岩石变形记忆效应：应用、试验与理论

王海军; 汤雷; 任旭华; 钟凌伟; 司富安; HSIEHAriel

doi:10.11779/CJGE201809002

岩石变形记忆效应：应用、试验与理论 English Version

1. 南京水利科学研究院水文水资源与水利工程国家重点试验室,江苏南京 210029;
2. 河海大学,江苏南京 210098;
3. 水利部水利水电规划设计总院,北京100120;
4. The University of Western Australia,Perth 6009, Australia

基金项目: 国家重点研发计划项目（2016YFC0401801）; 国家自然科学基金项目（51409170,51739008）; 江苏省自然科学基金项目（BK20171130）; 中央级公益性科研院所基本科研业务费重点项目（Y417007,Y417016）

详细信息

作者简介:
王海军(1985- ),男,博士,高级工程师,主要从事记忆岩石力学相关科研工作。E-mail：hjwang@nhri.cn。

通讯作者:
任旭华，E-mail：renxh@hhu.edu.cn

中图分类号: TU452
计量
- 文章访问数: 410
- HTML全文浏览量: 18
- PDF下载量: 358
出版历程
- 收稿日期: 2017-06-12
- 发布日期: 2018-09-24

Rock deformation memory effect: applications, experiments and theories

1. State Key Laboratory of Hydrology-Water Resource and Hydraulic Enginering, Nanjing Hydraulic Research Institute, Nanjing 210029, China;
2. Hohai University, Nanjing 210098, China;
3. China Renewable Energy Engineering Institute, Beijing 100120, China;
4. The University of Western Australia, Perth 6009, Australia

摘要

摘要: 基于岩石变形记忆效应DME & DRA法,为准确便捷测量初始地应力提供了全新的思路,国际上及中国台湾的一系列实践应用证明了其巨大的潜力。但是,岩石变形记忆效应的研究和工程应用在中国（除中国台湾外）刚起步,同时,试验及理论的系统性研究整体上落后于工程应用,成为制约DME & DRA法成熟和普及的瓶颈问题。因此,开展岩石变形记忆效应的应用、试验、理论的研究进展综述具有重要意义。首先给出岩石DME & DRA法的基本概念,然后给出在国际上的应用实践现状;从7个方面的内容对试验研究进展进行系统性评述：①岩石变形记忆DRA曲线特征;②岩石变形记忆效应的失忆性;③人工记忆与地应力记忆;④初始加载保持时间;⑤初始加载重复次数;⑥记忆存在应力区域;⑦三维应力记忆特征;详细探讨各方面成果及不足;探讨了岩石变形记忆效应形成机理的两种认识及相应的理论模型,深入剖析现有研究结论与进展揭示存在的挑战,最终给出研究方向与建议。为推动国内开始开展岩石变形记忆效应的研究与应用提供基础。
- 初始地应力 /
- 岩石变形记忆效应（DME） /
- 变形率分析法(DRA法) /
- 岩石力学 /
- 研究进展
Abstract: Based on the rock deformation memory effect (DME), the deformation rate analysis (DRA) method is a new method for determining the magnitudes and orientation of the in-situ stress. The DME & DRA method has an inherent advantage over the traditional in-situ stress determination methods. A significant number of successful experiments have been done in many countries. But in China, the DME & DRA method has not been explored and used by now. At the same time, the lack of the experimental and theoretical researches on the rock deformation memory prevents the improvements of the DME & DRA method. A review of application, experimental and theoretical researches on rock DME is given. For the experiments, 7 topics include: (1) features of DRA curve, (2) memory fading, (3) artificial memory and in-situ stress memory, (4) duration of loading application, (5) preload times, (6) stress level memorized by DME, (7) memory under triaxial stress state. Two kinds of mechanisms and the corresponding theoretical models are discussed with their strengths and weakness analyzed. Finally, the necessity and the directions for the future researches are outlined.
- in-situ stress /
- deformation memory effect /
- deformation rate analysis /
- rock mechanics /
- research advance

HTML全文

参考文献(98)

[1]	FAIRHURST C.Stress estimation in rock: a brief history and review[J]. International Journal of Rock Mechanics & Mining Sciences, 2003, 40(7/8): 957-973.
[2]	HUDSON J A, CORNET F H, CHRISTIANSSON R.ISRM suggested methods for rock stress estimation part 1: strategy for rock stress estimation[J]. International Journal of Rock Mechanics & Mining Sciences, 2003, 40(7/8): 991-998.
[3]	蔡美峰, 王双红. 地应力状态与围岩性质的关系研究[J]. 中国矿业, 1997(6): 38-41. (CAI Mei-feng, WANG Shang-hong.Relation between ground stress behaviour and propertities of surrounding rock[J]. China Mining Magazine, 1997(6): 38-41. (in Chinese))
[4]	谢和平. “深部岩体力学与开采理论”研究构想与预期成果展望[J]. 工程与科学技术, 2017(2): 1-16. (XIE He-ping.Research framework and anticipated results of deep rock mechanics and mining theory[J]. Advanced Engineering Science, 2017(2): 1-16. (in Chinese))
[5]	郭建春, 王兴文, 曾凡辉. 异常高应力储层改造理论与技术[M]. 北京: 科学出版社, 2015. (GUO Jian-chun, WANG Xing-wen, ZENG Fan-hui.Stimulation theories and technologies in abnormal high stress reservoir[M]. Beijing: Science Press, 2015. (in Chinese))
[6]	DIGHT P.Stress states in open pits[C]// Keynote Lecture-Slope Stability in Mining and Civil Engineering. Vancouver, 2011.
[7]	葛修润, 侯明勋. 三维地应力BWSRM测量新方法及其测井机器人在重大工程中的应用[J]. 岩石力学与工程学报, 2011, 30(11): 2161-2180. (GE Xiu-run, HOU Ming-xun.A new 3D in-situ rock stress measuring method: borehole wall stress relief method (BWSRM) and development of geostress measuring instrument based on BWSRM and its primary applications to engineering[J]. Chinese Journal of Rock Mechanics and Engineering, 2011, 30(11): 2161-2180. (in Chinese))
[8]	张社荣, 顾岩, 张宗亮. 超大型地下洞室围岩锚杆支护方式的优化设计[J]. 水力发电学报, 2007, 26(5): 47-52. (ZHANG She-rong, GU Yan, ZHANG Zong-liang.The optimized design of rockbolts supporting the large-scale underground cavities[J]. Journal of Hydroelectric Engineering, 2007, 26(5): 47-52. (in Chinese))
[9]	HEAL D.Observations and analysis of incidence of rockburst damage in underground mines[D]. Perth: The University of Western Australia, 2010.
[10]	段东, 唐春安, 李连崇, 等. 煤和瓦斯突出过程中地应力作用机理[J]. 东北大学学报自然科学版, 2009, 30(9): 1326-1329. (DUAN Dong, TANG Chun-an, LI Lian-chong, et al.Study on the mechanism of ground stress in coal-gas outburst[J]. Journal of Northeastern Univeristy (Natural Science), 2009, 30(9): 1326-1329. (in Chinese))
[11]	LJUNGGREN C, CHANG Y, JANSON T, et al.An overview of rock stress measurement methods[J]. International Journal of Rock Mechanics & Mining Sciences, 2003, 40(7/8): 975-989.
[12]	AMADEI B, STEPHANSSON O.Rock stress and its measurement[J]. Engineering Geology, 1986, 49(1): 81-82.
[13]	蔡美峰. 地应力测量原理和技术[M]. 北京: 科学出版社, 1995. (CAI Mei-feng.Principles and techniques of in-situ stress measurement[M]. Beijing: Science Press, 1995. (in Chinese))
[14]	SJÖBERG J, CHRISTIANSSON R, HUDSON J A. ISRM Suggested Methods for rock stress estimation part 2: overcoring methods[J]. International Journal of Rock Mechanics & Mining Sciences, 2003, 40(7): 999-1010.
[15]	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 & Mining Sciences, 2003, 40(7/8): 1011-1020.
[16]	HUNT S P, MEYERS A G, LOUCHNIKOV V.Modelling the Kaiser effect and deformation rate analysis in sandstone using the discrete element method[J]. Computers & Geotechnics, 2003, 30(7): 611-621.
[17]	侯明勋, 葛修润, 王水林. 水力压裂法地应力测量中的几个问题[J]. 岩土力学, 2003, 24(5): 840-844. (HOU Ming-xun, GE Xiu-run, WANG Shui-lin.Discussion on application of hydraulic fracturing method to geostress measurement[J]. Rock and Soil Mechanics, 2003, 24(5): 840-844. (in Chinese))
[18]	YAMAMOTO K, KUWAHARA Y, KATO N, et al.Deformation rate analysis: a new method for in situ stress estimation from inelastic deformation of rock samples under uni-axial compression[J]. Science Reports of the Tohoku University Fifth, 1990, 33(2): 34-34.
[19]	DIGHT P, DYSKIN A V.Accounting for the effect of rock mass anisotropy in stress measurements[C]// Deep Mining 07. Proc 4th International Seminar on Deep and High Stress Mining. Nedlands, Western Australia, 2007: 415-425.
[20]	DIGHT P, DYSKIN A.On the determination of rock anisotropy for stress measurements[C]// Proceedings of the First Southern Hemisphere International Rock Mechanics Symposium. Perth, 2008: 575-585.
[21]	葛伟凤, 张飞, 陈勉, 等. 盐膏岩DRA-Kaiser地应力测试方法初探[J]. 岩石力学与工程学报, 2015(增刊1): 3138-3142. (GE Wei feng, ZHANG Fei, CHEN Mian, et al. Research on Geotress Measurement Using DRA-KAISER Method in Salt-Gypsum Formation[J]. Chinese Journal of Rock Mechanics and Engineering, 2015(S1): 3138-3142. (in Chinese))
[22]	石凯, 梅甫定, 程明胜, 等. 循环加载高应力对大理岩Kaiser效应影响的实验研究[J]. 岩石力学与工程学报, 2017, 36(12): 2906-2916. (SHI Kai, MEI Fu-ding, CHENG Ming-sheng, et al.Experimental study on the effect of high stress of cyclic loading on Kaiser effectin marble[J]. Chinese Journal of Rock Mechanics and Engineering, 2017, 36(12): 2906-2916. (in Chinese))
[23]	王海军, 任旭华, 陶冉冉, 等. 基于摩擦滑动的低应力区岩石变形记忆性机理[J]. 中南大学学报(自然科学版), 2012, 43(11): 4464-4471. (WANG Hai-jun, REN Xun-hua, TAO Ran-ran, et al.Mechanism of rock deformation memory effect in low stress region based on frictional sliding[J]. Journal of Central South University (Science and Technology), 2012, 43(11): 4464-4471. (in Chinese))
[24]	王海军, 汤雷, 任旭华, 等. 低应力区岩石变形记忆效应形成机制及失忆性[J]. 岩土力学, 2014, 35(4): 1007-1014. (WANG Hai-jun, TANG Lei, REN Xu-hua, et al.Mechanism of rock deformation memory effect in low stress region and its memory fading[J]. Rock and Soil Mechanics, 2014, 35(4): 1007-1014. (in Chinese))
[25]	谢强, 邱鹏, 余贤斌. 利用声发射法和变形率变化法联合测定地应力[J]. 煤炭学报, 2010, 35(4): 559-564. (XIE Qiang, QIU Peng, YU Xian-bin.Initial-stress measurements with AE and DRA combined technique[J]. Journal of China Coal Society, 2010, 35(4): 559-564. (in Chinese))
[26]	YAMSHCHIKOV V S, SHKURATNIK V L, LAVROV A V.Memory effects in rocks (review)[J]. Journal of Mining Science, 1994, 30(5): 463-473.
[27]	VINNIKOV V A, SHKURATNIK V L.Theoretical model for the thermal emission memory effect in rocks[J]. Journal of Applied Mechanics & Technical Physics, 2008, 49(2): 301-305.
[28]	ZOGALA B, ZUBEREK M, GOROSKIEWICZ A.Acoustic emission in Carboniferous sandstone and mudstone samples subjected to cyclic heating[J]. Mining-Induced Seismicity, 1992, 89(3).
[29]	REED L D, MCDOWELL G M.A fracto-emission memory effect and subharmonic vibrations in rock samples stressed at sonic frequencies[J]. Rock Mechanics and Rock Engineering, 1994, 27(4): 253-261.
[30]	SHKURATNIK V L, LAVROV A V.A theoretical model of the electromagnetic emission effect of rock memory[J]. Journal of Applied Mechanics & Technical Physics, 1996, 37(6): 913-916.
[31]	JONASON K, VINCENT E, HAMMANN J, et al.Memory and chaos effects in spin glasses[J]. Physical Review Letters, 1998, 81(15): 3243-3246.
[32]	FUJII N, HAMANO Y.Anisotropic changes in resistivity and velocity during rock deformation[J]. High-Pressure Research, 1977: 53-63.
[33]	LIN H, WU J, LEE D.Evaluating the pre-stress of Mu-Shan sandstone using acoustic emission and deformation rate analysis[M]// London: In-situ Rock Stress, 2006: 215-222.
[34]	DIGHT P.Determination of in-situ stress from oriented core[M]. London: In-situ Rock Stress, 2006: 167-176.
[35]	SATO N, YABE Y, YAMAMOTO K, et al.In situ stresses near the Nojima fault estimated by deformation rate analysis[J]. Journal of the Seismological Society of Japan, 2003, 56: 157-169.
[36]	SETO M, NAG D K, VUTUKURI V S.In-situ rock stress measurement from rock cores using the acoustic emission method and deformation rate analysis[J]. Geotechnical and Geological Engineering, 1999, 17(3): 241-266.
[37]	UTAGAWA M, SETO M, KATSUYAMA K.Estimation of initial stress by deformation rate analysis (DRA)[J]. International Journal of Rock Mechanics & Mining Sciences, 1997, 34(3/4): 501.
[38]	YAMAMOTO K.A theory of rock core-based methods for in-situ stress measurement[J]. Earth, Planets and Space, 2009, 61(10): 1143-1161.
[39]	YAMAMOTO H.An experimental study on stress memory of rocks and its application to in situ stress estimation[D]. Miyagi-ken: Tohoku Univ, 1991.
[40]	DIGHT P, ARIEL H.Insitu stress measurement report——DGDD 117 & DGDD 047[R]. Perth: The University of Western Australia, 2010.
[41]	DIGHT P, ARIEL H.Insitu stress measurement report——1037A[R]. Perth: The University of Western Australia, 2010.
[42]	DIGHT P, ARIEL H.Preliminary insitu stress measurement report[R]. Perth: The University of Western Australia, 2010.
[43]	DIGHT P, ARIEL H.Insitu stress measurement report——EH753[R]. Perth: The University of Western Australia, 2011.
[44]	HULLS L.George fisher mine 17 level stress measurement results[R]. Mlebourne: Mining One Pty Ltd, 2014.
[45]	YAMAMOTO K, YABE Y.Stresses at sites close to the Nojima fault measured from core samples[J]. Island Arc, 2001, 10(3/4): 266-281.
[46]	YAMAMOTO K, YABE Y, YAMAMOTO H.Relation of in-situ stress field to seismic activity as inferred from the stresses measured on core samples[M]// Rotterdam: Balkema, 375-380.
[47]	YAMAMOTO K, YAMAMOTO H, KATO N, et al.Deformation rate analysis for in situ stress measurement[M]. Clausthal-Zellerfeld: Trans Tech Publications. 243-255.
[48]	TSUKAHARA H, IKEDA R.Hydraulic fracturing stress measurements and in-situ stress field in the Kanto-Tokai area, Japan[J]. Tectonophysics, 2012, 135(4): 329-345.
[49]	MCMAHON A.Results of insitu stress tests appendix g in argyle diamond mine-underground geotechnical investigations[R]. Perth: Report on Geotechnical Observations and Measurement, 1996.
[50]	BOGACZ V, DIGHT P.Extensional tectonic deformation and tectonic genesis model of the deposit[R]. Perth: BFPO Consultants Report, 2002.
[51]	YABE Y, SONG S R, WANG C Y.In-situ stress at the northern portion of the Chelungpu fault, Taiwan, estimated on boring cores recovered from a 2-km-deep hole of TCDP[J]. Earth, Planets and Space, 2008, 60(8): 809-819.
[52]	YABE Y, YAMAMOTO K, SATO N, et al.Comparison of stress state around the Atera fault, central Japan, estimated using boring core samples and by improved hydraulic fracture tests[J]. Earth, Planets and Space, 2010, 62(3): 257-268.
[53]	YABE Y, OMURA K.In-situ stress at a site close proximity to the Gofukuji Fault, central Japan, measured using drilling cores[J]. Island Arc, 2011, 20(2): 160-173.
[54]	SETO M, SOMA N, MAEDA N, et al.Methodology and case studies of stress measurement by the AE and DRA methods using rock core[J]. Journal of Mmij, 2001, 117: 829-835.
[55]	SETO M, VILLAESCUSA E.In situ stress determination by acoustic emission techniques from mcarthur river mine cores[C]// Proceedings 8th Australia New Zealand Conference on Geomechanics. Hobart, 1999: 929-934.
[56]	SETO M, VILLAESCUSA E, UTAGAWA M, et al.In Situ Stress Evaluation from Rock Cores Using AE Method and DRA[J]. Shigen-to-Sozai, 1998, 114(12): 845-855.
[57]	PARK P, PARK N, HONG C, et al.The influence of delay time and confining pressure on in-situ stress measurement using AE and DRA[C]// Proceedings of the 38th US Symposium on Rock Mechanics. Washington, 2001: 1281-1284.
[58]	VILLAESCUSA E, SETO M, BAIRD G.Stress measurements from oriented core[J]. International Journal of Rock Mechanics & Mining Sciences, 2002, 39(5): 603-615.
[59]	藤井義明, 石島洋二, 堀場夏峰, 等. あるV字谷におけるシーティングの力学的背景に関する研究[J]. 資源と素材, 1998, 114(12): 869-874. (FUJII Y, ISHIJIMA Y, HORIBA N, et al.A study on mechanical backgrounds of sheeting joints in a V-shaped valley[J]. Shigen-to-Sozai, 1998, 114(12): 869-874. (in Japanese))
[60]	松本裕之, 後藤龍彦, 出口剛太. 太平洋炭鉱における原位置地圧計測結果と変形率変化法との比較[J]. 資源と素材, 1996, 112(11): 796-799. (MATSUMOTO H, GOTO Tatsuhiko.Comperison between results of in-site stress measurements and DRA. method in taiheiyo coal mine[J]. Shigen-to-Sozai, 1996, 112(11): 796-799. (in Japanese))
[61]	HOLMES C.Deformation rate analysis and “stress memory” effect in rock[D]. Perth: The University of Western Australia, 2004.
[62]	CHANG C F.Investigating the laboratory experiments to estimate pre-stress on black schist[D]. Tainan City: National Cheng Kung University, 2007.
[63]	WANG H J, DYSKIN A V, HSIEH A, et al.The mechanism of the deformation memory effect and the deformation rate analysis in layered rock in the low stress region[J]. Computers & Geotechnics, 2012, 44: 83-92.
[64]	WU J H, JAN S C.Experimental validation of core-based pre-stress evaluations in rock: a case study of Changchikeng sandstone in the Tseng-wen reservoir transbasin water tunnel[J]. Bulletin of Engineering Geology and the Environment, 2010, 69(4): 549-559.
[65]	CHAN S C.Investigating the laboratory experiments to estimate pre-stress on changchikeng sandstone[D]. Tainan City: Cheng Kung University, 2008.
[66]	英樹島田, 史樹後藤, 政宏瀬戸, 等. DRA法による地圧測定の適用性に関する基礎的研究[J]. 資源と素材, 2006, 117(3): 202-208. (SHIMADA H, GOTO F, SETO M, et al.Fundamental study on applicability on in-situ stress using DRA methods[J]. Shigen-to-Sozai, 2006, 117(3): 202-208. (in Japanese))
[67]	HUNT S, MEYERS A, LOUCHNIKOV V, et al.Use of the DRA technique, porosimetry and numerical modelling for estimating the maximum in-situ stress in rock from core[J]. South African Institute of Mining & Metallurgy, 2003, 37(1): 17-22.
[68]	II'INOV M D. Development of a method of quantitative evaluation of the stress state of rocks in situ from indices of the mechanical properities of an extracted core[D]. VINIMI: Leningrad, 1985.
[69]	MAKASI M, FUJII Y.Effects of strain rate and temperature on tangent modulus method[C]// Proceedings of Korean Rock Mecahanics Symposium. Gwangju, 2008: 279-285.
[70]	MAKASI M, FUJII Y.Effects of strain rate and temperature on bending point stress in tangent modulus method[C]// The 3rd International Workshop and Conference on Earth Resources Technology. Sapporo, 2009: 116-123.
[71]	PROSKURYUAKOV N M, KARTASHOV Y M, II'INOV M D. Memory effects of rocks under various types of their loading[C]// Memory Effects in Rocks. Moscow, 1986.
[72]	KAISER J.Information and conclusions from the measurement of noises in tensile stressing of metallic materials[J]. Arch Eisenhuttenwesen, 1953(24): 43-45.
[73]	TANG C A, CHEN Z H, XU X H, et al.A theoretical model for kaiser effect in rock[J]. Pure and Applied Geophysics, 1997, 150(2): 203-215.
[74]	樊运晓. 损伤:Kaiser效应记忆机理的探讨[J]. 岩石力学与工程学报, 2000, 19(2): 254-258. (FAN Yun-xiao.Damage, the mechanism of Kaiser effect[J]. Chinese Journal of Rock Mechanics and Engineering, 2000, 19(2): 254-258. (in Chinese))
[75]	TAMAKI K, YAMAMOTO K, FURUTA T, et al.An experiment of in-situ stress estimation on basaltic rock core samples from hole 758a, ninetyeast ridge, Indian Ocean[J]. Journal of Infectious Diseases, 1991, 208(3): 425-432.
[76]	TAMAKI K, YAMAMOTO K.Estimating in situ stress field from basaltic rock core samples of Hole 794C, Yamato Basin, Japan Sea[C]// Proceedings of the Ocean Drilling Program, Scientific Results. Texas, 1992: 1047-1059.
[77]	STEVENS J L, HOLCOMB D J.A Theoretical investigation of the sliding crack model of dilatancy[J]. Journal of Geophysical Research, 1980, 85(B12): 7091-7100.
[78]	KUWAHARA Y, KYAMAMOTO I, HIRASAWA T.An experimental and theoretical study of inelastic deformation of brittle rocks under cyclic uniaxial loading[J]. Tohoku Geophys J, 1990, 33(1):1-21.
[79]	REN X H, WANG H J.Numerical study of AE and DRA methods in sandstone and granite in orthogonal loading directions[J]. Water Science and Engineering, 2012, 5(1): 93-104.
[80]	Itasca Consulting Group.PFC2D particle flow code in 2 Dimensions[M]. Minnesota: Minneapolis, 1999.
[81]	POTYONDY D O, CUNDALL P A.A bonded-particle model for rock[J]. International Journal of Rock Mechanics & Mining Sciences, 2004, 41(8): 1329-1364.
[82]	WAWERSIK W R, FAIRHURST C.A study of brittle rock fracture in laboratory compression experiments[J]. International Journal of Rock Mechanics & Mining Sciences & Geomechanics Abstracts, 1970, 7(5): 561-564.
[83]	JAEGER J C.Brittle fracture of rocks[C]// Proceeding of the 8th Symposium on Rock Mechanics. Baltimore: Port City Press, 1967: 3-57.
[84]	HUDSON J, HARRISON J, POPESCU M.Engineering rock mechanics: an introduction to the principles[J]. Applied Mechanics Reviews, 1997, 55(2): 72.
[85]	EBERHARDT E, STEAD D, STIMPSON B, et al.Identifying crack initiation and propagation thresholds in brittle roc[J]. Canadian Geotechnical Journal, 1998, 35(2): 222-233.
[86]	BIENIAWSKI Z T.Mechanism of brittle fracture of rock part II: experimental studies[J]. International Journal of Rock Mechanics & Mining Sciences & Geomechanics Abstracts, 1967, 4(4): 407-423.
[87]	BRACE W F, PAULDING B W, SCHOLZ C.Dilatancy in the fracture of crystalline rocks[J]. Journal of Geophysical Research, 1966, 71(16): 3939-3953.
[88]	MARTIN D C.The strength of massive Lac du Bonnet granite around underground openings[D]. Winnipeg: University of Manitoba, 1993.
[89]	CAI M, KAISER P K, TASAKA Y, et al.Generalized crack initiation and crack damage stress thresholds of brittle rock masses near underground excavations[J]. International Journal of Rock Mechanics & Mining Sciences, 2004, 41(5): 833-847.
[90]	DIEDERICHS M S, KAISER P K, EBERHARDT E.Damage initiation and propagation in hard rock during tunnelling and the influence of near-face stress rotation[J]. International Journal of Rock Mechanics & Mining Sciences, 2004, 41(5): 785-812.
[91]	YUAN S C, HARRISON J P.An empirical dilatancy index for the dilatant deformation of rock[J]. International Journal of Rock Mechanics & Mining Sciences, 2004, 41(4): 679-686.
[92]	ALKAN H, CINAR Y, PUSCH G.Rock salt dilatancy boundary from combined acoustic emission and triaxial compression tests[J]. International Journal of Rock Mechanics & Mining Sciences, 2007, 44(1): 108-119.
[93]	DAVID E C, BRANTUT N, SCHUBNEL A, et al.Sliding crack model for nonlinearity and hysteresis in the uniaxial stress-strain curve of rock[J]. International Journal of Rock Mechanics & Mining Sciences, 2012, 52(6): 9-17.
[94]	EBERHARDT E.Brittle rock fracture and progressive damage in uniaxial compression[J]. Human Factors, 1998, 8(3): 239-243.
[95]	LAVROV A.The Kaiser effect in rocks: principles and stress estimation techniques[J]. International Journal of Rock Mechanics & Mining Sciences, 2003, 40(2): 151-171.
[96]	BASISTA M, GROSS D.The sliding crack model of brittle deformation: an internal variable approach[J]. International Journal of Solids & Structures, 1998, 35(5/6): 487-509.
[97]	MORI T, MURA T.Blocking effect of inclusions on grain boundary sliding; spherical grain approximation[J]. Journal of the Mechanics & Physics of Solids, 1987, 35(5): 631-641.
[98]	王海军. 基于黏弹性摩擦滑动的岩石变形记忆效应形成机理研究[D]. 南京: 河海大学, 2012. (WANG Hai-jun.Mechanism of rock deformation memory effect based on viscoelastic frictional sliding[D]. Nanjing: Hohai University.(in Chinese))

施引文献(11)

期刊类型引用(7)

1.	刘建伟. 循环载荷作用下含水煤岩组合体损伤特性及裂纹扩展规律. 矿业研究与开发. 2024(04): 213-221 . 百度学术
2.	经来旺，李学帅，严悦，彭绍驰，李树文，经纬. 分级循环加卸载作用下煤岩损伤本构模型研究. 煤矿安全. 2022(01): 71-78 . 百度学术
3.	张俊文，丁露江，宋治祥，范文兵，王善勇. 加载速率效应下深部砂岩的力学特性（英文）. Journal of Central South University. 2022(06): 1933-1944 . 百度学术
4.	杨科，张寨男，池小楼，吕鑫，魏祯，刘文杰. 循环载荷下含水砂岩裂纹演化与损伤特征试验研究. 岩土力学. 2022(07): 1791-1802 . 百度学术
5.	朱淳，王海军，钟凌伟，汤雷，任旭华. 基于变形率变化法的初始地应力测量技术. 地下空间与工程学报. 2022(S2): 865-873 . 百度学术
6.	钟凌伟，王海军，任旭华，汤雷，Ariel Hsieh，尹健民，李永松. 保持加载下岩石变形记忆效应时效特征规律研究. 岩石力学与工程学报. 2020(02): 228-238 . 百度学术
7.	蔡国军，陈世豪，赵大安，周扬. 饱和砂土蠕变特性及其影响因素试验研究. 工程地质学报. 2019(05): 1048-1055 . 百度学术