| Citation: |
XIAO Meng,JU Feng,HE Zequan,et al. Induced eddy currents characteristics of coal gangue-based functional concrete in compression process[J]. Coal Science and Technology,2025,53(6):292−304. DOI: 10.12438/cst.2025-0264
|
Coal gangue-based cemented structures (CGCS) have been widely used in underground engineering. Due to the complex environment and limited space, there is still no effective method to monitor structural health in under-ground engineering. Adding conductive additives in coal gangue-based cemented materials, its conductive proper-ties can be enhanced. The changes of electrical parameters during loading can be detected by eddy current testing method, and then the stress state of CGCS can be calculated. This method can overcome the drawbacks about installation and maintenance induced by embedded sensor. The eddy current testing platform based on STM32 microcontroller was designed, .and the CGCS specimens containing steel fibers were prepared. The mechanical and eddy current inducting tests were conducted, and the signal changes of specimens with different steel fiber content during uniaxial compress, cyclic loading were analyzed. The results show that the change in stages of eddy current induction signal has a strong consistency with that of stress-strain curves. The fractional changes in resistivity (FCR) of specimens under uniaxial compressive loading can be divided into 3 stages, including initial constancy, rapid decline, and then slow decline. These 3 stages correspond to the compaction, elastic and after-peak stages in stress-strain curves. In cyclic loading test, the voltage difference changes of specimens with 0.8% and 1.2% steel fiber contents were consistent to the cyclic compressive loading, and the cyclic changes of “steel fibers contact – increase of conductive paths – steel fibers separation – decrease of conductive paths” were shown. Higher steel fibers content cannot further improve the sensitivity of the voltage difference to cyclic loading. With the SF content of specimens in-creasing from 0.4% to 2.0%, the gauge factor increases first and then decreases, and the linearity of eddy current induction signal decreases linearly. The CGCS specimens with 0.8% SF content have highest gangue factor during uniaxial and cyclic compressive loading test.
| [1] |
杨科,赵新元,何祥,等. 多源煤基固废绿色充填基础理论与技术体系[J]. 煤炭学报,2022,47(12):4201−4216.
YANG Ke,ZHAO Xinyuan,HE Xiang,et al. Basic theory and key technology of multi-source coal-based solid waste for green backfilling[J]. Journal of China Coal Society,2022,47(12):4201−4216.
|
| [2] |
张吉雄,张强,周楠,等. 煤基固废充填开采技术研究进展与展望[J]. 煤炭学报,2022,47(12):4167−4181.
ZHANG Jixiong,ZHANG Qiang,ZHOU Nan,et al. Research progress and prospect of coal based solid waste backfilling mining technology[J]. Journal of China Coal Society,2022,47(12):4167−4181.
|
| [3] |
冯国瑞,杜献杰,郭育霞,等. 结构充填开采基础理论与地下空间利用构想[J]. 煤炭学报,2019,44(1):74−84.
FENG Guorui,DU Xianjie,GUO Yuxia,et al. Basic theory of constructional backfill mining and the underground space utilization concept[J]. Journal of China Coal Society,2019,44(1):74−84.
|
| [4] |
冯国瑞,解文硕,郭育霞,等. 早期受载对矸石胶结充填体力学特性及损伤破坏的影响[J]. 岩石力学与工程学报,2022,41(4):775−784.
FENG Guorui,XIE Wenshuo,GUO Yuxia,et al. Effect of early load on mechanical properties and damage of cemented gangue backfill[J]. Chinese Journal of Rock Mechanics and Engineering,2022,41(4):775−784.
|
| [5] |
郭育霞,赵永辉,冯国瑞,等. 矸石胶结充填体单轴压缩损伤破坏尺寸效应研究[J]. 岩石力学与工程学报,2021,40(12):2434−2444.
GUO Yuxia,ZHAO Yonghui,FENG Guorui,et al. Study on damage size effect of cemented gangue backfill body under uniaxial compression[J]. Chinese Journal of Rock Mechanics and Engineering,2021,40(12):2434−2444.
|
| [6] |
程爱平,付子祥,邓代强,等. 高低应力水平下胶结充填体蠕变特征及分数阶本构模型[J]. 中国矿业大学学报,2023,52(2):276−285,299.
CHENG Aiping,FU Zixiang,DENG Daiqiang,et al. Creep characteristics and fractional order constitutive model of cemented backfill under high and low stress levels[J]. Journal of China University of Mining & Technology,2023,52(2):276−285,299.
|
| [7] |
刘炜震,郭忠平,黄万朋,等. 不同温度养护后胶结充填体三轴卸围压力学特性试验研究[J]. 岩石力学与工程学报,2022,41(11):2268−2282.
LIU Weizhen,GUO Zhongping,HUANG Wanpeng,et al. Experimental study on mechanical characteristics of cemented backfill under triaxial unloading confining pressure after cured at different temperatures[J]. Chinese Journal of Rock Mechanics and Engineering,2022,41(11):2268−2282.
|
| [8] |
XIAO M,JU F,HE Z Q. Research on shotcrete in mine using non-activated waste coal gangue aggregate[J]. Journal of Cleaner Production,2020,259:120810. doi: 10.1016/j.jclepro.2020.120810
|
| [9] |
刘浪,罗屹骁,朱梦博,等. 建筑物下特厚煤层镁渣基全固废连采连充开采技术与实践[J]. 煤炭科学技术,2024,52(4):83−92.
LIU Lang,LUO Yixiao,ZHU Mengbo,et al. Mining technology and practice of full-solid waste cemented backfilling in narrow strip of extra-thick coal seam under buildings[J]. Coal Science and Technology,2024,52(4):83−92.
|
| [10] |
张自政,柏建彪,王襄禹,等. 我国沿空留巷围岩控制技术研究进展与展望[J]. 煤炭学报,2023,48(11):3979−4000.
ZHANG Zizheng,BAI Jianbiao,WANG Xiangyu,et al. Review and development of surrounding rock control technology for gob-side entry retaining in China[J]. Journal of China Coal Society,2023,48(11):3979−4000.
|
| [11] |
ZHAO S Y,FAN S L,YANG J,et al. Numerical and experimental investigation of electro-mechanical impedance based concrete quantitative damage assessment[J]. Smart Materials and Structures,2020,29(5):055025. doi: 10.1088/1361-665X/ab58e9
|
| [12] |
魏晓明,郭利杰,周小龙,等. 高阶段胶结充填体全时序应力演化规律及预测模型研究[J]. 岩土力学,2020,41(11):3613−3620.
WEI Xiaoming,GUO Lijie,ZHOU Xiaolong,et al. Full sequence stress evolution law and prediction model of high stage cemented backfill[J]. Rock and Soil Mechanics,2020,41(11):3613−3620.
|
| [13] |
CHUNG D D L. Cement reinforced with short carbon fibers:A multifunctional material[J]. Composites Part B:Engineering,2000,31(6-7):511−526. doi: 10.1016/S1359-8368(99)00071-2
|
| [14] |
AZHARI F,BANTHIA N. Cement-based sensors with carbon fibers and carbon nanotubes for piezoresistive sensing[J]. Cement and Concrete Composites,2012,34(7):866−873. doi: 10.1016/j.cemconcomp.2012.04.007
|
| [15] |
HAN B G,GUAN X C,OU J P. Electrode design,measuring method and data acquisition system of carbon fiber cement paste piezoresistive sensors[J]. Sensors and Actuators A:Physical,2007,135(2):360−369. doi: 10.1016/j.sna.2006.08.003
|
| [16] |
LEE S Y,LE H V,KIM D J. Self-stress sensing smart concrete containing fine steel slag aggregates and steel fibers under high compressive stress[J]. Construction and Building Materials,2019,220:149−160. doi: 10.1016/j.conbuildmat.2019.05.197
|
| [17] |
丁思齐,韩宝国,欧进萍. 本征自感知混凝土及其智能结构[J]. 工程力学,2022,39(3):1−10.
DING Siqi,HAN Baoguo,OU Jinping. Intrinsic self-sensing concrete for smart structures[J]. Engineering Mechanics,2022,39(3):1−10.
|
| [18] |
孙怀凤,李术才,苏茂鑫,等. 基于场路耦合的隧道瞬变电磁超前探测正演与工程应用[J]. 岩石力学与工程学报,2011,30(S1):3362−3369.
SUN Huaifeng,LI Shucai,SU Maoxin,et al. Forward of transient electromagnetic method for geological prediction in tunnels based on field-circuit coupling and its engineering application[J]. Chinese Journal of Rock Mechanics and Engineering,2011,30(S1):3362−3369.
|
| [19] |
HAN B G,DING S Q,YU X. Intrinsic self-sensing concrete and structures:A review[J]. Measurement,2015,59:110−128. doi: 10.1016/j.measurement.2014.09.048
|
| [20] |
李肖寒. 基于高频涡流的热障涂层厚度检测方法研究[D]. 徐州:中国矿业大学,2020.
LI Xiaohan. Research on thermal barrier coating thickness measurement based on high frequency eddy current[D]. Xuzhou:China University of Mining and Technology,2020.
|
| [21] |
TIAN Z,LI Y C,ZHENG J J,et al. A state-of-the-art on self-sensing concrete:Materials,fabrication and properties[J]. Composites Part B:Engineering,2019,177:107437. doi: 10.1016/j.compositesb.2019.107437
|
| [22] |
DINESH A,SUJI D,PICHUMANI M. Electro-mechanical investigations of steel fiber reinforced self-sensing cement composite and their implications for real-time structural health monitoring[J]. Journal of Building Engineering,2022,51:104343. doi: 10.1016/j.jobe.2022.104343
|
| [23] |
DEMIRCILIOĞLU E,TEOMETE E,SCHLANGEN E,et al. Temperature and moisture effects on electrical resistance and strain sensitivity of smart concrete[J]. Construction and Building Materials,2019,224:420−427. doi: 10.1016/j.conbuildmat.2019.07.091
|
| [24] |
SHI Z M,LI J T,ZHAO Y. Study on damage evolution and constitutive model of sandstone under the coupled effects of wetting-drying cycles and cyclic loading[J]. Engineering Fracture Mechanics,2021,253:107883. doi: 10.1016/j.engfracmech.2021.107883
|
| [25] |
LE H V,KIM D J. Detecting crack and damage location in self-sensing fiber reinforced cementitious composites[J]. Construction and Building Materials,2020,240:117973. doi: 10.1016/j.conbuildmat.2019.117973
|
| [26] |
ALLAM H,DUPLAN F,AMZIANE S,et al. About the self-sensing behavior of smart concrete and its interaction with the carbon fiber percolation status,sand connectivity status and grain size distribution[J]. Construction and Building Materials,2022,324:126609. doi: 10.1016/j.conbuildmat.2022.126609
|
| [27] |
LI X P,LI M. Multifunctional self-sensing and ductile cementitious materials[J]. Cement and Concrete Research,2019,123:105714. doi: 10.1016/j.cemconres.2019.03.008
|
| [28] |
HWANG J P,KIM M,ANN K Y. Porosity generation arising from steel fibre in concrete[J]. Construction and Building Materials,2015,94:433−436. doi: 10.1016/j.conbuildmat.2015.07.044
|
| [29] |
DEMIRCILIOGLU E,TEOMETE E,OZBULUT O E. Strain sensitivity of steel-fiber-reinforced industrial smart concrete[J]. Journal of Intelligent Material Systems and Structures,2020,31(1):127−136. doi: 10.1177/1045389X19888722
|
| [1] | JIN Jiaxu, GU Xiaowei, LI Mingxu, QIN Zhifa, LIU Tao, WU Pengfei, ZUO Shenghao. Effect of aggregate surface strengthening on compressive damage of pre-placed coal gangue cemented backfill[J]. COAL SCIENCE AND TECHNOLOGY, 2025, 53(6): 277-291. DOI: 10.12438/cst.2025-0342 |
| [2] | SONG Qiang, YANG Yuxin, XU Shipeng, GAO Shujun, LIU Jie, BAO Jiuwen, XUE Shanbin. Research progress in performance and enhancement of coal gangue concrete[J]. COAL SCIENCE AND TECHNOLOGY, 2025, 53(2): 407-425. DOI: 10.12438/cst.2024-1070 |
| [3] | ZHANG Qiang, YANG Kang, CAO Jinming, BAI Yu, DENG Panbo, YANG Zi. Solid intelligent backfill coal mining method with video ai algorithm analysis in coal mine[J]. COAL SCIENCE AND TECHNOLOGY, 2024, 52(11): 163-173. DOI: 10.12438/cst.2024-0955 |
| [4] | WANG Yuting, ZHANG Hong. Research on the axial force-slip characteristics of permanent magnetic eddy current Frictional torque limiter[J]. COAL SCIENCE AND TECHNOLOGY, 2023, 51(4): 198-208. DOI: 10.13199/j.cnki.cst.2022-1352 |
| [5] | ZHANG Zhanbo, LIU Hui, HOU Shilin, CHEN Fei. Experimental study on mechanical properties of superfine sand and coal gangue concrete[J]. COAL SCIENCE AND TECHNOLOGY, 2022, 50(9): 57-66. |
| [6] | ZHANG Ziyue, FU Shichen, LIU Chao, LI Yongze, LAN Yu, WU Miao. Position detection system of shearer based on combined measurement of multiple sensing modes[J]. COAL SCIENCE AND TECHNOLOGY, 2021, 49(11): 218-224. |
| [7] | HUANG Yucheng, DUAN Xiaobo, WANG Yumin, LUO Haotian, HAO Yuxin. Research on non-full pipeline flow transportation and prevention method of coal gangue cemented backfill[J]. COAL SCIENCE AND TECHNOLOGY, 2020, 48(9): 117-122. |
| [8] | GUO Yongcun, HE Jiarui, LI Chenglin. Research on starting characteristics of long distance belt conveyor based on permanent magnet eddy current transmission[J]. COAL SCIENCE AND TECHNOLOGY, 2020, 48(1). |
| [9] | LIU Zhenzhen, TIAN Zijian, WANG Wenqing, XU Zhiming, LIU Ting, HUANG Lei, ZHANG Xiangyang. Mine distributed target location method based on TOA compressed sensing[J]. COAL SCIENCE AND TECHNOLOGY, 2018, (9). |
| [10] | Zhao Xiaohu Deng Yuanfang Mu Dengcong, . Applied study on compressed sensing technology to mine internet of things[J]. COAL SCIENCE AND TECHNOLOGY, 2016, (7). |
Supported by: Beijing Renhe Information Technology Co., Ltd. 
DownLoad: