含不同胶结充填物的碳酸盐岩层面剪切力学特性试验研究

doi:10.13722/j.cnki.jrme.2015.0361

摘要
图/表
参考文献
相关文章 (15)

全文: PDF (761 KB) HTML (1 KB)
输出: BibTeX | EndNote (RIS)

摘要层面是层状岩体稳定性的主控结构面，层面的剪切力学行为及抗剪强度对建造于层状岩体中的地下工程具有重要影响。由于成岩时期物化作用的差异，同一工程场址常发育不同地质特征(胶结充填物、粗糙度等)的层面。为了深入了解不同类型层面的剪切力学特性，利用乌东德水电站地下厂房区域取得的胶结层面试样开展常法向应力及峰后降法向应力直剪试验。试验结果表明，不同地质特征的层面表现出不同的剪切力学行为，按有无明显峰值可将剪切变形–剪应力曲线分为2类，无明显峰值层面的粗糙度和表面附着物均有别于有明显峰值层面。法向变形与法向应力直接相关，但与层面类别之间的关系不明显。不同类型层面还表现出不同的剪胀行为及相应的剪胀角差异。胶结层面抗剪强度低于完整岩石但高于已分离层面，对层状岩体起弱化作用。按层面地质特征对其进行分类有助于进一步理解层状岩体的复杂力学行为，而选择不同层面力学模型可使计算更贴近实际工程岩体特征。

	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
	周扬一1
	冯夏庭1
	徐鼎平1
	李帅军1
	陈东方2

关键词 ：岩石力学, 层面, 层状岩体, 胶结层面, 法向刚度, 剪胀角, 剪切力学行为

Abstract：Bedding planes are of significant importance for the stability of layered rock mass. In order to perform detailed stability analysis for underground excavations in layered rock mass，it is necessary to gain sufficient knowledge of shear behavior and strength of bedding planes. Due to the complex physical and chemical processes involved during diagenesis，bedding planes exhibiting different geological features(cementation，roughness，etc) are often seen in a specific engineering site. In order to better characterize the shear behavior of these bedding planes，two types of shear tests，namely the constant normal stress tests and the post-peak stepwise-decreasing normal stress tests，were conducted using the cemented bedding plane samples obtained from underground caverns of Wudongde hydropower station. Test results showed that obviously different shear behavior corresponded to different geological features. The curves of shear displacement-shear stress were mainly divided into two groups according to their peak and residual behavior. The roughness and surface materials of groups with clear peak shear stress were different from the ones without peak. Direct relationship existed between the normal stiffness and normal stress，however，no obvious correlation was found between the normal stiffness and bedding plane types. Dilation behavior and the corresponding dilation angles of different kinds were also observed. The shear strength of cemented bedding planes is higher than the one of the separated bedding planes and lower than the one of the intact rock，which weakens the whole rock mass. A deeper understanding of rock mass behavior can be achieved when the geological variety of bedding planes is properly considered.

Key words： rock mechanics bedding plane layered rock mass cemented bedding plane normal stiffness dilation angle shear behavior

引用本文:

周扬一1，冯夏庭1，徐鼎平1，李帅军1，陈东方2. 含不同胶结充填物的碳酸盐岩层面剪切力学特性试验研究[J]. 岩石力学与工程学报, 2016, 35(6): 1161-1172.
ZHOU Yangyi1，FENG Xiating1，XU Dingping1，LI Shuaijun1，CHEN Dongfang2. Experimental study of the shear behavior of carbonate bedding planes cemented by different materials. , 2016, 35(6): 1161-1172.

链接本文:

http://www.rockmech.org/CN/10.13722/j.cnki.jrme.2015.0361 或 http://www.rockmech.org/CN/Y2016/V35/I6/1161

[10]	PLESHA M E. Constitutive models for rock discontinuities with dilatancy and surface degradation[J]. International Journal for Numerical and Analytical Methods in Geomechanics，1987，11(4)：345-362. " target="_blank">
[11]	BANDIS S，LUMSDEN A C，BARTON N R. Experimental studies of scale effects on the shear behaviour of rock joints[J]. International Journal of Rock Mechanics and Mining Sciences and Geomechanics Abstracts，1981，18(1)：1-21. " target="_blank">
[8]	BARTON N. The shear strength of rock and rock joints[J]. International Journal of Rock Mechanics and Mining Sciences and Geomechanics Abstracts，1976，13(9)：255-279. " target="_blank">
[1]	谷德振. 岩体工程地质力学基础[M]. 北京：科学出版社，1979：214-218.(GU Dezhen. Fundamentals of rock mass engineering geomechanics[M]. Beijing：Science Press，1979：214-218.(in Chinese)) " target="_blank">
[6]	BANDIS S C，LUMSDEN A C，BARTON N R. Fundamentals of rock joint deformation[J]. International Journal of Rock Mechanics and Mining Sciences and Geomechanics Abstracts，1983，20(6)：249-268. " target="_blank">
[15]	杜时贵，胡晓飞，郭霄，等. JRC-JCS 模型与直剪试验对比研究[J]. 岩石力学与工程学报，2008，27(增1)：2 747-2 753.(DU Shigui，HU Xiaofei，GUO Xiao，et al. Comparison study of JRC-JCS model and direct shear test[J]. Chinese Journal of Rock Mechanics and Engineering，2008，27(Supp.1)：2 747-2 753.(in Chinese)) " target="_blank">
[5]	黄曼，杜时贵，罗战友，等. 基于多尺度直剪试验的岩石模型结构面抗剪强度特征研究[J]. 岩土力学，2013，34(11)：3 180-3 186. (HUANG Man，DU Shigui，LUO Zhanyou，et al. Study of shear strength characteristic of simulation rock structural planes based on multi-size direct shear tests[J]. Rock and Soil Mechanics，2013，34(11)：3 180-3 186.(in Chinese)) " target="_blank">
[7]	BARTON N. Review of a new shear-strength criterion for rock joints[J]. Engineering Geology，1973，7(4)：287-332. " target="_blank">
[9]	GOODMAN R E. Methods of geological engineering in discontinuous rocks[M]. [s. l.]：West Publishing Company，1976：322-326. " target="_blank">
[13]	ZHAO J. Joint surface matching and shear strength part B：JRC-JMC shear strength criterion[J]. International Journal of Rock Mechanics and Mining Sciences，1997，34(2)：179-185. " target="_blank">
[14]	夏才初，肖维民，丁增志. 非贯通节理Jennings强度准则的岩桥弱化和节理面起伏角修正[J]. 岩石力学与工程学报，2010，29(3)：485-492.(XIA Caichu，XIAO Weimin，DING Zengzhi. Modification of Jennings strength criterion for intermittent joints considering rock bridge weakening and joint surface undulating angle[J]. Chinese Journal of Rock Mechanics and Engineering，2010，29(3)：485-492.(in Chinese))
[16]	GRASSELLI G，EGGER P. Constitutive law for the shear strength of rock joints based on three-dimensional surface parameters[J]. International Journal of Rock Mechanics and Mining Sciences，2003，40(1)：25-40.
[17]	BOULON M，ARMAND G，HOTEIT N，et al. Experimental investigations and modelling of shearing of calcite healed discontinuities of granodiorite under typical stresses[J]. Engineering Geology，2002，64(2)：117-133. " target="_blank">
[22]	USEFZADEH A，YOUSEFZADEH H，SALARI-RAD H，et al. Empirical and mathematical formulation of the shear behavior of rock joints[J]. Engineering Geology，2013，164：243-252. " target="_blank">
[23]	衡帅，杨春和，曾义金，等. 基于直剪试验的页岩强度各向异性研究[J]. 岩石力学与工程学报，2014，33(5)：874-883.(HENG Shuai，YANG Chunhe，ZENG Yijin，et al. Anisotropy of shear strength of shale based on direct shear test[J]. Chinese Journal of Rock Mechanics and Engineering，2014，33(5)：874-883.(in Chinese))
[18]	INDRARATNA B，OLIVEIRA D A F，BROWN E T，et al. Effect of soil-infilled joints on the stability of rock wedges formed in a tunnel roof[J]. International Journal of Rock Mechanics and Mining Sciences，2010，47(5)：739-751.
[21]	JING L，NORDLUND E，STEPHANSSON O. An experimental study on the anisotropy and stress-dependency of the strength and deformability of rock joints[J]. International Journal of Rock Mechanics and Mining Sciences and Geomechanics Abstracts，1992，29(6)：535-542. " target="_blank">
[24]	徐鼎平，冯夏庭，崔玉军，等. 白鹤滩水电站层间错动带的剪切特性[J]. 岩石力学与工程学报，2012，31(增1)：2 692-2 703.(XU Dingping，FENG Xiating，CUI Yujun，et al. Shear behaviors of interlayer staggered zone at Baihetan hydropower station[J]. Chinese Journal of Rock Mechanics and Engineering，2012，31(Supp.1)：2 692-2 703. (in Chinese)) " target="_blank">
[3]	HAMMETT R D，HOEK E. Design of large underground caverns for hydroelectric projects with particular reference to structurally controlled failure mechanisms[J]. Recent Developments in Geotechnical Engineering for Hydro Projects，1981：192-206. " target="_blank">
[4]	BARTON N，CHOUBEY V. The shear strength of rock joints in theory and practice[J]. Rock Mechanics，1977，10(1/2)：1-54. " target="_blank">
[12]	LADANYI B，ARCHAMBAULT G. Simulation of shear behavior of a jointed rock mass[C]// The 11th US Symposium on Rock Mechanics (USRMS). [S.l.]：American Rock Mechanics Association，1969：105-125. " target="_blank">
[19]	JING L，STEPHANSSON O，NORDLUND E. Study of rock joints under cyclic loading conditions[J]. Rock Mechanics and Rock Engineering，1993，26(3)：215-232. " target="_blank">
[20]	BROWN S R. Fluid flow through rock joints：the effect of surface roughness[J]. Journal of Geophysical Research：Solid Earth(1978—2012)，1987，92(B2)：1 337-1 347. " target="_blank">
[25]	LAJTAI E Z. Shear strength of weakness planes in rock[J]. International Journal of Rock Mechanics and Mining Sciences and Geomechanics Abstracts，1969，6(5)：499-515. " target="_blank">
[26]	JAEGER J C. Friction of rocks and stability of rock slopes[J]. Geotechnique，1971，21(2)：97-134. " target="_blank">
[2]	GOODMAN R E，SHI G. Block theory and its application to rock engineering[M]. New Jersey：Prentice-Hall，Inc.，1985：4-9. " target="_blank">