|
|
|
| Experimental study on shear properties of red sandstone joints after cyclic wetting-drying treatment |
| LIU Xing1,TANG Zhicheng1,LI Lu1,ZHANG Qingzhao2,SU Feng3 |
| (1. Faculty of Engineering,China University of Geosciences,Wuhan,Hubei 430074,China;2. Department of Geotechnical Engineering,Tongji University,Shanghai 200092,China;3. Northwest Engineering Corporation Limited,Power China,Xi'an,Shaanxi 710065,China) |
|
|
|
|
Abstract In order to study the effect of wetting and drying cycles on the shear mechanical properties of jointed rock mass,joint samples with a JRC range of 5.20 ± 0.25 were selected by tilt test,and the direct shear tests of red sandstone joints with different numbers of wetting-drying cycles were carried out under constant normal stress. At the beginning of the wetting-drying cycle,the peak shear displacement of the joints increased first and then decreased,and increased after 8 wetting-drying cycles. As the number of wetting and drying cycle increased,the shear stiffness of joints gradually decreased,especially under low normal stress. After 16 wetting-drying cycles,the peak shear strength of sandstone joints decreased by 12.41%–23.77%. The influence of wetting and drying cycles weakened with the increase of cycle times,and the deterioration degree of peak shear strength of joints under high normal stress decreased. The cohesion and friction angle deteriorated significantly when the number of wetting and drying cycles is small. Under the same number of cycles,the degree of degradation of the cohesion is greater than the friction angle. The degree of joint surface damage increased with the increase of the number of wetting and drying cycles. After 4 wetting-drying cycles,the degree of damage tended to be stable. Under the action of wetting and drying cycles,the shear mechanical properties of joints are significantly degraded. The generation and expansion of cracks and fissures near the joint surface is the cause of the deterioration of shear mechanical parameters.
|
|
|
|
|
|
| [1] ALLAM M M,SRIDHARAN A. Effect of wetting and drying on shear strength[J]. Journal of the Soil Mechanics and Foundations Division,1981,107(4):421–438.
[2] FAQUAN W,SHENGWEN Q,HENGXING L. Mechanism of uplift deformation of the dam foundation of Jiangya Water Power Station,Hunan Province,PR China[J]. Hydrogeology Journal,2005,13(3):451–466.
[3] QIN Z,CHEN X X,FU H L,et al. Damage features of altered rock subjected to drying-wetting cycles[J]. Advances in Civil Engineering,2018,2018(5):1–10.
[4] 陈开圣. 干湿循环下红黏土裂隙演化规律及对抗剪强度影响[J]. 水文地质工程地质,2018,45(1):89–95.(CHEN Kaisheng,Evolution of cracks in red clay under wetting-drying cycles and its influence on shear strength[J]. Hydrogeology and Engineering Geology,2018,45(1):89–95.(in Chinese))
[5] 刘新荣,王子娟,傅 晏,等. 考虑干湿循环作用泥质砂岩的强度与破坏准则研究[J]. 岩土力学,2017,38(12):3 395–3 401.(LIU Xinrong,WANG Zijuan,FU Yan,et al. Strength and failure criterion of argillaceous sandstone under dry-wet cycles[J]. Rock and Soil Mechanics,2017,38(12):3 395–3 401.(in Chinese))
[6] 马芹永,郁培阳,袁 璞. 干湿循环对深部粉砂岩蠕变特性影响的试验研究[J]. 岩石力学与工程学报,2018,37(3):593–600.(MA Qinyong,YU Peiyang,YUAN Pu. Experimental study on creep properties of deep siltstone under cyclic wetting and drying[J]. Chinese Journal of Rock Mechanics and Engineering,2018,37(3):593–600.(in Chinese))
[7] ALDAOOD A,BOUASKER M,AL-MUKHTAR M. Impact of wetting-drying cycles on the microstructure and mechanical properties of lime-stabilized gypseous soils[J]. Engineering Geology,2014,174:11–21.
[8] STOLTZ G,CUISINIER O,MASROURI F. Weathering of a lime-treated clayey soil by drying and wetting cycles[J]. Engineering Geology,2014,181:281–289.
[9] SUN Q,ZHANG Y. Combined effects of salt,cyclic wetting and drying cycles on the physical and mechanical properties of sandstone[J]. Engineering Geology,2019,248:70–79.
[10] HUA W,DONG S,LI Y,et al. The influence of cyclic wetting and drying on the fracture toughness of sandstone[J]. International Journal of Rock Mechanics and Mining Sciences,2015,78:331–335.
[11] ZHOU Z,CAI X,CHEN L,et al. Influence of cyclic wetting and drying on physical and dynamic compressive properties of sandstone[J]. Engineering Geology,2017,220:1–12.
[12] 蔡美峰,何满潮,刘东燕. 岩石力学与工程[M]. 北京:科学出版社,2013:107–113.(CAI Meifeng,HE Manchao,LIU Dongyan. Rock mechanics and engineering[M]. Beijing:Science Press,2013:107–113.(in Chinese))
[13] 李 鹏,刘 建. 不同含水率软弱结构面剪切蠕变试验及模型研究[J]. 水文地质工程地质,2009,36(6):49–53.(LI Peng,LIU Jian. Shear creep test and model study on weak structure surface with different moisture content[J]. Hydrogeology and Engineering Geology,2009,36(6):49–53.(in Chinese))
[14] ZHAO Z,YANG J,ZHOU D,et al. Experimental investigation on the wetting-induced weakening of sandstone joints[J]. Engineering Geology,2017,225:61–67.
[15] TANG Z C,ZHANG Q Z,PENG J,et al. Experimental study on the water-weakening shear behaviors of sandstone joints collected from the middle region of Yunnan province,P.R. China[J]. Engineering Geology,2019,258:105–161.
[16] MU J,PEI X,HUANG R,et al. Degradation characteristics of shear strength of joints in three rock types due to cyclic freezing and thawing[J]. Cold Regions Science and Technology,2017,138:91–97.
[17] 邓华锋,段玲玲,支永艳,等. 干湿循环作用下节理面剪切力学特性演化规律[J]. 岩石力学与工程学报,2018,37(增2):3 958–3 967.(DENG Huafeng,DUAN Lingling,ZHI Yongyan,et al. Evolution of shear mechanical properties of jointed surface under dry-wet cycle[J]. Chinese Journal of Rock Mechanics and Engineering,2018,37(Supp.2):3 958–3 967.(in Chinese))
[18] 中华人民共和国行业标准编写组. SL264—2001水利水电工程岩石试验规程[S]. 北京:中国水利水电出版社,2001.( The Professional Standards Compilation Group of People's Republic of China. SL264—2001 Code for rock testing in water conservancy hydropower projects[S]. Beijing:China Water Power Press,2001.(in Chinese))
[19] XIA C C,TANG Z C,XIAO W M,et al. New peak shear strength criterion of rock joints based on quantified surface description[J]. Rock Mechanics and Rock Engineering,2014,47(2):387–400.
[20] ALEJANO L R,MURALHA J,ULUSAY R,et al. ISRM suggested method for determining the basic friction angle of planar rock surfaces by means of tilt tests[J]. Rock Mechanics and Rock Engineering,2018,51(12):3 853–3 859.
[21] BARTON N. Review of a new shear-strength criterion for rock joints[J]. Engineering Geology,1973,7(4):287–332.
[22] BARTON N,CHOUBEY V. The shear strength of rock joints in theory and practice[J]. Rock mechanics,1977,10(1/2):1–54.
[23] ALEJANO L R,MURALHA J,ULUSAY R,et al. A benchmark experiment to assess factors affecting tilt test results for sawcut rock surfaces[J]. Rock Mechanics and Rock Engineering,2017,50(9): 2 547–2 562.
[24] MURALHA J,GRASSELLI G,TATONE B,et al. ISRM suggested method for laboratory determination of the shear strength of rock joints:revised version[J]. Rock Mechanics and Rock Engineering,2014,47(1):291–302.
[25] TANG Z C,HUANG R Q,LIU Q S,et al. Effect of contact state on the shear behavior of artificial rock joint[J]. Bulletin of Engineering Geology and the Environment,2016,75(2):761–769.
[26] CHEN Y,CAO P,MAO D W,et al. Morphological analysis of sheared rock with water–rock interaction effect[J]. International Journal of Rock Mechanics and Mining Sciences,2014,70:264–272.
[27] RISS J,GENTIER S,ARCHAMBAULT G,et al. Sheared rock joints:dependence of damage zones on morphological anisotropy[J]. International Journal of Rock Mechanics and Mining Sciences,1997,34(3/4):251–258.
[28] NOUAILLETAS O,PERLOT C,RIVARD P,et al. Impact of acid attack on the shear behaviour of a carbonate rock joint[J]. Rock Mechanics and Rock Engineering,2017,50(6):1 439–1 451.
[29] 邓华锋,李建林,朱 敏,等. 饱水-风干循环作用下砂岩强度劣化规律试验研究[J]. 岩土力学,2012,33(11):3 306–3 312.(DENG Huafeng,LI Jianlin,ZHU Min,et al. Experimental research on strength deterioration rules of sandstone under “saturation-air dry” circulation function[J]. Rock and Soil Mechanics,2012,33(11):3 306–3 312.(in Chinese))
[30] ZHANG B Y,ZHANG J H,SUN G L. Deformation and shear strength of rockfill materials composed of soft siltstones subjected to stress,cyclical drying/wetting and temperature variations[J]. Engineering Geology,2015,190:87–97.
[31] 陈宇龙,张 科,孙 欢. 冻融循环作用下岩石表面裂纹扩展过程细观研究[J]. 土木工程学报,2019,52(增1):1–7.(CHEN Yulong,ZHANG Ke,SUN Huan. Meso-research on the development of rock surface crack under freeze-thaw cycles[J]. China Civil Engineering Journal,2019,52(Supp.1):1–7.(in Chinese))
|
|
|
|
2020, Vol. 39 
