水利水电深部工程地质勘察技术现状与发展趋势

doi:10.3724/1000-6915.jrme.2024.0921

摘要
图/表
参考文献
相关文章 (15)

全文: PDF (1064 KB) HTML (1 KB)
输出: BibTeX | EndNote (RIS)

摘要随着国家基础设施建设和能源资源开发的深入推进，我国西部水利水电开发呈现出更深更大规模发展趋势，受制于复杂的深部地质环境和有限的探测技术水平，深部工程常遇高地应力、高地温和高渗透压等高能地质环境挑战，给国家重大工程的规划和实施带来一系列挑战，亟需发展适用于深部环境的勘探与测试技术。从深部工程超深定向钻探技术、深部工程物探技术、深部工程随掘与随钻探测技术、深部工程岩体原位试验与测试技术以及深部工程围岩分类与参数取值等方面，全面梳理了国内外深部工程地质探测与测试研究进展和面临的问题，探讨深部工程地质勘察技术未来的发展趋势和研究方向，以期为深部地下工程建设和资源开发利用奠定基础。

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	张世殊

关键词 ：水利工程, 深部工程, 工程地质, 勘察技术, 定向钻探, 工程物探, 随掘与随钻探测, 原位测试

Abstract：With the advancement of national infrastructure construction and energy resource development strategies, hydraulic and hydropower development in Western China has exhibited a deeper and larger-scale trend. However, due to the complexities of deep geological environments and limitations in exploration techniques, deep engineering often faces challenges posed by high-energy geological conditions, such as elevated in-situ stress, high ground temperatures, and significant hydraulic pressures. Consequently, these factors present a series of challenges for the planning and implementation of major national projects, underscoring the necessity for the development of exploration and testing techniques tailored to deep conditions. This paper summarizes the current state of research on deep geological exploration and testing techniques, including ultra-deep directional drilling methods, deep geophysical exploration techniques, detection methods during tunneling or drilling, in-situ testing techniques, and the classification and parameter values of deep rock masses. It also identifies existing challenges within these areas. Furthermore, the paper discusses the development trends in deep geological exploration and testing techniques. The research findings will provide a foundation for deep engineering construction and the exploitation and utilization of deep resources.

Key words： hydraulic engineering deep engineering engineering geology exploration technology direction drilling engineering geophysical exploration detection while tunnelling or drilling in-situ testing

引用本文:

张世殊. 水利水电深部工程地质勘察技术现状与发展趋势[J]. 岩石力学与工程学报, 2025, 44(6): 1377-1404.
ZHANG Shishu. Research status and development trend of deep geological exploration techniques for hydraulic and hydropower engineering#br#. , 2025, 44(6): 1377-1404.

链接本文:

https://rockmech.whrsm.ac.cn/CN/10.3724/1000-6915.jrme.2024.0921 或 https://rockmech.whrsm.ac.cn/CN/Y2025/V44/I6/1377

[1]	谢和平，张茹，张泽天，等. 深地科学与深地工程技术探索与思考[J]. 煤炭学报，2023，48(11)：3 959-3 978.(XIE Heping，ZHANG Ru，ZHANG Zetian，et al. Reflections and explorations on deep earth science and deep earth engineering technology[J]. Journal of China Coal Society，2023，48(11)：3 959-3 978.(in Chinese))
[2]	高德利，黄文君. 深层、超深层定向钻井中若干基础研究进展与展望[J]. 天然气工业，2024，44(1)：1-12.(GAO Deli，HUANG Wenjun. Basic research progress and prospect in deep and ultra-deep directional drilling[J]. Natural Gas Industry，2024，44(1)：1-12.(in Chinese))
[3]	苏义脑，窦修荣，高文凯，等. 旋转导向系统研究现状与发展趋势[J]. 钻采工艺，2024，47(3)：1-8.(SU Yinao，DOU Xiurong，GAO Wenkai，et al. Research status and development trends of rotary steerable system[J]. Drilling and Production Technology，2024，47(3)：1-8.(in Chinese))
[4]	吴金生，黄晓林，蒋炳，等. 水平绳索随钻定向钻进技术研究与应用[J]. 煤田地质与勘探，2021，49(5)：260-264.(WU Jinsheng，HUANG Xiaolin，JIANG Bing，et al. Research and application of horizontal wire-line directional deviation correction while drilling[J]. Coal Geology and Exploration，2021，49(5)：260-264.(in Chinese))
[5]	马保松，程勇，刘继国，等. 超长距离水平定向钻进技术在隧道精准地质勘察的研究及应用[J]. 隧道建设(中英文)，2021，41(6)：972.(MA Baosong，CHENG Yong，LIU Jiguo，et al. Tunnel accurate geological investigation using long-distance horizontal directional drilling technology[J]. Tunnel Construction，2021，41(6)：972.(in Chinese))
[6]	郭昆明. 高地应力下护孔钻进用套管的研制[J]. 煤矿机械，2019，40(5)：57-59.(GUO Kunming. Development of casing for casing drilling under high ground stress[J]. Coal Mine Machinery，2019，40(5)：57-59.(in Chinese))
[7]	徐耀鉴，张绍和，杨仙. 弱包镶金刚石钻头在高地应力地层中的应用研究[J]. 金刚石与磨料磨具工程，2008，(1)：27-30.(XU Yaoqian，ZHANG Shaohe，YANG Xian. Research of diamond weak combined bit for high geo-stress stratum drilling[J]. Diamond and Abrasives Engineering，2008，(1)：27-30.(in Chinese))
[8]	张春林. 涌水钻孔施工工艺探讨——以新疆苇子沟矿区水文孔施工为例[J]. 中国煤炭地质，2022，34(3)：71-74.(ZHAMG Chunlin. Discussion on water gushing borehole operation technology—A case study of hydrogeological borehole operation in weizigou coalmine area，Xinjiang[J]. Coal Geology of China，2022，34(3)：71-74.(in Chinese))
[9]	时志兴. 河南省寺家沟银多金属矿区复杂地层绳索取心钻进技术[J]. 探矿工程(岩土钻掘工程)，2019，46(3)：31-35.(SHI Zhixing. Wireline core drilling in complex strata in Sijiagou silver polymetallic mine of Henan Province[J]. Exploration Engineering(Rock and Soil Drilling and Tunneling)，2019，46(3)：31-35.(in Chinese))
[10]	王佳亮，张绍和. 基于打滑地层的孕镶金刚石钻头设计[J]. 地球科学，2016，41(5)：895-900.(WANG Jialiang，ZHANG Shaohe. Design of impregnated diamond bit based on slipping formation[J]. Earth Science，2016，41(5)：895-900.(in Chinese))
[11]	BLÍ?KOSKÝ M，FUSÁN O，IBRMAJER J，et al. Geophysical phenomena of the deep structure in Czechoslovakia[J]. Journal of Geodynamics，1986，5(2)：165-178.
[12]	KRYLOV S V，MISHENKIN B P，BRYSKIN A V. Deep structure of the baikal rift from multiwave seismic explorations[J]. Journal of Geodynamics，1991，13(1)：87-96.
[13]	潘志伟. 高精度反射波勘探在超埋深管道探测中的应用[J]. 科技与创新，2024，(18)：179-181.(PAN Zhiwei. Application of high-precision reflected wave exploration in ultra-deep buried pipeline detection[J]. Science and Technology and Innovation，2024，(18)：179-181.(in Chinese))
[14]	HAJNAL Z，TAKÁCS E，ANNESLEY I R，et al. Effective utilization of seismic reflection technique with moderate cost in uranium exploration[J]. Geophysical Prospecting，2020，68(1)：129-144.
[15]	李玉波. 三维地震波法超前地质预报在引汉济渭工程TBM施工中的应用[J]. 水利水电技术，2017，48(8)：131-136.(LI Yubo. Application of 3-D seismic wave advanced geological forecast to TBM construction of Hanjiang-to-Weihe River Valley Water Diversion Project[J]. Water Resources and Hydropower Engineering，2017，48(8)：131-136.(in Chinese))
[16]	OKAMOTO T，IIDA D，KOSHIKIYA Y. Distributed acoustic sensing of seismic wave using optical frequency domain reflectometry[J]. Journal of Lightwave Technology，2023，41(22)：7 036-7 044.
[17]	杨旭. 地震波法在岩溶隧道中的应用研究[J]. 黑龙江交通科技，2022，45(6)：137-139.(YANG Xu. Application of seismic wave method in karst tunnel[J]. Communications Science and Technology Heilongjiang，2022，45(6)：137-139.(in Chinese))
[18]	李永鑫. 基于S变换与互相关的瑞雷面波频散曲线提取研究[硕士学位论文][D]. 西安：长安大学，2023.(LI Yongxin. Research on extracting rayleigh wave dispersion curve based on s-transform and cross-correlation[M. S. Thesis][D]. Xi?an：Chang?an University，2023.(in Chinese))
[19]	杨婷. 基于地震体波和面波成像的青藏高原东缘深部结构研究[博士学位论文][D]. 北京：中国地震局地球物理研究所，2024.(YANG Ting. Study on deep structures of the eastern margins of the Tibetan Plateau based or seismic body- and surface-wave travel time tomography[Ph. D. Thesis][D]. Beijing：Institute of Geophysics，China Earthquake Administration，2024.(in Chinese))
[20]	谭鑫. 隐伏断裂构造音频大地电磁法探测[J]. 工程地球物理学报，2018，15(3)：376-382.(TAN Xin. Exploration of concealed fault structures in audio magnetotelluric method(AMT)[J]. Journal of Engineering Geophysics，2018，15(3)：376-382.(in Chinese))
[21]	于双瑀. 直无人机载航空宽频电磁探测采集系统研究[硕士学位论文][D]. 长春：吉林大学，2024.(YU Shuangyu. Research on airborne broadband electromagnetic detection acquisition system carried by UAV[M. S. Thesis][D]. Changchun：Jilin University，2024.(in Chinese))
[22]	章成广，江万哲，潘和平. 声波测井原理与应用[M]. 北京：石油工业出版社，2009：52-69.(ZHANG Chengguang，JIANG Wanzhe，PAN Heping. Principles and applications of acoustic logging[M]. Beijing：Petroleum Industry Press，2009：52-69.(in Chinese))
[23]	张斌山. 井下电视在延长油田吴起采油厂的应用研究[硕士学位论文][D]. 西安：西安石油大学，2020.(ZHANG Binshan. Application of downhole TV in Wuqi oil production plant of Yanchang oilfield[M. S. Thesis][D]. Xi?an：Xi?an Shiyou University，2020.(in Chinese))
[24]	欧莽平. 石油测井技术现状与发展趋向探寻[J]. 中国石油和化工标准与质量，2019，39(10)：197-198.(OU Mangping. Exploration of the current status and development trends of petroleum logging technology[J]. China Petroleum and Chemical Standard and Quality，2019，39(10)：197-198.(in Chinese))
[25]	COBB C C，SCHULTZ P K. A real-time fiber optic downhole video system[C]// Proceedings of the Offshore Technology Conference. Houston，Texas：[s. n.]，1992：OTC-7046-MS.
[26]	MUKHLISS A E，DRIWEESH S M，SAGR A M，et al. First successfull implementation of high temperature video camera to identify downhole obstructions in gas wells：a saudi case[C]// Proceedings of the SPE Middle East Oil and Gas Show and Conference. Manama，Bahrain：[s. n.]，2015：SPE-172750-MS.
[27]	罗青平. VideoLog网络高清井下电视技术及其应用[硕士学位论文][D]. 西安：西安石油大学，2019.(LUO Qingping. VideoLog Network HD Downhole TV[M. S. Thesis][D]. Xi?an：Xi?an Shiyou University，2019.(in Chinese))
[28]	向英. 井下电视成像技术在水库工程勘察中的应用[J]. 地下水，2024，46(4)：184-185.(XIANG Ying. Application of downhole television imaging technology in reservoir engineering investigation[J]. Groundwater，2024，46(4)：184-185.(in Chinese))
[29]	刘四新，王文天，傅磊，等. 基于BS-MUSIC的定向钻孔雷达三维成像算法[J]. 地球物理学报，2017，60(12)：4 928-4 937.(LIU Sixin，WANG Wentian，FU Lei，et al. 3D borehole radar imaging method based on BS-MUSIC[J]. Chinese Journal of Geophysics，2017，60(12)：4 928-4 937.(in Chinese))
[30]	李术才，许振浩，黄鑫，等. 隧道突水突泥致灾构造分类、地质判识、孕灾模式与典型案例分析[J]. 岩石力学与工程学报，2018，37(5)：1 041-1 069.(LI Shucai，XU Zhenhao，HUANG Xin，et al. Classification，geological identification，hazard mode and typical case studies of hazard-causing structures for water and mud inrush in tunnels[J]. Chinese Journal of Rock Mechanics and Engineering，2018，37(5)：1 041-1 069.(in Chinese))
[31]	姚林林，张世殊，崔中涛，等. 双护盾TBM施工综合超前地质预报技术探讨[J]. 地下空间与工程学报，2019，5(5)：1 549-1 556. (YAO Linlin，ZHANG Shishu，CUI Zhongtao，et al. Discussion on comprehensive advanced geological prediction technology in double-shield TBM construction[J]. Chinese Journal of Underground Space and Engineering，2019，5(5)：1 549-1 556.(in Chinese))
[32]	姚林林，张世殊，彭仕雄，等. 双护盾TBM环境下TRT测试震源激发气锤[P]. 中国：ZL201920937075.0，2019-12-31.(YAO Linlin，ZHANG Shishu，PENG Shixiong，et al. Pneumatic hammer for seismic source stimulation in trt testing under double-shield TBM environment[P]. China：ZL201920937075.0，2019-12-31.(in Chinese))
[33]	PETRONIO L，POLETTO F. Seismic-while-drilling by using tunnel boring machine noise[J]. Geophysics，2002，67(6)：1 798-1 809.
[34]	NILOT E A，FANG G，LI E，et al. Real-time tunneling risk forecasting using vibrations from the working TBM[J]. Tunnelling and Underground Space Technology，2023，139：105213.
[35]	李术才，王鑫，郭伟东，等. 钻爆法机械化施工隧道随钻地震波超前地质探测技术研究[J]. 隧道建设(中英文)，2024，44(4)：617-632.(LI Shucai，WANG Xin，GUO Weidong，et al. An advance geological detection technology of seismic wave while drilling in mechanized tunnel construction by drilling and blasting method[J]. Tunnel Construction，2024，44(4)：617-632.(in Chinese))
[36]	KAUS A，BOENING W. BEAM-Geoelectrical Ahead onitoring for TBM-Drives[J]. Geomechanik and Tunnelbau，2008，1(5)：442-449.
[37]	李术才，聂利超，刘斌，等. 多同性源阵列电阻率法隧道超前探测方法与物理模拟试验研究[J]. 地球物理学报，2015，58(4)：1 434-1 446.(LI Shucai，NIE Lichao，LIU Bin，et al. Advanced detection and physical model test based on multi-electrode sources array resistivity method in tunnel[J]. Chinese Journal of Geophysics，2015，58(4)：1 434-1 446.(in Chinese))
[38]	MA J J，MA C C，LI T B，et al. Real-time classification model for tunnel surrounding rocks based on high-resolution neural network and structure-optimizer hyperparameter optimization[J]. Computers and Geotechnics，2024，168：106155.
[39]	LIU Q，WANG X，HUANG X，et al. Prediction model of rock mass class using classification and regression tree integrated AdaBoost algorithm based on TBM driving data[J]. Tunnelling and Underground Space Technology，2020，106：103595.
[40]	QIU D，FU K，XUE Y，et al. TBM tunnel surrounding rock classification method and real-time identification model based on tunneling performance[J]. International Journal of Geomechanics，2022，22(6)：04022070.
[41]	WU Z，WEI R，CHU Z，et al. Real-time rock mass condition prediction with TBM tunneling big data using a novel rock-machine mutual feedback perception method[J]. Journal of Rock Mechanics and Geotechnical Engineering，2021，13(6)：1 311-1 325.
[42]	ZHANG Q，LIU Z，TAN J. Prediction of geological conditions for a tunnel boring machine using big operational data[J]. Automation in Construction，2019，100：73-83.
[43]	朱梦琦，朱合华，王昕，等. 基于集成CART算法的TBM掘进参数与围岩等级预测[J]. 岩石力学与工程学报，2020，39(9)：1 860- 1 871.(ZHU Mengqi，ZHU Hehua，WANG Xin，et al. Study on CART-based ensemble learning algorithms for predicting TBM tunneling parameters and classing surrounding rockmasses[J]. Chinese Journal of Rock Mechanics and Engineering，2020，39(9)：1 860- 1 871.(in Chinese))
[44]	李青松，石豫川，周春宏. 多元回归法在某水电站TBM施工隧洞围岩质量预测中的应用[J]. 长江科学院院报，2012，29(2)：41-45. (LI Qingsong，SHI Yuchuan，ZHOU Chunhong. Application of multiple regression method to the prediction of surrounding rockmass quality for TBM-excavated tunnels of hydropower station[J]. Journal of Yangtze River Scientific Research Institute，2012，29(2)：41-45.(in Chinese))
[45]	GUI M W，SOGA K，BOLTON M D，et al. Instrumented borehole drilling for subsurface investigation[J]. Journal of Geotechnical and Geoenvironmental Engineering，2002，128(4)：283-291.
[46]	王琦，高红科，蒋振华，等. 地下工程围岩数字钻探测试系统研发与应用[J]. 岩石力学与工程学报，2020，39(2)：301-310.(WANG Qi，GAO Hongke，JIANG Zhenhua，et al. Development and application of a surrounding rock digital drilling test system of underground engineering[J]. Chinese Journal of Rock Mechanics and Engineering，2020，39(2)：301-310.(in Chinese))
[47]	LI S J，XU H S，ZHENG M Z，et al. Evaluating the structure and mechanical properties of deep rock masses based on drilling process monitoring and borehole televiewer[J]. Bulletin of Engineering Geology and the Environment，2023，82(10)：395.
[48]	TEALE R. The concept of specific energy in rock drilling[J]. International Journal of Rock Mechanics and Mining Sciences and Geomechanics Abstracts，1965，2(1)：57-73.
[49]	KARASAWA H，OHNO T，KOSUGI M，et al. Methods to estimate the rock strength and tooth wear while drilling with roller-bits—part 2：insert bits[J]. Journal of Energy Resources Technology，2002，124(3)：133-140.
[50]	HE M M，ZHANG Z Q，ZHU J W，et al. Correlation between the constant mi of Hoek-Brown criterion and porosity of intact rock[J]. Rock Mechanics and Rock Engineering，2022，55：923-936.
[51]	WANG X F，ZHANG M S，YUE Z Q. In-situ digital profiling of soil to rock strength from drilling process monitoring of 200 m deep drill hole in loess ground[J]. International Journal of Rock Mechanics and Mining Sciences，2021，142：104739.
[52]	GAO H K，WANG Q，MA F L，et al. The identification method for rock strength and joint while drilling based on cutting energy density[J]. Journal of Central South University，2024，31(2)：621-635.
[53]	FLEGNER P，KA?UR J，DURDÁN M，et al. Processing a measured vibroacoustic signal for rock type recognition in rotary drilling technology[J]. Measurement，2019，134：451-467.
[54]	ROSTAMI J，KAHRAMAN S，NAEIMIPOUR A，et al. Rock characterization while drilling and application of roof bolter drilling data for evaluation of ground conditions[J]. Journal of Rock Mechanics and Geotechnical Engineering，2015，7(3)：273-281.
[55]	KAHRAMAN S，ROSTAMI J，NAEIMIPOUR A. Review of ground characterization by using instrumented drills for underground mining and construction[J]. Rock Mechanics and Rock Engineering，2016，49：585-602.
[56]	ISRM. Rock characterization，testing and monitoring，ISRM suggested methods[M]. Oxford：Pergamon Press，1981：159-187.
[57]	潘义辉，闫冬飞. 结构面原位剪切试验在宗格鲁水电站中的应用[J]. 云南水力发电，2019，35(1)：38-43.(PAN Yihui，YAN Dongfei. Application of in-situ shear test of structural plane in Zonggelu hydropower station[J]. Yunnan Water Power，2019，35(1)：38-43.(in Chinese))
[58]	FRANKLIN J A，PELLS P，MCLACHLIN D，等. 测定点荷载强度的建议方法(1985年修订，取代1972年版本)[J]. 岩石力学与工程学报，1986，(1)：81-92.(FRANKLIN J A，PELLS P，MCLACHLIN D，et al. Suggested Method for Determining Point Load Strength (Revised 1985，Replaces of 1972 Version)[J]. Chinese Journal of Rock Mechanics and Engineering，1986，(1)：81-92.(in Chinese))
[59]	XIE W Q，ZHANG X P，LIU Q S，et al. Experimental investigation of rock strength using indentation test and point load test[J]. International Journal of Rock Mechanics and Mining Sciences，2021，139(1)：104647.
[60]	BCH A，FHC B. 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.
[61]	CORNET F H，VALETTE B. In situ stress determination from hydraulic injection test data[J]. Journal of Geophysical Research Solid Earth，1984，89：11 527-11 537.
[62]	TE KAMP L. Hydrofrac stress profile to 9 km at the German KTB site[C]// Proceedings of the Workshop on Rock Stresses in the North Sea. [S. l.]：[s. n.]，1995：19-22.
[63]	李邵军，郑民总. 基于光纤光栅的深部硬岩隧洞三维扰动应力测试系统研制及工程应用[J]. 岩石力学与工程学报，2024，43(2)：261-274.(LI Shaojun，ZHENG Minzong. Development and engineering application of three-dimensional disturbed stress measurement system for deep hard rock engineering based on fiber bragg grating[J]. Chinese Journal of Rock Mechanics and Engineering，2024，43(2)：261-274.(in Chinese))
[64]	刘允芳，朱杰兵，刘元坤. 空心包体式钻孔三向应变计地应力测量的研究[J]. 岩石力学与工程学报，2001，20(4)：448-453.(LIU Yunfang，ZHU Jiebing，LIU Yuankun. Research on hollow inclusion triaxial strain gauge for geostress measurement[J]. Chinese Journal of Rock Mechanics and Engineering，2001，20(4)：448-453.(in Chinese))
[65]	王益腾. 基于钻孔形态的地应力测试方法及地应力场反演研究[博士学位论文][D]. 北京：中国科学院大学，2019.(WANG Yiteng. Research on in-situ stress measurement method based on borehole morphology and inversion of stress field[Ph. D. Thesis][D]. Beijing：University of Chinese Academy of Sciences，2019.(in Chinese))
[66]	葛修润，侯明勋. 钻孔局部壁面应力解除法(BWSRM)的原理及其在锦屏二级水电站工程中的初步应用[J]. 中国科学：技术科学，2012，42(4)：10.(GE Xiurun，HOU Mingxun. Principle of in-situ 3D rock stress measurement with borehole wall stress relief method and its preliminary applications to determination of in-situ rock stress orientation and magnitude in Jinping hydropower station[J]. Scientia Sinica(Technologica)，2012，42(4)：10.(in Chinese))
[67]	FUNATO A，ITO T. Laboratory verification of the diametrical core deformation analysis(DCDA) developed for in-situ rock stress measurements[J]. Shigen-to-Sozai，2014，129(8/9)：577-584.
[68]	BARTON N. Some new Q-value correlations to assist in site characterization and tunnel design[J]. International Journal of Rock Mechanics and Mining Sciences，2002，39(2)：185-216.
[69]	李维树，周火明，陈华，等. 构皮滩水电站高拱坝建基面卸荷岩体变形参数研究[J]. 岩石力学与工程学报，2010，29(7)：1 333-1 338. (LI Weishu，ZHOU Huoming，CHEN Hua，et al. Study of unloading rock mass deformation parameters for high arch dam foundation base of Goupitan hydropower station[J]. Chinese Journal of Rock Mechanics and Engineering，2010，29(7)：1 333-1 338.(in Chinese))
[70]	AGLIARDI F，SAPIGNI M，CROSTA G B. Rock mass characterization by high-resolution sonic and GSI borehole logging[J]. Rock Mechanics and Rock Engineering，2016，49：4 303-4 318.
[71]	闫长斌，徐国元. 对Hoek-Brown公式的改进及其工程应用[J]. 岩石力学与工程学报，2005，24(22)：4 030-4 035.(YAN Changbin，XU Guoyuan. Modification of Hoek-Brown expressions and its application to engineering[J]. Chinese Journal of Rock Mechanics and Engineering，2005，24(22)：4 030-4 035.(in Chinese))
[72]	杨静熙，黄书岭，刘忠绪. 锦屏一级水电站工程岩体对穿声波与单孔声波关联性探讨[J]. 岩土力学，2020，41(4)：1 347-1 356. (YANG Jingxi，HUANG Shuling，LIU Zhongxu，et al. Study on the relationship between cross-hole sonic wave and single-hole sonic wave of rock mass at Jinping I hydropower station[J]. Rock and Soil Mechanics，2020，41(4)：1 347-1 356.(in Chinese))
[73]	AL-SIT W，AL-NUAIMY W，MARELLI M，et al. Visual texture for automated characterisation of geological features in borehole televiewer imagery[J]. Journal of Applied Geophysics，2015，119：139-146.
[74]	LI S J，FENG X T，WANG C Y，et al. ISRM suggested method for rock fractures observations using a borehole digital optical televiewer[J]. Rock Mechanics and Rock Engineering，2013，46(3)：635-644.
[75]	李术才，刘斌，孙怀凤，等. 隧道施工超前地质预报研究现状及发展趋势[J]. 岩石力学与工程学报，2014，33(6)：1 090-1 113.(LI Shucai，LIU Bin，SUN Huaifeng，et al. State of art and trends of advanced geological prediction in tunnel construction[J]. Chinese Journal of Rock Mechanics and Engineering，2014，33(6)：1 090- 1 113.(in Chinese))
[76]	EBIHARA S，SATO M，NIITSUMA H. Super-resolution of coherent targets by a directional borehole radar[J]. IEEE Transactions on Geoscience and Remote Sensing，2000，38(4)：1 725-1 732.
[77]	刘四新，王文天，傅磊，等. 基于BS-MUSIC的定向钻孔雷达三维成像算法[J]. 地球物理学报，2017，60(12)：10.(LIU Sixin，WANG Wentian，FU Lei，et al. 3D borehole radar imaging method based on BS-MUSIC[J]. Chinese Journal of Geophysics，2017，60(12)：10.(in Chinese))
[78]	申艳军，徐光黎，宋胜武，等. 高地应力区水电工程围岩分类法系统研究[J]. 岩石力学与工程学报，2014，33(11)：2 267-2 275. (SHEN Yanjun，XU Guangli，SONG Shengwu，et al. A classification method of surrounding rock mass in hydropower project in high geostress area[J]. Chinese Journal of Rock Mechanics and Engineering，2014，33(11)：2 267-2 275.(in Chinese))
[79]	刘泉声，许锡昌. 温度作用下脆性岩石的损伤分析[J]. 岩石力学与工程学报，2000，19(4)：408-411.(LIU Quansheng，XU Xichang. Damage analysis of brittle rock at high temperature[J]. Chinese Journal of Rock Mechanics and Engineering，2000，19(4)：408- 411.(in Chinese))
[80]	陈国庆，李天斌，张岩，等. 花岗岩隧道脆性破坏的温度效应研究[J]. 岩土力学，2013，34(12)：3 513-3 519.(CHEN Guoqing，LI Tianbin，ZHANG Yan，et al. Thermal effect of brittle failure for granite tunnel[J]. Rock and Soil Mechanics，2013，34(12)：3 513-3 519. (in Chinese))
[81]	申艳军，徐光黎，魏志云. 大跨度地下洞室集成化围岩分类体系构建及可视化程序实现[J]. 现代隧道技术，2014，51(4)：28-38. (SHEN Yanjun，XU Guangli，WEI Zhiyun. Establishment and visualization of an integrated surrounding-rock classification system for large-span underground caverns[J]. Modern Tunneling Technology，2014，51(4)：28-38.(in Chinese))
[82]	马显东，周剑，张路青，等. 强震区公路沿线崩塌危岩体特征提取及失稳分析[J]. 岩石力学与工程学报，2022，41(增1)：2 901-2 914. (MA Xiandong，ZHOU Jian，ZHANG Luqing，et al. Feature extraction and instability analysis of dangerous rock mass along highway in meizoseismal areas[J]. Chinese Journal of Rock Mechanics and Engineering，2022，41(Supp.1)：2 901-2 914.(in Chinese))
[83]	许振浩，邵瑞琦，林鹏，等. 隧道不良地质识别：方法、现状及智能化发展方向[J]. 地球学报，2024，45(1)：5-24.(XU Zhenhao，SHAO Ruiqi，LIN Peng，et al. Adverse geology identification in tunnel：method，research status and intelligent development direction[J]. Acta Geoscientica Sinica，2024，45(1)：5-24.(in Chinese))
[84]	BARTON N. Some new Q-value correlations to assist in site characterisation and tunnel design[J]. International Journal of Rock Mechanics and Mining Sciences，2002，39(2)：185-216.
[85]	YANG J. Estimation of rock mass properties in excavation damage zones of rock slopes based on the Hoek-Brown criterion and acoustic testing[J]. International Journal of Rock Mechanics and Mining Sciences，2020，126：104192.
[86]	HOEK E，WOOD D，SHAH S. A modified Hoek-Brown failure criterion for jointed rock masses[C]// Proceedings of the International ISRM Symposium Proceedings of the International ISRM Symposium. Chester，UK：Thomas Telford Publishing，1992：209-214.
[87]	HOEK E，BROWN E T. The Hoek-Brown failure criterion-a 1998 update[J]. Journal of Heuristics，1988，16(2)：167-188.
[88]	HOEK E，BROWN E T. Practical estimates of rock mass strength[J]. International Journal of Rock Mechanics and Mining Sciences，1997，34(8)：1 165-1 186.
[89]	夏开宗，刘夏临，林英书，等. 基于岩体波速的地下洞室围岩损伤区岩体力学参数取值方法及工程应用[J]. 岩石力学与工程学报，2024，43(10)：2 414-2 429.(XIA Kaizong，LIU Xialin，LIN Yingshu，et al. A method for determining mechanical parameter values of rock mass in the damage zone of surrounding rocks of underground caverns based on wave velocities of rock mass and its engineering application[J]. Chinese Journal of Rock Mechanics and Engineering，2024，43(10)：2 414-2 429.(in Chinese))
[90]	冯夏庭，杨成祥. 深部工程硬岩力学[M]. 北京：科学出版社，2023：447-455.(FENG Xiating，YANG Chengxiang. Hard rock mechanics in deep engineering[M]. Beijing：Science Press，2023：447-455.(in Chinese))