|
|
|
| Evolution of mining-induced stress and strata control in underground coal mines |
| KANG Hongpu1,2,3,GAO Fuqiang1,2,3 |
(1. Coal Mining Research Institute,China Coal Technology and Engineering Group Co. Ltd.,Beijing 100013,China;
2. Coal Mining Branch,China Coal Research Institute,Beijing 100013,China;3. State Key Laboratory of Intelligent Coal Mining and Strata Control,Beijing 100013,China) |
|
|
|
|
Abstract Stress is the fundamental driving force causing deformation and damage of the surrounding rock in mining engineering underground spaces. Widespread and highly concentrated stress is a notable feature of mining-induced stress in underground coal mines. The stress field underground in coal mines includes the in-situ stress field,mining-induced stress field,and support stress field,together forming the comprehensive underground stress field. This article discusses the stress evolution characteristics of coal mine surrounding rock and the theory and technology of surrounding rock control,with stress as the main focus. Regarding in-situ stress,based on extensive field measurements of in-situ stress,the distribution characteristics and influencing factors of the underground stress field in Chinese coal mines were detailedly analyzed. Concerning mining-induced stress,a combination of theoretical analysis,numerical simulation,physical simulation,and field monitoring methods were employed. The evolution process of stress in the excavation face and roadway surrounding rock was comprehensively studied from multiple perspectives,and the mining-induced stress evolution characteristics and main influencing factors around the coal mining face were analyzed. In terms of support stress,a series of roadway support test and simulation experiment platforms were independently developed. Systematic tests were conducted on rock bolts and roadway surface protective components under various complex load conditions,and their mechanical response characteristics and failure mechanisms were evaluated. The distribution characteristics and evolution laws of the support stress fields generated by various support methods,both in support itself and in the surrounding rock,were deeply studied. Based on the studies of in-situ stress,mining-induced stress,and support stress,the control mechanisms,design methods,support reinforcement materials,and control techniques of rock surface support,anchoring,modification,unloading,and combined methods were analyzed. Application examples emphasized hydraulic fracturing unloading technology and the synergistic control technology of support+modification+destressing. Underground tests and applications showed that the surrounding rock control technology based on mining-induced stress evolution significantly improved the stability and safety level of the roadway surrounding rock,achieving good rock control effects. Finally,the challenges in the study of underground stress fields in coal mines and the control of roadway surrounding rock were analyzed,and the future trends in surrounding rock stress testing and analysis,and the theory and technology of surrounding rock control were discussed.
|
|
|
|
|
|
[1] 康红普. 煤矿井下应力场类型及相互作用分析[J]. 煤炭学报,2008,33(12):1 329–1 335.(KANG Hongpu. Analysis on types and interaction of stress fields in underground coal mines[J]. Journal of China Coal Society,2008,33(12):1 329–1 335.(in Chinese))
[2] 康红普,林 健. 我国巷道围岩地质力学测试技术新进展[J]. 煤炭科学技术,2001,29(7):27–30.(KANG Hongpu,LIN Jian. Newdevelopment in geomechanics measurement and test technology of mine roadway surrounding rock[J]. Coal Science and Technology,2001,29(7):27–30.(in Chinese))
[3] 康红普,林 健,张 晓. 深部矿井地应力测量方法研究与应用[J].岩石力学与工程学报,2007,26(5):929–933.(KANG Hongpu,LIN Jian,ZHANG Xiao. Research and application of in-situ stress measurement in deep mines[J]. Chinese Journal of Rock Mechanics and Engineering,2007,26(5):929–933.(in Chinese))
[4] 康红普,林 健,颜立新,等. 山西煤矿区井下地应力场分布特征研究[J]. 地球物理学报,2009,52(7):1 782–1 792.(KANG Hongpu,LIN Jian,YAN Lixin,et al. Study on characteristics of underground in-situ stress distribution in Shanxi coal mining fields[J]. Chinese Journal of Geophysics,2009,52(7):1 782–1 792.(in Chinese))
[5] 康红普,姜铁明,张 晓,等. 晋城矿区地应力场研究及应用[J]. 岩石力学与工程学报,2009,28(1):1–8.(KANG Hongpu,JIANG Tieming,ZHANG Xiao,et al. Research on in-situ stress field in Jincheng coal mining area and its application[J]. Chinese Journal of Rock Mechanics and Engineering,2009,28(1):1–8.(in Chinese))
[6] KANG H P,ZHANG X,SI L P,et al. In-situ stress measurements and stress distribution characteristics in underground coal mines in China[J]. Engineering Geology,2010,116(3/4):333–345.
[7] 康红普,林 健,张 晓,等. 潞安矿区井下地应力测量及分布规律研究[J]. 岩土力学,2010,31(3):827–831.(KANG Hongpu,LIN Jian,ZHANG Xiao,et al. In-situ stress measurements and distribution laws in Lu?an underground coal mines[J]. Rock and Soil Mechanics,2010,31(3):827–831.(in Chinese))
[8] 康红普,吴志刚,高富强,等. 煤矿井下地质构造对地应力分布的影响[J]. 岩石力学与工程学报,2012,31(增1):2 674–2 680.(KANG Hongpu,WU Zhigang,GAO Fuqiang,et al. Effect of geological structures on in-situ stress distribution in underground coal mines[J]. Chinese Journal of Rock Mechanics and Engineering,2012,31(Supp.1):2 674–2 680.(in Chinese))
[9] 蔡美峰,郭奇峰,李 远,等. 平顶山十矿地应力测量及其应用[J].北京科技大学学报,2013,35(11):1 399–1 406.(CAI Meifeng,GUO Qifeng,LI Yuan,et al. In-situ stress measurement and its application in the 10th mine of Pingdingshan coal group[J]. Journal of University of Science and Technology Beijing,2013,35(11):1 399–1 406.(in Chinese))
[10] 康红普,伊丙鼎,高富强,等. 中国煤矿井下地应力数据库及地应力分布规律[J]. 煤炭学报,2019,44(1):23–33.(KANG Hongpu,YI Bingding,GAO Fuqiang,et al. Database and characteristics of underground in-situ stress distribution in Chinese coal mines[J]. Journal of China Coal Society,2019,44(1):23–33.(in Chinese))
[11] SJÖBERG J,CHRISTIANSSON R,HUDSON J A. ISRM suggested methods for rock stress estimation—Part 2:overcoring methods[J]. International Journal of Rock Mechanics and Mining Sciences,2003,40(7/8):999–1 010.
[12] HAIMSON B C,CORNET F H. ISRM suggested methods for rock stress estimation—Part 3:hydraulic fracturing(HF) and/or hydraulic testing of pre-existing fractures(HTPF)[J]. International Journal of Rock Mechanics and Mining Sciences,2003,40(7/8):1 011–1 020.
[13] GAO F Q,STEAD D,KANG H P. Numerical simulation of squeezing failure in a coal mine roadway due to mining-induced stresses[J]. Rock Mechanics and Rock Engineering,2015,48(4),:1 635–1 645.
[14] PENG S S. Coal mine ground control[M]. New York:Wiley,1986:336–345.
[15] 王家臣,王兆会,杨 杰,等. 千米深井超长工作面采动应力旋转特征及应用[J]. 煤炭学报,2020,45(3):876–888.(WANG Jiachen,WANG Zhaohui,YANG Jie,et al. Mining-induced stress rotation and its application in longwall face with large length in kilometer deep coalmine[J]. Journal of China Coal Society,2020,45(3):876–888.(in Chinese))
[16] NING S,ZHU W,XIE J,et al. Influence of stress distribution in coal seams of non-uniform extremely thick key stratum and disaster-causing mechanisms[J]. Scientific Reports,2022,12:14465.
[17] 窦林名,何学秋. 煤岩特性对应力分布影响的实验研究[J]. 辽宁工程技术大学学报:自然科学版,2001,20(4):484–486.(DOU Linming,HE Xueqiu. Coal and rock mechanic features influencing the stress distribution[J]. Journal of Liaoning Technical University:Natural Science,2001,20(4):484–486.(in Chinese))
[18] 王朋飞,冯国瑞,赵景礼,等. 长壁采空区对采动煤岩应力分布规律的影响研究[J]. 岩土工程学报,2018,40(7):1 237–1 246.(WANG Pengfei,FENG Guorui,ZHAO Jingli,et al. Effect of longwall gob on distribution of mining-induced stress[J]. Chinese Journal of Geotechnical Engineering,2018,40(7):1 237–1 246.(in Chinese))
[19] 武泉森,蒋力帅,孔 朋,等. 断层煤柱及倾角对采动应力及能量分布的影响特征[J]. 采矿与安全工程学报,2018,35(4):708–716.(WU Quansen,JIANG Lishuai,KONG Peng,et al. Effects characterristics of fault pillar and its dip angle on mining-induced stress and energy distribution[J]. Journal of Mining and Safety Engineering,2018,35(4):708–716.(in Chinese))
[20] XIE J L,XU J L. Effect of key stratum on the mining abutment pressure of a coal seam[J]. Geosciences Journal,2017,21(2):267–276.
[21] ZHU Z,WU Y,LIANG Z. Mining-induced stress and ground pressure behavior characteristics in mining a thick coal seam with hard roofs[J]. Frontiers in Earth Science,2022,10:843191
[22] LU J,JIANG C,JIN Z,et al. Three-dimensional physical model experiment of mining-induced deformation and failure characteristics of roof and floor in deep underground coal seams[J]. Process Safety and Environmental Protection,2021,150:400–415.
[23] HUO Y,SONG X,SUN Z,et al. Evolution of mining-induced stress in fully mechanized top-coal caving under high horizontal stress[J]. Energy Science and Engineering,2020,8(6):2 203–2 215.
[24] ZHOU K,DOU L,SONG S,et al. Experimental study on the mechanical behavior of coal samples during water saturation[J]. ACS Omega,2021,6(49):33 822–33 836.
[25] 汪北方,武 力,张 晶,等. 煤矿地下水库煤岩变形特性的尺寸效应试验[J]. 采矿与安全工程学报,2021,38(4):810–818.(WANG Beifang,WU Li,ZHANG Jing,et al. Experiment on size effect for deformation characteristics of rock and coal in coal mine underground reservoir[J]. Journal of Mining and Safety Engineering,2021,38(4):810–818.(in Chinese))
[26] 陈光波,张俊文,李 谭,等. 水岩作用下煤岩组合体力学特性损伤劣化机制[J]. 煤炭学报,2021,46(增2):701–712.(CHEN Guangbo,ZHANG Junwen,LI Tan,et al. Timeliness of damage and deterioration of mechanical properties of coal-rock combined body under water-rock interaction[J]. Journal of China Coal Society,2021,46(Supp.2):701–712.(in Chinese))
[27] 康红普. 软岩遇水膨胀引起的巷道底臌[J]. 淮南矿业学院学报,1993,13(1):30–36.(KANG Hongpu. Opening floor heave caused by swelling of soft rocks meeting with water[J]. Journal of Huainan Mining Institute,1993,13(1):30–36.(in Chinese))
[28] 司荣军,王春秋,谭云亮. 采场支承压力分布规律的数值模拟研究[J]. 岩土力学,2007,28(2):351–354.(SI Rongjun,WANG Chunqiu,TAN Yunliang. Numerical simulation of abutment pressure distribution law of working faces[J]. Rock and Soil Mechanics,2007,28(2):351–354.(in Chinese))
[29] 蒋力帅,武泉森,李小裕,等. 采动应力与采空区压实承载耦合分析方法研究[J]. 煤炭学报,2017,42(8):1 951–1 959.(JIANG Lishuai,WU Quansen,LI Xiaoyu,et al. Numerical simulation on coupling method between mining-induced stress and goaf compression[J]. Journal of China Coal Society,2017,42(8):1 951–1 959.(in Chinese))
[30] 康红普,姜铁明,高富强. 预应力在锚杆支护中的作用[J]. 煤炭学报,2007,32(7):680–685.(KANG Hongpu,JIANG Tieming,GAO Fuqiang. Effect of pretensioned stress to rock bolting[J]. Journal of China Coal Society,2007,32(7):680–685.(in Chinese))
[31] 康红普,姜铁明,高富强. 预应力锚杆支护参数的设计[J]. 煤炭学报,2008,33(7):721–726.(KANG Hongpu,JIANG Tieming,GAO Fuqiang. Design for pretensioned rock bolting parameters[J]. Journal of China Coal Society,2008,33(7):721–726.(in Chinese))
[32] 康红普,王金华,林 健. 高预应力强力支护系统及其在深部巷道中的应用[J]. 煤炭学报,2007,32(12):1 233–1 238.(KANG Hongpu,WANG Jinhua,LIN Jian. High pretensioned stress and intensive bolting system and its application in deep roadways[J]. Journal of China Coal Society,2007,32(12):1 233–1 238.(in Chinese))
[33] 康红普,王金华. 煤巷锚杆支护理论与成套技术[M]. 北京:煤炭工业出版社,2007:122–130.(KANG Hongpu,WANG Jinhua. Rock bolting theory and complete technology for coal roadways[M]. Beijing:Coal Industry Publishing House,2007:122–130.(in Chinese))
[34] 康红普. 煤岩体地质力学原位测试及在围岩控制中的应用[M]. 北京:科学出版社,2013:295–300.(KANG Hongpu. In-situ geomechanics measurements for coal rock masses and their application on strata control[M]. Beijing:Science Press,2013:295–300.(in Chinese))
[35] 周 钢,李玉寿,吴振业. 大屯矿区地应力测量与特征分析[J]. 煤炭学报,2005,30(3):314–318.(ZHOU Gang,LI Yushou,WU Zhenye. Measurement of crustal stress and analysis of characteristics in Datun mining area[J]. Journal of China Coal Society,2005,30(3):314–318.(in Chinese))
[36] 蔡美峰,陈长臻,彭 华,等. 万福煤矿深部水压致裂地应力测量[J]. 岩石力学与工程学报,2006,25(5):1 069–1 074.(CAI Meifeng,CHEN Changzhen,PENG Hua,et al. In-situ stress measurement by hydraulic fracturing technique in deep position of Wanfu coal mine[J]. Chinese Journal of Rock Mechanics and Engineering,2006,25(5):1 069–1 074.(in Chinese))
[37] 王连国,陆银龙,杨新华,等. 霍州矿区地应力分布规律实测研究[J]. 岩石力学与工程学报,2010,29(1):2 768–2 773.(WANG Lianguo,LU Yinlong,YANG Xinhua,et al. Study of distribution characteristics of in-situ stresses for Huozhou mining area[J]. Chinese Journal of Rock Mechanics and Engineering,2010,29(1):2 768–2 773.(in Chinese))
[38] 张国锋,朱 伟,赵 培. 徐州矿区深部地应力测量及区域构造作用分析[J]. 岩土工程学报,2012,34(12):2 318–2 324.(ZHANG Guofeng,ZHU Wei,ZHAO Pei. In-situ stress measurements and analysis of action of geological structures of deep coal mines in Xuzhou[J]. Chinese Journal of Geotechnical Engineering,2012,34(12):2 318–2 324.(in Chinese))
[39] BROWN E T,HOEK E. Trends in relationships between measured in-situ stresses and depth[J]. International Journal of Rock Mechanics and Mining Sciences and Geomechanics Abstract,1978,15(4):211–215.
[40] 赵德安,陈志敏,蔡小林,等. 中国地应力场分布规律统计分析[J]. 岩石力学与工程学报,2007,26(6):1 265–1 271.(ZHAO Dean,CHEN Zhimin,CAI Xiaolin,et al. Analysis of distribution rule of geostress in China[J]. Chinese Journal of Rock Mechanics and Engineering,2007,26(6):1 265–1 271.(in Chinese))
[41] 朱焕春,陶振宇. 不同岩石中地应力分布[J]. 地震学报,1994,16(1):49–63.(ZHU Huanchun,TAO Zhenyu. Geostress distributions in different rocks[J]. Acta Seismologic Sinica,1994,16(1):49–63.(in Chinese))
[42] 王胜本,张 晓. 煤矿井下地质构造与地应力的关系[J]. 煤炭学报,2008,33(7):738–742.(WANG Shengben,ZHANG Xiao. Relation between geological structures and in-situ stresses in underground coal mines[J]. Journal of China Coal Society,2008,33(7):738–742.(in Chinese))
[43] 陈志敏. 不同岩性侧压比随深度变化规律探讨[J]. 西部探矿工程,2006,(6):99–101.(CHEN Zhimin. Discussion on change law of different lithology?s side press ratio with depths[J]. West-China Exploration Engineering,2006,(6):99–101.(in Chinese))
[44] SHEOREY P R. A theory for in-situ stresses in isotropic and transversely isotropic rock[J]. International Journal of Rock Mechanics and Mining Sciences and Geomechanics Abstracts,1994,31(1):23–34.
[45] SHEOREY P R,MOHAN G M,SINHA A. Influence of elastic constants on the horizontal in situ stress[J]. International Journal of Rock Mechanics and Mining Sciences,2001,38(8):1 211–1 216.
[46] 李化敏,周 英,苏承东,等. 砚北煤矿地应力测量及其特征分析[J]. 岩石力学与工程学报,2004,23(23):3 938–3 942.(LI Huamin,ZHOU Ying,SU Chengdong,et al. Measurement and characteristics analysis of in-situ stresses of Yanbei coal mine[J]. Chinese Journal of Rock Mechanics and Engineering,2004,23(23):3 938–3 942.(in Chinese))
[47] OBERT L,DUVALL W I. Rock mechanics and the design of structure in rock[M]. New York:John Wiley and Sons,1967:20–32.
[48] JAEGER J C,GOOK N G W. Fundamentals of rock mechanics[M]. London:Chapman and Hall,1978:12–20.
[49] 钱鸣高,石平五,许家林. 矿山压力与岩层控制[M]. 徐州:中国矿业大学出版社,2010:48–57.(QIAN Minggao,SHI Pingwu,XU Jialin. Ground pressure and strata control[M]. Xuzhou:China University of Mining and Technology Press,2010:48–57.(in Chinese))
[50] 陈子荫. 围岩力学分析中的解析方法[M]. 北京:煤炭工业出版社,1994:49–55.(CHEN Ziyin. Analytic method around rock roadway[M]. Beijing:Coal Industry Publishing House,1994:49–55.(in Chinese))
[51] 于学馥,郑颖人,刘怀恒,等. 地下工程围岩稳定分析[M]. 北京:煤炭工业出版社,1983:62–71.(YU Xuefu,ZHENG Yingren,LIU Huaiheng,et al. Stability analysis of surrounding rock in underground engineering[M]. Beijing:China Coal Industry Publishing House,1983:62–71.(in Chinese))
[52] 康红普,颜立新,郭相平,等. 回采工作面多巷布置留巷围岩变形特征与支护技术[J]. 岩石力学与工程学报,2012,31(10):2 022–2 036.(KANG Hongpu,YAN Lixin,GUO Xiangping,et al. Characteristics of surrounding rock deformation and reinforcement technology of retained entry in working face with multi-entry layout[J]. Chinese Journal of Rock Mechanics and Engineering,2012,31(10):2 022–2 036.(in Chinese))
[53] 张路青,杨志法,吕爱钟. 两平行的任意形状洞室围岩位移场解析法研究及其在位移反分析中的应用[J]. 岩石力学与工程学报,2000,19(5):584–589.(ZHANG Luqing,YANG Zhifa,LV Aizhong. Analysis study on displacement field of surrounding rocks of two parallel tunnels with arbitrary shapes and its application to back-analysis of displacement[J]. Chinese Journal of Rock Mechanics and Engineering,2000,19(5):584–589.(in Chinese))
[54] 朱大勇,蔡永祥. 含多孔洞无限平面体弹性应力场解析逼近方法[J]. 岩石力学与工程学报,2016,35(12):2 583–2 592.(ZHU Dayong,CAI Yongxiang. Approaching analytical solution to elastic stress field of an infinite plane containing multiple holes[J]. Chinese Journal of Rock Mechanics and Engineering,2016,35(12):2 583–2 592.(in Chinese))
[55] 康红普. 深部煤矿应力分布特征及巷道围岩控制技术[J]. 煤炭科学技术,2013,41(9):12–17.(KANG Hongpu. Stress distribution characteristics and strata control technology for roadways in deep coal mines[J]. Coal Science and Technology,2013,41(9):12–17.(in Chinese))
[56] 康红普,姜鹏飞,高富强,等. 掘进工作面围岩稳定性分析及快速成巷技术途径[J]. 煤炭学报,2021,46(7):2 023–2 045.(KANG Hongpu,JIANG Pengfei,GAO Fuqiang,et al. Analysis on stability of rock surrounding heading faces and technical approaches for rapid heading[J]. Journal of China Coal Society,2021,46(7):2 023–2 045. (in Chinese))
[57] 吴 乐. 阳泉矿区回采工作面双巷布置留巷采动应力演化规律研究[硕士学位论文][D]. 北京:煤炭科学研究总院,2018.(WU Le. Study on mine-induced stress of reused roadway in longwall mining with two gateroad layout in Yangquan mining area[M. S. Thesis][D]. Beijing:China Coal Research Institute,2018.(in Chinese))
[58] 谢广祥,杨 科,刘全明. 综放面倾向煤柱支承压力分布规律研究[J]. 岩石力学与工程学报,2006,25(3):545–549.(XIE Guangxiang,YANG Ke,LIU Quanming. Study on distribution laws of stress in inclined coal pillar for fully mechanized top-coal caving face[J]. Chinese Journal of Rock Mechanics and Engineering,2006,25(3):545–549.(in Chinese))
[59] 谢广祥,杨 科,常聚才,等. 综放采场围岩支承压力分布及动力灾害的层厚效应[J]. 煤炭学报,2006,31(6):731–735.(XIE Guangxiang,YANG Ke,CHANG Jucai. Surrounding rock abutment pressure distribution and thickness effect of dynamic catastrophic in fully mechanized sublevel mining stope[J]. Journal of China Coal Society,2006,31(6):731–735.(in Chinese))
[60] 伍永平,王红伟,解盘石. 大倾角煤层长壁开采围岩宏观应力拱壳分析[J].煤炭学报,2012,37(4):559–564.(WU Yongping,WANG Hongwei,XIE Panshi. Analysis of surrounding rock macro stress arch-shell of longwall face in steeply dipping seam mining[J]. Journal of China Coal Society,2012,37(4):559–564.(in Chinese))
[61] PENG S S. Longwall mining[M]. Boca Raton:CRC Press,2019:135–142.
[62] 王家臣. 基于采动岩层控制的煤炭科学开采[J]. 采矿与岩层控制工程学报,2019,1(2):40–47.(WANG Jiachen. Sustainable coal mining based on mining ground control[J]. Journal of Mining and Strata Control Enineering,2019,1(2):40–47.(in Chinese))
[63] KANG H P,WU L,GAO F Q,et al. Field study on the load transfer mechanics associated with longwall coal retreat mining[J]. International Journal of Rock Mechanics and Mining Sciences,2019,124:104141.
[64] 程利兴,姜鹏飞,杨建威,等. 深井孤岛工作面巷道围岩采动应力分区演化特征[J]. 岩土力学,2020,41(12):4 078–4 086.(CHENG Lixing,JIANG Pengfei,YANG Jianwei,et al. Evolution characteristics of mining?induced stress partition of roadway surrounding rock on working face of deep island[J]. Rock and Soil Mechanics,2020,41(12):4 078–4 086.(in Chinese))
[65] KANG H P,LOU J F,GAO F Q,et al. A physical and numerical investigation of sudden massive roof collapse during longwall coal retreat mining[J]. International Journal of Coal Geology,2018,188:25–36.
[66] 娄金福. 大采高工作面采场矿压显现特征的大型模型试验研究[博士学位论文][D]. 北京:中国矿业大学(北京),2019.(LOU Jinfu. Research on strata behavior characteristics at large–height working face with large–scale physical modeling[Ph. D. Thesis][D]. Beijing:China University of Mining and Technology(Beijing),2019.(in Chinese))
[67] 康红普. 煤矿巷道支护与加固材料的发展及展望[J]. 煤炭科学技术,2021,49(4):1–11.(KANG Hongpu. Development and prospects of support and reinforcement materials for coal mine roadways[J]. Coal Science and Technology,2021,49(4):1–11.(in Chinese))
[68] 康红普,范明建,高富强,等. 超千米深井巷道围岩变形特征与支护技术[J]. 岩石力学与工程学报,2015,34(11):2 227–2 241. (KANG Hongpu,FAN Mingjian,GAO Fuqiang,et al. Deformation and support of rock roadway at depth more than 1 000 meters[J]. Chinese Journal of Rock Mechanics and Engineering,2015,34(11):2 227–2 241.(in Chinese))
[69] 吴拥政. 锚杆杆体的受力状态及支护作用研究[硕士学位论文][D]. 北京:煤炭科学研究总院,2009.(WU Yongzheng. Study on stress states and supporting effects of bolt body[M. S. Thesis][D]. Beijing:China Coal Research Institute,2009.(in Chinese))
[70] 董双勇. 围压作用下锚杆锚固性能及其影响因素研究[硕士学位论文][D]. 北京:煤炭科学研究总院,2021.(DONG Shuangyong. Study on anchoring performance and influencing factors of bolt under confining pressure[M. S. Thesis][D]. Beijing:China Coal Research Institute,2021.(in Chinese))
[71] 李昌儒. 高强度螺纹钢锚杆抗剪力学性能试验研究[硕士学位论文][D]. 北京:煤炭科学研究总院,2019.(LI Changru. Experimental study on shear mechanical properties of high strength threaded steel bolt[M. S. Thesis][D]. Beijing:China Coal Research Institute,2019.(in Chinese))
[72] 司林坡,娄金福,杨景贺,等. 轴向冲击下锚固锚杆变形与应力特征分析[J]. 煤炭学报,2022,47(10):3 645–3 653.(SI Linpo,LOU Jinfu,YANG Jinghe,et al. Deformation and stress characteristics of anchor bolt under axial impact[J]. Journal of China Coal Society,2022,47(10):3 645–3 653.(in Chinese))
[73] KANG H P,YANG J H,GAO F Q,et al. Experimental study on the mechanical behavior of rock bolts subjected to complex static and dynamic loads[J]. Rock Mechanics and Rock Engineering,2020,53(11):4 993–5 004.
[74] 司林坡. 动静载作用下锚杆力学响应特征及破坏机制研究[博士学位论文][D]. 北京:煤炭科学研究总院,2023.(SI Linpo. Research on mechanical response characteristics and failure mechanism of the bolt applied dynamic and static load[Ph. D. Thesis][D]. Beijing:China Coal Research Institute,2023.(in Chinese))
[75] 康红普,杨景贺. 锚杆组合构件力学性能实验室试验及分析[J].煤矿开采,2016,21(3):1–6.(KANG Hongpu,YANG Jinghe. Laboratory experimental and analysis on mechanical performance of rock bolt accessories[J]. Coal Mining Technology,2016,21(3):1–6.(in Chinese))
[76] 原贵阳. 锚杆支护组合构件与金属网力学性能及其匹配性试验研究[硕士学位论文][D]. 北京:煤炭科学研究总院,2020.(YUAN Guiyang. Experimental study on mechanical properties and matching of bolt support composite components and metal mesh[M. S. Thesis][D]. Beijing:China Coal Research Institute,2020.(in Chinese))
[77] 原贵阳,高富强,娄金福,等. 锚杆支护金属网力学性能及传力机制试验研究[J]. 煤炭学报,2022,47(4):1 512–1 522.(YUAN Guiyang,GAO Fuqiang, LOU Jinfu,et al. Experimental study on mechanical properties and force transfer mechanism of bolt supported metal mesh[J]. Journal of China Coal Society,2022,47(4):1 512–1 522.(in Chinese))
[78] 康红普,王金华,高富强. 掘进工作面围岩应力分布特征及其与支护的关系[J].煤炭学报,2009,34(12):1 585–1 593.(KANG Hongpu,WANG Jinhua,GAO Fuqiang. Stress distribution characteristics in rock surrounding heading face and its relationship with supporting[J]. Journal of China Coal Society,34(12):1 585–1 593.(in Chinese))
[79] 康红普,吴拥政,何 杰,等. 深部冲击地压巷道锚杆支护作用研究与实践[J]. 煤炭学报,2015,40(10):2 225–2 233.(KANG Hongpu,WU Yongzheng,HE Jie,et al. Rock bolting performance and field practice in deep roadway with rock burst[J]. Journal of China Coal Society,2015,40(10):2 225–2 233.(in Chinese))
[80] 康红普,林 健,吴拥政,等. 锚杆构件力学性能及其匹配性[J]. 煤炭学报,2015,40(1):11–23.(KANG Hongpu,LIN Jian,WU Yongzheng,et al. Mechanical performances and compatibility of rock bolt components[J]. Journal of China Coal Society,2015,40(1):11–23.(in Chinese))
[81] 康红普,吴拥政,李建波. 锚杆支护组合构件的力学性能与支护效果分析[J]. 煤炭学报,2010,35(7):1 057–1 065.(KANG Hongpu,WU Yongzheng,LI Jianbo. Analysis on mechanical performances and support function of combination components for rock bolting[J]. Journal of China Coal Society,2010,35(7):1 057–1 065.(in Chinese))
[82] 石 垚. 不同组合构件对锚杆支护应力场影响的实验室研究[硕士学位论文][D]. 北京:煤炭科学研究总院,2016.(SHI Yao. Study on the influence of difference composite parts on the rockbolt stress field by laboratory studies[M. S. Thesis][D]. Beijing:China Coal Research Institute,2016.(in Chinese))
[83] 林 健,石 垚,孙志勇,等. 端部锚固锚杆预应力场分布特征的大型模型试验研究[J]. 岩石力学与工程学报,2016,35(11):2 237–2 247.(LIN Jian,SHI Yao,SUN Zhiyong,et al. Large scale model test on the distribution characteristics of the prestressed field of end-anchored bolts[J]. Chinese Journal of Rock Mechanics and Engineering,2016,35(11):2 237–2 247.(in Chinese))
[84] 康红普,徐 刚,王彪谋,等. 我国煤炭开采与岩层控制技术发展40 a及展望[J]. 采矿与岩层控制工程学报,2019,1(1):1–33. (KANG Hongpu,XU Gang,WANG Biaomou,et al. Forty years development and prospects of underground coal mining and strata control technologies in China[J]. Journal of Mining and Strata Control Engineering,2013,1(1):1–33.(in Chinese))
[85] 康红普,姜鹏飞,黄炳香,等. 煤矿千米深井巷道围岩支护–改性–卸压协同控制技术[J]. 煤炭学报,2020,45(3):845–864.(KANG Hongpu,JIANG Pengfei,HUANG Bingxiang,et al. Roadway strata control technology by means of bolting-modification-destressing in synergy in 1 000 m deep coal mines[J]. Journal of China Coal Society,2020,45(3):845–864.(in Chinese))
[86] 姜鹏飞. 千米深井巷道围岩支护–改性–卸压协同控制原理及技术[博士学位论文][D]. 北京:煤炭科学研究总院,2020.(JIANG Pengfei. Roadway strata control principle and techniques by means of bolting-modification-destressing in synergy in 1000 m deep coal mines[Ph. D. Thesis][D]. Beijing:China Coal Research Institute,2020.(in Chinese))
[87] 李桂臣,杨 森,孙元田,等. 复杂条件下巷道围岩控制技术研究进展[J]. 煤炭科学技术,2022,50(6):29–45.(LI Guichen,YANG Sen,SUN Yuantian,et al. Research progress of roadway surrounding strata rock control technologies under complex conditions[J]. Coal Science and Technology,2022,50(6):29–45.(in Chinese))
[88] 姜鹏飞,康红普,王志根,等. 千米深井软岩大巷围岩锚架充协同控制原理、技术及应用[J]. 煤炭学报,2020,45(3):1 020–1 035. (JIANG Pengfei,KANG Hongpu,WANG Zhigen,et al. Principle,technology and application of soft rock roadway strata control by means of “rock bolting,U-shaped yielding steel arches and back filling” in synergy in 1 000 m deep coal mines[J]. Journal of China Coal Society,2020,45(3):1 020–1 035.(in Chinese))
[89] 张 农,魏 群,吴建生. 煤矿巷道喷涂柔膜技术及适用性[J]. 煤炭科学技术,2022,50(1):78–85.(ZHANG Nong,WEI Qun,WU Jiansheng. Spray-on membrane technology and its applicability in coal mine roadways[J]. Coal Science and Technology,2022,50(1):78–85.(in Chinese))
[90] 魏 群. 喷涂柔膜在锚杆支护中的作用机制研究[博士学位论文][D]. 徐州:中国矿业大学,2020.(WEI Qun. Study on the mechanism of spray-on membranes under bolting system[Ph. D. Thesis][D]. Xuzhou:China University of Mining and Technology,2020.(in Chinese))
[91] 康红普. 煤矿预应力锚杆支护技术的发展与应用[J]. 煤矿开采,2011,16(3):25–30.(KANG Hongpu. Development and application of pre-stress anchored bolt supporting technology in coal mine[J]. Coal Mining Technology,2011,16(3):25–30.(in Chinese))
[92] 康红普. 我国煤矿巷道锚杆支护技术发展60年及展望[J]. 中国矿业大学学报,2016,45(6):1 071–1 081.(KANG Hongpu. Sixty years development and prospects of rock bolting technology for underground coal mine roadways in China[J]. Journal of China University of Mining and Technology,2016,45(6):1 071–1 081.(in Chinese))
[93] 苏东风. 复合充填注浆材料与扩散充填注浆理论的研究[硕士学位论文][D]. 阜新:辽宁工程技术大学,2001.(SU Dongfeng. Investigation about composite filling and pre-grouting material and spreading theory[M. S. Thesis][D]. Fuxin:Liaoning Technical University,2001.(in Chinese))
[94] 郝 哲,王介强,刘 斌. 岩体渗透注浆的理论研究[J]. 岩石力学与工程学报,2001,20(4):492–496.(HAO Zhe,WANG Jieqiang,LIU Bin. Theoretical study of osmotic grouting in rock mass[J]. Chinese Journal of Rock Mechanics and Engineering,2001,20(4):492–496.(in Chinese))
[95] 张忠苗,邹 健,何景愈,等. 考虑压滤效应下饱和黏土压密注浆柱扩张理论[J]. 浙江大学学报:工学版,2011,45(11):1 980–1 984. (ZHANG Zhongmiao,ZOU Jian,HE Jingyu,et al. Cavity expansion theory of compaction grouting in saturated clay considering pressure filtration[J]. Journal of Zhejiang University:Engineering Science,2011,45(11):1 980–1 984.(in Chinese))
[96] TE GROTENHUIS R. Fracture grouting in theory:modelling of fracture grouting in sand[Ph. D. Thesis][D]. Netherlands:Delft University of Technology,2004.
[97] 邹金锋,李 亮,杨小礼. 劈裂注浆扩散半径及压力衰减分析[J]. 水利学报,2006,37(3):314–319.(ZOU Jinfeng,LI Liang,YANG Xiaoli. Penetration radius and pressure attenuation law in fracturing grouting[J]. Journal of Hydraulic Engineering,2006,37(3):314–319.(in Chinese))
[98] 管学茂,仲启方. 超细水泥基注浆材料性能研究与工程应用[J]. 煤矿安全,2013,44(6):142–145.(GUAN Xuemao,ZHONG Qifang. Research on the performance of micro-fine cement-based grouting material and its engineering application[J]. Safety in Coal Mines,2013,2013,44(6):142–145.(in Chinese))
[99] 牛宇涛,张春静,杨政鹏,等. 聚氨酯基有机/无机复合注浆材料的研究进展[J]. 化工新型材料,2018,46(3):42–44.(NIU Yutao,ZHANG Chunjing,YANG Zhengpeng,et al. Recent progress of organic/ inorganic composite grouting material based on polyurethane[J]. New Chemical Material,2018,46(3):42–44.(in Chinese))
[100] 王江峰,张海波,管学茂. 超细水泥注浆材料煤壁注浆加固试验研究[J]. 河南理工大学学报:自然科学版,2011,30(2):145–148. (WANG Jiangfeng,ZHANG Haibo,GUAN Xuemao. The study on micro-fine cement grouting matial applying in coal reinforcement[J]. Journal of Henan Polytechnic University:Natural Science,2011,30(2):145–148.(in Chinese))
[101] 吴爱祥,于少峰,韩 斌,等. 超细水泥注浆溶液配比优化及扩散规律研究[J]. 采矿与安全工程学报,2014,31(2):304–309.(WU Aixiang,YU Shaofeng,HAN Bin,et al. Optimization of mix-proportion and diffusing rule of super-fine cement grouting slurry[J]. Journal of Mining and Safety Engineering,2014,31(2):304–309.(in Chinese))
[102] 管学茂,张海波,杨政鹏,等. 高性能无机–有机复合注浆材料研究[J]. 煤炭学报,2020,45(3):902–910.(GUAN Xuemao,ZHANG Haibo,YANG Zhengpeng,et al. Research of high performance inorganic-organic composite grouting materials[J]. Journal of China Coal Society,2020,45(3):902–910.(in Chinese))
[103] KANG H P,LI W Z,GAO F Q,et al. Grouting theories and technologies for the reinforcement of fractured rocks surrounding deep roadways[J]. Deep Underground Science and Engineering,2023,2(1):2–19.
[104] 张海波,狄红丰,刘庆波,等. 微纳米无机注浆材料研发与应用[J]. 煤炭学报,2020,45(3):949–955.(ZHANG Haibo,DI Hongfeng,LIU Oingbo,et al. Research and application of micro-nano inorganic grouting materials[J]. Journal of China Coal Society,2020,45(3):949–955.(in Chinese))
[105] 康红普,姜鹏飞,冯彦军,等. 煤矿巷道围岩卸压技术及应用[J].煤炭科学技术,2022,50(6):1–15.(KANG Hongpu,JIANG Pengfei,FENG Yanjun,et al. Destressing technology for rock around coal mine roadways and its applications[J]. Coal Science and Technology,2022,50(6):1–15.(in Chinese))
[106] 潘俊锋,康红普,闫耀东,等. 顶板“人造解放层”防治冲击地压方法、机制及应用[J]. 煤炭学报,2023,48(2):636–648.(PAN Junfeng,KANG Hongpu,YAN Yaodong,et al. The method,mechanism and application of preventing rock burst by artificial liberation layer of roof[J]. Journal of China Coal Society,2023,48(2):636–648.(in Chinese))
[107] KANG H P,JIANG P F,FENG Y J,et al. Application of large-scale hydraulic fracturing for reducing mining-induced stress and microseismic events:a comprehensive case study[J]. Rock Mechanics and Rock Engineering,2023,56(2):1 399–1 413.
[108] 夏永学,潘俊锋,谢 非,等. 特厚煤层大巷复合构造区重复冲击致灾机制及控制技术[J]. 岩石力学与工程学报,2022,41(11):2 199–2 209.(XIA Yongxue,PAN Junfeng,XIE Fei,et al. Disaster mechanism and control technology of large roadway group with repeated impact in extra-thick coal seam[J]. Chinese Journal of Rock Mechanics and Engineering,2022,41(11):2 199–2 209.(in Chinese)) |
| [1] |
LI Botao1, 2, 3, TAN Yuxuan1, LIN Haifei4, 5*, WEI Jianping1, 2, 3, ZHANG Hongtu1, 2, 3, LI Shugang4, 5, WEI Zongyong4, 5, WANG Pei4, LUO Rongwei4, LIU Yanwei1, 2, 3. Mechanical properties and mesoscopic damage evolution of coal under liquid-nitrogen freezing at different initial temperatures[J]. , 2026, 45(6): 1757-1772. |
|
|
|
|
2024, Vol. 43 
