研究表明：考虑盐分对土壤的影响,当其温度在一次冻结温度T_f与二次冻结温度T_s之间时,电阻率随温度下降缓慢上升,只有当温度降至二次冻结温度时,才存在突增现象;在永冻土中,当冻土温度高于T_s时,接地极仍具有较好的散流性能。由此可知降低T_s可以减小水分冻结对土壤电阻率的影响,为避免极寒地区接地极失效提供了新思路。

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关键词 ：接地, 冻土, 冲击电流, 极寒低温, 土壤电离

Abstract：Due to the unique geographical location and climate environment in Tibet, the coexistence of frozen soil and lightning current exists in the low temperature area, and the green energy transmission channel is difficult to avoid the low temperature area. However, as a complex system of water, ice, air and soil particles containing ice at negative temperature, the variation of soil resistivity with temperature under different water and salt contents and the impulse characteristics of grounding devices in frozen soil under lightning current are still unclear.
Therefore, in view of the above problems, on the one hand, the change of resistivity with temperature of 16 soil samples with different water content and salt content was measured by the quadrupole method, and the reasons for the change of soil resistivity were analyzed by combining the soil conductivity mechanism and the calculation formula of unfrozen water content; on the other hand, based on the similarity principle of the scale experiment, taking the surface soil freezing thickness of the seasonal frozen soil sample and the surface soil melting thickness of the permafrost sample as variables, the influence law of the vertical grounding electrode transient potential in the corresponding frozen soil sample was explored. Furthermore, the X-ray imaging device was used to observe the discharge image of the impulse current in the frozen soil sample and the numerical simulation results of electric field intensity and current density in the frozen soil were combined to explain the experimental law.
The measurement results of soil resistivity at different temperatures show that when the temperature of saline soil is higher than the secondary freezing temperature (T_s), its resistivity increases slowly with the decrease of temperature; when the temperature is lower than T_s, the resistivity has a sudden rise. The results of impulse current dispersion experiment of grounding electrode in permafrost show that when the temperature of permafrost layer is higher than T_s, the permafrost still has good current dispersion performance; the melting thickness of surface soil increases, and the potential of grounding electrode decreases slowly; when the melting thickness exceeds its end, the potential decreases greatly; however, when the temperature of the frozen soil layer is lower than T_s, the frozen soil with great resistivity will force the current to disperse in the surface thawing soil, and the grounding electrode potential is very small. The impulse current dispersion test results of the grounding electrode in seasonal frozen soil show that the grounding electrode potential will rise slowly with the increase of the freezing thickness of the surface soil; when the freezing thickness exceeds its end, the potential rise becomes larger.
The following conclusions can be drawn from the analysis of the results: (1) When the temperature of saline frozen soil decreases to T_s, a large amount of non-conductive ice and water salt will be generated, and the water content will decrease sharply, resulting in a sudden increase in soil resistivity. (2) The discharge image observation results and numerical simulation results of impulse current in frozen soil show that the current dispersion performance of frozen soil is inferior to that of thawed soil, and the soil ionization degree around the grounding extreme is the most serious, while the soil ionization is beneficial to the end current dispersion, therefore, when the thickness of the surface soil is greater than the length of the vertical grounding electrode, the change range of the transient potential of the grounding electrode will be greater. It can be seen from the above that by reducing the T_s of the soil, the grounding performance of the grounding device can be avoided to fail under extremely cold conditions.

Key words： Grounding frozen soil impulse current extremely cold temperature soil ionizaion

收稿日期: 2022-11-29

PACS:

TM863

基金资助:国家自然科学基金面上项目资助（51777020）

通讯作者: 袁涛男,1976年生,副教授,博士生导师,研究方向为电力系统过电压防护及防雷接地技术、电磁兼容技术。E-mail：yuantao_cq@cqu.edu.cn

作者简介: 任健行男,1998年生,硕士研究生,研究方向为输电线路防雷接地。E-mail：1109073216@qq.com

引用本文:

袁涛, 任健行, 司马文霞, 常飞童, 蔡永翔, 肖小兵. 土壤电阻率的负温特性及冻土对接地极冲击响应的影响[J]. 电工技术学报, 2024, 39(5): 1474-1485. Yuan Tao, Ren Jianxing, Sima Wenxia, Chang Feitong, Cai Yongxiang, Xiao Xiaobing. Negative Temperature Characteristics of Soil Resistivity and Influence of Frozen Soil on Impulse Response of Grounding Electrode. Transactions of China Electrotechnical Society, 2024, 39(5): 1474-1485.

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https://dgjsxb.ces-transaction.com/CN/10.19595/j.cnki.1000-6753.tces.222233 https://dgjsxb.ces-transaction.com/CN/Y2024/V39/I5/1474

[1] 蔡国伟, 雷宇航, 葛维春, 等. 高寒地区风电机组雷电防护研究综述[J]. 电工技术学报, 2019, 34(22): 4804-4815.
Cai Guowei, Lei Yuhang, Ge Weichun, et al.Review of research on lightning protection for wind turbines in alpine areas[J]. Transactions of China Electrotechnical Society, 2019, 34(22): 4804-4815.
[2] 周仿荣, 邹德旭, 马御棠, 等. 2010~2014年西藏地区雷电地闪分布特征[C]//2017智能电网信息化建设研讨会论文集, 北京, 2017: 84-88.
[3] 陈博. 中国冻土时空变化特征及其与东亚气候的关系[D]. 北京: 中国科学院研究生院(大气物理研究所), 2007.
Chen Bo.Characteristics of spatial and temporal variation of frozen soil in China and their association with the East Asian Climate[D]. Beijing: Graduate School of the Chinese Academy of Sciences (Institute of Atmospheric Physics), 2007.
[4] 郭蕾, 古维富, 刘彬, 等. 杆塔接地装置的冲击阻抗建模及应用[J]. 电工技术学报, 2020, 35(10): 2239-2247.
Guo Lei, Gu Weifu, Liu Bin, et al.Impulse impedance modeling and application of tower grounding device[J]. Transactions of China Electrotechnical Society, 2020, 35(10): 2239-2247.
[5] Charalambous C A, Dimitriou A, Kioupis N, et al.Wall fusion of buried pipelines due to direct lightning strikes: field, laboratory, and simulation investigation of the damaging mechanism[J]. IEEE Transactions on Power Delivery, 2020, 35(2): 763-773.
[6] 钟逸涵, 邓丰, 史鸿飞, 等. 基于动态电阻串联的高阻接地故障精确建模[J/OL]. 电工技术学报, 2023: 1-14. https://doi.org/10.19595/j.cnki.1000-6753. tces.230065.
Zhong Yihan, Deng Feng, Shi Hongfei, et al. Accurate modeling of high-impedance grounding faults based on dynamic resistance series[J/OL]. Transactions of China Electrotechnical Society, 2023: 1-14. https:// doi.org/10.19595/j.cnki.1000-6753.tces.230065.
[7] Wang Chenyang, Liang Xiaodong, Adajar E P, et al.Investigation of seasonal variations of tower footing impedance in transmission line grounding systems[J]. IEEE Transactions on Industry Applications, 2021, 57(3): 2274-2284.
[8] 张宝平, 何金良, 康鹏, 等. 高海拔永冻地区青藏铁路输电线路防雷设计[J]. 高电压技术, 2008, 34(6): 1095-1099.
Zhang Baoping, He Jinliang, Kang Peng, et al.Lightning protection design strategy for transmission lines of the Qinghai-Tibet railway in high altitude permafrost region[J]. High Voltage Engineering, 2008, 34(6): 1095-1099.
[9] 邹乐凯. 极寒地区直流接地极入地电流散流特性及监测装置研究[D]. 重庆: 重庆大学, 2020.
Zou Lekai.Research on ground current dispersion characteristics and monitoring device of DC grounding electrode in extremely cold region[D]. Chongqing: Chongqing University, 2020.
[10] 罗豪良, 滕继东, 张升, 等. 冻土未冻水含量与电导率的关系研究[J]. 岩石力学与工程学报, 2021, 40(5): 1068-1079.
Luo Haoliang, Teng Jidong, Zhang Sheng, et al.Study on the relationship between unfrozen water content and electrical conductivity in frozen soils[J]. Chinese Journal of Rock Mechanics and Engineering, 2021, 40(5): 1068-1079.
[11] 曹晓斌, 吴广宁, 付龙海, 等. 温度对土壤电阻率影响的研究[J]. 电工技术学报, 2007, 22(9): 1-6.
Cao Xiaobin, Wu Guangning, Fu Longhai, et al.Study of the temperature impact on soil resistivity[J]. Transactions of China Electrotechnical Society, 2007, 22(9): 1-6.
[12] 郭在华, 邢天放, 吴广宁, 等. 冰冻土壤中垂直接地极的接地电阻变化规律[J]. 高电压技术, 2014, 40(3): 698-706.
Guo Zaihua, Xing Tianfang, Wu Guangning, et al.Grounding resistance change rule of vertical grounding electrode in frozen soil[J]. High Voltage Engineering, 2014, 40(3): 698-706.
[13] Liu Yaqing, Theethayi N, Thottappillil R, et al.An improved model for soil ionization around grounding system and its application to stratified soil[J]. Journal of Electrostatics, 2004, 60(2/3/4): 203-209.
[14] 张宝平, 何金良, 康鹏, 等. 冻土冲击特性的试验研究[J]. 中国电机工程学报, 2008, 28(16): 143-147.
Zhang Baoping, He Jinliang, Kang Peng, et al.Experimental study on impulse characteristics of frozen soil[J]. Proceedings of the CSEE, 2008, 28(16): 143-147.
[15] He Jinliang, Zhang Baoping, Kang Peng, et al.Lightning impulse breakdown characteristics of frozen soil[J]. IEEE Transactions on Power Delivery, 2008, 23(4): 2216-2223.
[16] He Jinliang, Zhang Baoping, Zeng Rong, et al.Experimental studies of impulse breakdown delay characteristics of soil[J]. IEEE Transactions on Power Delivery, 2011, 26(3): 1600-1607.
[17] 邴慧, 马巍. 盐渍土冻结温度的试验研究[J]. 冰川冻土, 2011, 33(5): 1106-1113.
Bing Hui, Ma Wei.Experimental study on freezing point of saline soil[J]. Journal of Glaciology and Geocryology, 2011, 33(5): 1106-1113.
[18] Mukhedkar D, Gervais Y, DeJean J P. Modelling of a grounding electrode[J]. IEEE Transactions on Power Apparatus and Systems, 1973, PAS-92(1): 295-297.
[19] Thapar B, Goyal S L.Scale model studies of grounding grids in non-uniform soils[J]. IEEE Transactions on Power Delivery, 1987, 2(4): 1060-1066.
[20] 徐学祖, 王家澄, 张立新. 冻土物理学[M]. 北京: 科学出版社, 2001.
[21] 肖泽岸, 侯振荣, 董晓强. 降温过程中含盐土孔隙溶液相变规律研究[J]. 岩土工程学报, 2020, 42(6): 1174-1180.
Xiao Zean, Hou Zhenrong, Dong Xiaoqiang.Phase transition of pore solution in saline soil during cooling process[J]. Chinese Journal of Geotechnical Engineering, 2020, 42(6): 1174-1180.
[22] 张立新, 徐学祖, 陶兆祥, 等. 含氯化钠盐冻土中溶液的二次相变分析[J]. 自然科学进展, 1993, 3(1): 48-52.
[23] 吴冰, 朱鸿鹄, 曹鼎峰, 等. 基于光纤光栅的冻土含冰量监测可行性试验研究[J]. 岩土工程学报, 2019, 41(12): 2323-2330.
Wu Bing, Zhu Honghu, Cao Dingfeng, et al.Feasibility study on FBG-based monitoring method for ice content in frozen soil[J]. Chinese Journal of Geotechnical Engineering, 2019, 41(12): 2323-2330.
[24] Mousa A M.The soil ionization gradient associated with discharge of high currents into concentrated electrodes[J]. IEEE Transactions on Power Delivery, 1994, 9(3): 1669-1677.
[25] 刘毅, 赵勇, 任益佳, 等. 水中大电流脉冲放电电弧通道发展过程分析[J]. 电工技术学报, 2021, 36(16): 3525-3534.
Liu Yi, Zhao Yong, Ren Yijia, et al.Analysis on the development process of arc channel for underwater high current pulsed discharge[J]. Transactions of China Electrotechnical Society, 2021, 36(16): 3525-3534.
[26] 罗东辉, 袁涛, 司马文霞, 等. 连续冲击电流作用下土壤放电通道体积特征参数提取方法及机理分析[J]. 高电压技术, 2020, 46(5): 1791-1799.
Luo Donghui, Yuan Tao, Sima Wenxia, et al.Mechanism and method of volume parameter extraction of soil discharge channel under successive impulse currents[J]. High Voltage Engineering, 2020, 46(5): 1791-1799.
[27] 王泽忠, 司远, 刘连光. 考虑地下各向异性介质的磁暴感应地电场研究[J]. 电工技术学报, 2022, 37(5): 1070-1077, 1114.
Wang Zezhong, Si Yuan, Liu Lianguang.Study on the induced geoelectric field of geomagnetic storm considering the underground anisotropic medium[J]. Transactions of China Electrotechnical Society, 2022, 37(5): 1070-1077, 1114.
[28] Clark D, Mousa S, Harid N, et al.Lightning Current performance of conventional and enhanced rod ground electrodes[J]. IEEE Transactions on Electromagnetic Compatibility, 2021, 63(4): 1179-1188.
[29] 黄仕杰, 刘毅, 林福昌, 等. 高压脉冲放电破岩电弧阻抗特性分析[J]. 电工技术学报, 2022, 37(19): 4978-4988.
Huang Shijie, Liu Yi, Lin Fuchang, et al.Analysis of arc impedance characteristics in high-voltage electric pulse discharge rock destruction[J]. Transactions of China Electrotechnical Society, 2022, 37(19): 4978-4988.