岩石厚壁圆筒试验破坏的细观力学机制

doi:10.13722/j.cnki.jrme.2015.1447

摘要
图/表
参考文献
相关文章 (15)

全文: PDF (835 KB) HTML (1 KB)
输出: BibTeX | EndNote (RIS)

摘要目前采用传统颗粒体模型较难表征岩石内部不规则矿物颗粒的结构特征。以颗粒流理论及PFC程序为平台，采用平面黏结接触模型，构建能反映矿物颗粒结构特征的岩石厚壁圆筒数值模型，从细观力学角度深入探究岩石厚壁圆筒试样在不同内外部围压条件下的破裂机制与规律。研究表明：当内部围压为0时，试样张拉型微破裂占主导优势；层状剥离的破碎颗粒体以轴线为中心形成近似对称的“V”型破坏区域。当内部围压不为0时，随着内部围压不断增大，试样承受的极限外部围压逐渐增大；试样剪切型微破裂逐渐占主导优势，以轴线为中心产生的近似对称的“V”型破坏区域逐渐消退，破坏逐渐从内径岩壁向各个方向扩展。无论内部围压是否为0，试样外部围压、外部体应变等破坏参量演化曲线均可近似划分为3个阶段。

	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
	周喻
	吴庆良
	杜晓伟
	吴顺川
	高永涛

关键词 ：岩石力学, 厚壁圆筒试验, 颗粒流理论, 平面黏结接触模型, 细观力学机制

Abstract：At present，the conventional bonded particle model is difficult to represent the irregular structural feature of mineral grains in rock. A numerical model of thick-walled hollow cylinder of rock to reflect the feature of mineral grain in rock was established using the flat-joint contact model based upon the particle flow theory and PFC code. The failure mechanism and law of thick-walled hollow cylinder of rock with the different inner and external pressures were investigated from the meso mechanical viewpoint. When inner pressure was equal to zero，the microcracks were mainly tensile type in the failure process and the spalling fragmentation particles formed a V-shaped damage area symmetrical to the cylinder axis. When the inner pressure was not equal to zero，the limiting external pressure increased and the shear microcracks gradually dominated in the failure process with the increase of the inner pressures. Meanwhile，the symmetrical V-shaped damage area in the specimen receded and the failure expanded towards all the directions from the inner rock face. With or without the inner pressure， the variation of the failure parameters such as the external pressure and the external volume strain can be divided into three stages.

Key words： rock mechanics thick-walled hollow cylinder test particle flow theory flat-joint contact model meso mechanical mechanisms

引用本文:

周喻，吴庆良，杜晓伟，吴顺川，高永涛. 岩石厚壁圆筒试验破坏的细观力学机制[J]. 岩石力学与工程学报, 2016, 35(9): 1854-1863.
ZHOU Yu，WU Qingliang，DU Xiaowei，WU Shunchuan，GAO Yongtao. Meso mechanical mechanisms of thick-walled hollow rock cylinder during failure process. , 2016, 35(9): 1854-1863.

链接本文:

http://www.rockmech.org/CN/10.13722/j.cnki.jrme.2015.1447 或 http://www.rockmech.org/CN/Y2016/V35/I9/1854

[15]	JAEGER J C. Elasticity，fracture and flow：with engineering and geological applications[M]. New York：Wiley Press，1956：157-158. " target="_blank">
[12]	DIEDERICHS M S. Instablity of hard rock masses，the role of tensile damage and relaxation[Ph. D. Thesis][D]. Waterloo：University of Waterloo，1999. " target="_blank">
[5]	DAEMEN J J K，FAIRHURSK C. Influence of failed rock properties on tunnel stability[C] // The 12th US Symposium on Rock Mechanics. New York：AIME，1970：855-875. " target="_blank">
[1]	HOSKINS E R. The failure of thick-walled hollow cylinders of isotropic rock[J]. International Journal of Rock Mechanics and Mining Sciences，1969，6(1)：99-125. " target="_blank">
[4]	张后全，刘红岗，贺永年，等. 岩石厚壁圆筒三向压缩下的卸荷试验与岩石强度破坏[J]. 北京科技大学学报，2011，33(7)：800-805. (ZHANG Houquan，LIU Honggang，HE Yongnian，et al. Unloading experiment and rock strength failure of rock thick-walled cylinders under triaxial compression[J]. Journal of University of Science and Technology Beijing，2011，33(7)：800-805.(in Chinese))
[6]	FANTILLI A P，VALLINI P. Crushing failure in hollow cylinders made of quasi-brittle materials[J]. Computers and Structures，2010，88(7)：426-436. " target="_blank">
[13]	CHO N，MARTIN C D，SEGO D C. A clumped particle model for rock[J]. International Journal of Rock Mechanics and Mining Sciences，2007，44(7)：997-1 010.
[2]	EWY R T，COOK N G W，MYER L R. Hollow cylinder tests for studying fracture around underground openings[C]// The 29th US Symposium on Rock Mechanics. Rotterdam：Balkema，1986：67-74. " target="_blank">
[9]	POTYONDY D O，CUNDALL P A. A bonded-particle model for rock[J]. International Journal of Rock Mechanics and Mining Sciences，2004，41(8)：1 329-1 364. " target="_blank">
[11]	周喻，高永涛，吴顺川，等. 等效晶质模型及岩石力学特征细观研究[J]. 岩石力学与工程学报，2015，34(3)：511-519.(ZHOU Yu，GAO Yongtao，WU Shunchuan，et al. An equivalent crystal model for mesoscopic behaviour of rock[J]. Chinese Journal of Rock Mechanics and Engineering，2015，34(3)：511-519.(in Chinese))
[18]	WU T H，LOH A，MALVERN L. Study of the failure envelope of soils[J]. Journal of Soil Mechanics and Foundation Engineering，1963，89(S. M. 1)：145-181. " target="_blank">
[7]	CUNDALL P A，STRACK O D L. A discrete numerical model for granular assemblies[J]. Geotechnique，1979，29(1)：47-65. " target="_blank">
[16]	ROBERTSON E C. Experimental study of the strength of rocks[J]. Bullitin of Geology Society of America，1955，66(1)：1 275-1 314. " target="_blank">
[3]	ALSAYED M I. Utilising the Hoek triaxial cell for multiaxial testing of hollow rock cylinders[J]. International Journal of Rock Mechanics and Mining Sciences，2002，39(3)：355-366.
[8]	HAZZARD J F，YOUNG R P. Simulating acoustic emissions in bonded-particle models of rock[J]. International Journal of Rock Mechanics and Mining Sciences，2000，37(5)：867-872. " target="_blank">
[10]	吴顺川，周喻，高利立，等. 等效岩体技术在岩体工程中的应用[J]. 岩石力学与工程学报，2010，29(7)：1 435-1 441.(WU Shunchuan，ZHOU Yu，GAO Lili，et al. Application of equivalent rock mass technique to rock mass engineering[J]. Chinese Journal of Rock Mechanics and Engineering，2010，29(7)：1 435-1 441.(in Chinese))
[14]	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. " target="_blank">
[17]	MACGREGOR C W，COFFIN L F J，FISCHER J C. Partially plastic thick-walled tubes[J]. Journal of the Franklin Institute，1948，245(2)：135-158. " target="_blank">
[19]	GAY N C. Fracture growth around openings in thick-walled cylinders of rock subjected to hydrostatic compression[J]. International Journal of Rock Mechanics and Mining Sciences and Geomechnics Abstract，1973，10(3)：209-233. " target="_blank">