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山东大学学报 (工学版) ›› 2026, Vol. 56 ›› Issue (2): 76-81.doi: 10.6040/j.issn.1672-3961.0.2024.300

• 土木工程 • 上一篇    下一篇

基于有限元仿真钢筋混凝土电阻率预估模型

贾刘建1,胡杰1,卞雷祥1*,徐展1,史皓天1,王冲1,刘海龙2   

  1. 1.南京理工大学安全科学与工程学院(应急管理学院), 江苏 南京 210094;2.南京理工大学机械工程学院, 江苏 南京 210094
  • 出版日期:2026-04-20 发布日期:2026-04-13
  • 作者简介:贾刘建(1999— ),男,江苏宿迁人,硕士研究生,主要研究方向为钢筋砼物性参数. E-mail:492787100@qq.com. *通信作者简介:卞雷祥(1985— ),男,江苏泗阳人,教授,博士生导师,博士,主要研究方向为地下目标无人化探测与识别. E-mail:lxbian@163.com
  • 基金资助:
    国家自然科学基金青年科学基金资助项目(52209133)

Prediction model of reinforced concrete resistivity based on finite element simulation

JIA Liujian1, HU Jie1, BIAN Leixiang1*, XU Zhan1, SHI Haotian1, WANG Chong1, LIU Hailong2   

  1. JIA Liujian1, HU Jie1, BIAN Leixiang1*, XU Zhan1, SHI Haotian1, WANG Chong1, LIU Hailong2(1. School of Safety Science and Engineering(School of Emergency Management), Nanjing university of science &
    technology, Nanjing 210094, Jiangsu, China;
    2. School of Mechanical Engineering, Nanjing university of Science &
    Technology, Nanjing 210094, Jiangsu, China
  • Online:2026-04-20 Published:2026-04-13

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摘要: 为从瞬变电磁信号中准确分析地下人工构筑物信息,提高反演成像准确性,需明确设定地下人工介质电阻率初值,以提取其响应。基于有限元分析研究四电极法所得钢筋混凝土电阻率规律,揭示钢筋混凝土厚度与钢筋间距对电阻率的影响;分析电极间距对测试结果的影响,提出电极优化布置方法及预估函数模型;制备不同工况钢筋混凝土进行试验,对比试验数据与预测值并分析均方误差,验证了模型优势。

关键词: 钢筋混凝土, 四电极法, 有限元分析, 混凝土电阻率, 钢筋间距, 混凝土厚度

Abstract: In order to accurately analyze the information of underground artificial structures from transient electromagnetic signals and improve the accuracy of inversion imaging, it was necessary to clearly set the initial value of underground artificial medium resistivity to extract its response. Based on the finite element analysis, the resistivity law of reinforced concrete obtained by the four-electrode method was studied, and the influence of reinforced concrete thickness and steel bar spacing on resistivity was revealed. The influence of electrode spacing on the test results was analyzed, and the optimal electrode arrangement method and prediction function model were proposed. The reinforced concrete under different working conditions was prepared and tested. The experimental data were compared with the predicted values and the mean square error was analyzed to verify the advantages of the model.

Key words: reinforced concrete, four-electrode method, finite element analysis, concrete resistivity, bar spacing, concrete thickness

中图分类号: 

  • TU375.3
[1] 鱼志鸿, 杨大勇, 章定文, 等. 深圳地铁13号线盾构渣土绿色循环利用技术[J]. 隧道与地下工程灾害防治, 2022, 4(4): 100-106. YU Zhihong, YANG Dayong, ZHANG Dingwen, et al. Application of green treatment and reuse technology of shield muck for Shenzhen Metro Line 13[J]. Hazard Control in Tunnelling and Underground Engineering, 2022, 4(4): 100-106.
[2] CUI J Q, BROERE W, LIN D. Underground space utilisation for urban renewal[J]. Tunnelling and Underground Space Technology, 2021, 108: 103726.
[3] 马洪岭, 梁孝鹏, 赵凯, 等. 山东泰安盐穴储气库地质可行性分析[J]. 隧道与地下工程灾害防治, 2022, 4(2): 19-27. MA Hongling, LIANG Xiaopeng, ZHAO Kai, et al. Geological feasibility analysis of Tai'an salt cavern gas storage in Shandong Province[J]. Hazard Control in Tunnelling and Underground Engineering, 2022, 4(2): 19-27.
[4] QIAO P Y, LIU Z B, LI Y P, et al. Research and application of comprehensive detection methods for geological structural planes in drill and blast tunnels[J]. Journal of Applied Geophysics, 2024, 228: 105449.
[5] 杨立, 夏增选, 娄文杰, 等. 山区深埋公路隧道穿越断层破碎带施工稳定性[J]. 隧道与地下工程灾害防治, 2024, 6(3): 32-42. YANG Li, XIA Zengxuan, LOU Wenjie, et al. Construction stability of deeply buried highway tunnel through fault fracture zones in mountainous areas[J]. Hazard Control in Tunnelling and Underground Engineering, 2024, 6(3): 32-42.
[6] 周雨竹, 彭子茂, 全珈颖, 等. 装配式隧道接头冲击动力响应特性[J]. 隧道与地下工程灾害防治, 2024, 6(3): 82-91. ZHOU Yuzhu, PENG Zimao, QUAN Jiaying, et al. Impact dynamic response characteristics of assembled tunnel joints[J]. Hazard Control in Tunnelling and Underground Engineering, 2024, 6(3): 82-91.
[7] BANG J S, YIM H J. Segregation evaluation of concrete pavements under excessive vibration using electrical resistivity measurement[J]. Case Studies in Construction Materials, 2023, 19: e02300.
[8] MINAGAWA H, MIYAMOTO S, KURASHIGE I, et al. Appropriate geometrical factors for four-probe method to evaluate electrical resistivity of concrete specimens[J]. Construction and Building Materials, 2023, 374: 130784.
[9] 徐国力, 朱珊, 谢向田. 钢纤维混凝土的损伤自感知试验研究[J]. 建筑结构, 2023, 53(增刊2): 1366-1370. XU Guoli, ZHU Shan, XIE Xiangtian. Experimental study on damage self-perception of steel fiber reinforced concrete[J]. Building Structure, 2023, 53(Suppl.2): 1366-1370.
[10] 徐宗南. 混凝土电阻率监测和基于电阻率的混凝土性能表征[D]. 深圳: 深圳大学, 2018: 9-12. XU Zongnan. Concrete resistivity monitoring and concrete performance characterization based on resistivity[D]. Shenzhen: Shenzhen University, 2018: 9-12.
[11] 赵卓, 曾力, 王东炜. 混凝土电阻率与氯离子扩散系数间的相关性试验[J]. 郑州大学学报(工学版), 2013, 34(6): 76-79. ZHAO Zhuo, ZENG Li, WANG Dongyi. Correlation test between concrete resistivity and chloride ion diffusion coefficient[J]. Journal of Zhengzhou University(Engineering Science), 2013, 34(6): 76-79.
[12] ROBLES K P V, GUCUNSKI N, KEE S H. Evaluation of steel corrosion-induced concrete damage using electrical resistivity measurements[J]. Construction and Building Materials, 2024, 411: 134512.
[13] DU F Y, JIN Z Q, XIONG C S, et al. Nanoindentation analysis of corrosion products and induced expansion stress in reinforced concrete exposed to marine environments[J]. Journal of Building Engineering, 2023, 78: 107753.
[14] 晏楚. 结构型纤维对智能混凝土裂缝自监测性能的研究[D]. 大连: 大连理工大学, 2022: 54-73. YAN Chu. Study on the self-monitoring performance of structural fibers on intelligent concrete cracks[D]. Dalian University of Technology, 2022: 54-73.
[15] TIAN X R, HU S W, XU Y Q, et al. Self-sensing study of stress in low-doped carbon fiber reinforced hydraulic concrete[J]. Journal of Building Engineering, 2023, 76: 107249.
[16] 张贺, 杨辉, 俞海勇. 对四电极法测试混凝土表面电阻率影响因素的研究[J]. 新型建筑材料, 2017, 44(1): 9-12. ZHANG He, YANG Hui, YU Haiyong. Research of influencing factors on concrete surface resistivity with Wenner four-probe measurement[J]. New Building Materials, 2017, 44(1): 9-12.
[17] BANG J S, YIM H J. Unbonded interlayer evaluation in freshly 3D printed concrete using electrical resistivity measurements[J]. Case Studies in Construction Materials, 2024, 21: e03913.
[18] 马衍轩, 于霞, 徐亚茜, 等. 智能纤维混凝土的力场损伤响应、监测与修复研究进展[J]. 材料导报, 2021, 35(19): 19081-19090. MA Yanxuan, YU Xia, XU Yaqian, et al. Research progress on the force field damage response, monitoring and repair of intelligent fiber reinforced concrete[J]. Materials Reports, 2021, 35(19): 19081-19090.
[19] 谷文伟, 谢智能, 张瑞琦, 等. 基于COMSOL的低温截止阀安全性仿真研究[J]. 液压气动与密封, 2024, 44(9): 73-77. GU Wenwei, XIE Zhineng, ZHANG Ruiqi, et al. Simulation study on safety of low temperature shut-off valve based on COMSOL[J]. Hydraulics Pneumatics & Seals, 2024, 44(9): 73-77.
[20] 中华人民共和国住房和城乡建设部. 普通混凝土配合比设计规程: JSJ 55—2011[S]. 北京: 中国建筑科学研究院, 2011.
[21] 中华人民共和国住房和城乡建设部.混凝土结构通用规范:GB 55008—2021[S]. 北京:中国建筑工业出版社, 2022.
[22] 朱超, 田雯菁, 许真, 等. 测试方法及试件深度对水泥体视电阻率的影响研究[J]. 水利科学与寒区工程, 2019, 2(1): 13-16. ZHU Chao, TIAN Wenjing, XU Zhen, et al. Study on the influence of test methods and test piece depth on the apparent resistivity of cement[J]. Hydro Science and Cold Zone Engineering, 2019, 2(1): 13-16.
[23] 金庆鹏, 刘璐, 吕侃骏, 等. 水泥混凝土含水率传感器设计与应用[J].电子测量与仪器学报, 2024, 38(6): 225-232. JIN Qingpeng, LIU Lu, LYU Kanjun, et al. Design and application of cement concrete moisture content sensor[J]. Journal of Electronic Measurement and Instrumen-tation, 2024, 38(6): 225-232.
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