基于借线遥控电极阵列的二维/三维电法勘探

doi:10.11720/wtyht.2024.0170

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摘要

借线遥控电极阵列是一种新型供电—观测电极阵列,它借助常规电法勘探的供电导线和测量导线载波传送信号,遥控各导线与其链接的系列编码电极开关,从而有序地开展供电和测量。这种阵列的电极点距可灵活改变,供电电极间距可逐渐遥控扩大,实现了梯度测深阵列化测量。借线遥控器可以与单道电测仪、多测道电法仪、高密度电法仪等配合使用,组合后电极的阵列能更有效地开展二维/三维电法勘探。应用实例表明,与传统探测方式或高密度方式相比较,借线遥控电极及其组合阵列在矿产、岩溶等复杂地形地质条件下展现出高效率和高灵活性,拓展了电法勘探深部探测应用技术体系,具有推广价值和应用前景。

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	葛为中
	梁炳和
	高建东
	吕玉增
	陈龙

关键词 ：电极阵列, 借线遥控, 梯度测深, 任意四极

Abstract：

The telecontrol electrode array is a new type of electrode array for power supply and observations that utilizes the carrier waves of the power-supply and measurement wires used in conventional electrical prospecting to transmit signals. By remotely controlling a series of coded electrode switches between various wires and their connections, this array allows for orderly power supply and measurements. This array enables flexible spacings between electrodes and the gradual expansion of the distances between power supply electrodes via remote control, thus achieving a gradient-based sounding array. The borrowing-line remote controller can be used combined with single-channel, multi-channel, and high-density resistivity instruments, and the combined arrays can perform 2D/3D electrical prospecting more effectively. Followed by the brief introduction of the principle of the borrowed-line telecontrol electrode array, this study discusses the applications and examples of this array and several combined arrays in the resistivity method and induced polarization (IP).

Key words： electrode array borrowing line remote control gradient sounding arbitrary quadrupole

收稿日期: 2024-04-15 修回日期: 2024-10-16 出版日期: 2024-12-20

ZTFLH:

P631

基金资助:国家自然科学基金项目(42274182)

通讯作者: 吕玉增(1978-),男,博士,教授,主要从事电磁法勘探理论与应用研究工作。Email:Lyz@glut.edu.cn

引用本文:

葛为中, 梁炳和, 高建东, 吕玉增, 陈龙. 基于借线遥控电极阵列的二维/三维电法勘探[J]. 物探与化探, 2024, 48(6): 1437-1447.
GE Wei-Zhong, LIANG Bing-He, GAO Jian-Dong, Lv Yu-Zeng, CHEN Long. 2D/3D electrical exploration based on borrowing-line telecontrol electrode arrays. Geophysical and Geochemical Exploration, 2024, 48(6): 1437-1447.

链接本文:

https://www.wutanyuhuatan.com/CN/10.11720/wtyht.2024.0170 或 https://www.wutanyuhuatan.com/CN/Y2024/V48/I6/1437

Fig.1-1 借线遥控器

Fig.1-2 借线遥控器

Fig.2 借线遥控发送机(a)和接收机(b)设计方框

Fig.3 借线遥控电极阵列示意图和GS的梯度电极序列示意

Fig.4 帷幕注浆孔及测线电极布设平面

Fig.5 1线梯度剖面视电阻率曲线

Fig.6 2线梯度剖面视电阻率曲线

Fig.7 GS反演电阻率断面

Fig.8 借线遥控供电阵列与IPR-12激电法仪组合

Fig.9 华阳铅锌矿Z2线梯度激电测深二维反演结果

Fig.10 板才矿区三维中梯激电测深布极平面

Fig.11 板才矿区主测线二维反演极化率断面

Fig.12 板才矿区三维反演极化率侧视立体图像

Fig.13 二维超深高密度法的高密度阵列与借线遥控供电阵列布设示意

Fig.14 海南省红水31线二维超深高密度电法反演电阻率断面

Fig.15 岩溶区5条二维剖面、三维电极阵列、有限元网格平面

Fig.16 2D+3D数据三维反演电阻率平面切片

Fig.17 3D数据三维反演电阻率异常立体

[1]	葛为中. 电阻率法新理念[C]// 中国地球物理学会第22届年会, 2006.
[1]	Ge W Z. New concepts in resistivity method[C]// Proceedings of the 22^nd Annual Meeting of the Chinese Geophysical Society, 2006.
[2]	葛为中. 电测深布极装置及观测方式的变革[C]// 中国地球物理学会第23届年会, 2007.
[2]	Ge W Z. Transformation of electrode arrangement and observation method in electrical sounding[C]// Proceedings of the 23^rd Annual Meeting of the Chinese Geophysical Society, 2007.
[3]	葛为中, 吕玉增, 丁云河. 梯度电测深剖面法及其应用[J]. 物探与化探, 2011, 35 (2):206-211.
[3]	Ge W Z, Lyu Y Z, Ding Y H. The gradient sounding profile method and its application[J]. Geophysical and Geochemical Exploration, 2011, 35 (2):206-211.
[4]	吕玉增, 葛为中, 彭苏萍. 多极距中梯观测与反演研究[J]. 物探与化探, 2013, 37 (1):92-97
[4]	Lyu Y Z, Ge W Z, Peng S P. A study of multiple electrode distance central gradient survey and inversion[J]. Geophysical and Geochemical Exploration, 2013, 37 (1):92-97.
[5]	Dahlin T, Zhou B. Multiple-gradient array measurements for multichannel 2D resistivity imaging[J]. Near Surface Geophysics, 2006, 4(2):113-123
[6]	高建东, 高勇, 杜利明, 等. 四极梯度电测深野外实测剖面对比研究[C]// 华东六省一市地学科技论坛, 2013.
[6]	Gao J D, Gao Y, Du L M, et al. Comparative study on field measured profiles of four-Electrode gradient electrical sounding[C]// Proceedings of the Geological Science and Technology Forum of Six Eastern Provinces and One City, 2013.
[7]	邱光辉, 尹学爱, 张启生, 等. 四极梯度测深在智利某铜矿区的应用[J]. 物探与化探, 2018, 42 (6):1059-1063.
[7]	Qiu G H, Yin X A, Zhang Q S, et al. The application of quadrupole gradient sounding to a certain copper mine in Chile[J]. Geophysical and Geochemical Exploration, 2018, 42 (6):1059-1063.
[8]	Wang J L, Lin P R, Wang M, et al. Three-dirnensional tomography using high-power induced polarization with the similar central gradient array[J]. Applied Geophysics, 2017, 14(2):291-300,324.
[9]	梁炳和. 电法勘探电极多通道遥控器的研制[J]. 企业科技与发展, 2010, 20:68-70
[9]	Liang B H. Development of a multi-channel remote controller for electrical prospecting electrodes[J]. Enterprise Science and Technology Development, 2010, 20:68-70.
[10]	梁佳会, 葛为中, 梁炳和. 电法勘探电极阵列借线遥控器:CIV201711013579.5[P]. 2021-03-06.
[10]	Liang J H, Ge W Z, Liang B H. Electrical exploration click array borrowing remote control:CN201711013579.5[P]. 2021-03-06.
[11]	高建东. GDF高密度电法二维正反演软件及模型测试结果[C]// 中国地球物理学会第23届年会, 2007.
[11]	Gao J D. GDF high-density electrical method 2D forward and inverse software and model test results[C]// Proceedings of the 23rd Annual Meeting of the Chinese Geophysical Society, 2007.
[12]	Loke M H, Kiflu H, Wilkinson P B, et al. Optimized arrays for 2D resistivity surveys with combined surface and buried arrays[J]. Near Surface Geophysics, 2015, 13(5):505-517.
[13]	黄智伟, 单片无线发射与接收电路设计[M]. 西安: 西安电子科技大学出版社, 2009.
[13]	Huang Z W. Design of single-chip wireless transmission and reception circuit[J]. Xi’an: University of Electronic Science and Technology Press, 2009.
[14]	杜树春. 数字集成电路:原理、测试与应用[M]. 北京: 化学工业出版社, 2023.
[14]	Du S C. Digital integrated circuits:Principles,testing,and applications[M]. Beijing: Chemical Industry Press, 2023.
[15]	梁炳和, 葛为中. 多通道电阻率仪的研制和应用[J]. 华北水利水电学院学报, 2010, 31(4):116-119.
[15]	Liang B H, Ge W Z. Development and application of multi-channel resistivity instruments[J]. Journal of North China Institute of Water Conservancy and Hydroelectric Power, 2010, 31(4):116-119.
[16]	杨兴沐, 黄卓雄, 葛为中, 等. 遥控电极阵列拓展高密度电阻率法勘探深度研究[J]. 物探与化探, 2016, 40(1):73-77.
[16]	Yang X M, Huang Z X, Ge W Z, et al. Research on electrical resistivity imaging with telecontrol electrode array in surveying depth[J]. Geophysical and Geochemical Exploration, 2016, 40(1):73-77.
[17]	葛为中, 梁炳和, 高建东, 等. 遥控电极阵列和二/三维超深高密度电法的研究[C]// 中国建筑学会工程勘察分会工程物探专业委员会第14届全国工程物探与岩土工程测试学术大会, 2015.
[17]	Ge W Z, Liang B H, Gao J D, et al. Research on remote control electrode array and two/three-dimensional ultra-deep high-density electrical method[C]// Proceedings of the 14^th National Conference on Engineering Geophysics and Geotechnical Engineering Testing of the Engineering Geophysical Professional Committee of the China Building Society, 2015.
[18]	冉军林, 刘俊岩. 组合激电测深装置的应用与研究[J]. 物探与化探, 2018, 42,(6):1259-1263.
[18]	Ran J L, Liu J Y. The application and study of induced polarization group device[J]. Geophysical and Geochemical Exploration, 2018, 42(6):1259-1263.
[19]	Wang J, Zhang X P, Du L Z, et al. Comparing methods of 3D acquisition of simulated multi-electrode resistivity data using TOPSIS[J]. Journal of Applied Geophysics, 2018, 159:631-639.
[20]	Nobahar M, Salunke R, Alzeghoul O E, et al. Mapping of slope failures on highway embankments using electrical resistivity imaging (ERI),unmanned aerial vehicle (UAV),and finite element method (FEM) numerical modeling for forensic analysis.[J]. Transportation Geotechnics, 2023, 40:100949.

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