颗粒材料黏滑运动特征与颗粒黏结试验研究

doi:10.13722/j.cnki.jrme.2015.1462

Abstract
Figure/Table
References (0)
Related Citation (15)

Download: PDF (943 KB) HTML (1 KB)
Export: BibTeX | EndNote (RIS)

Abstract In order to investigate the stick-slip phenomenon and surface sintering of saturated granular materials，spherical soda lime glass beads were used to perform consolidated drained triaxial compression，single particle compression，oedometer and thermal melting tests. The triaxial compression experiment results showed that the stick-slip events of saturated and dense glass beads always appeared under higher confining stress. As increasing the confining stress，the mean amplitude drop of the deviatoric stress shows an exponential growth. At the slip phase，the abrupt drop of the deviatoric stress corresponds to the jump of volumetric strain. At the stick phase，the deviatoric stress increases gradually，showing strain strengthening characteristic. The sample volume contracts first and then dilates until the next slip phase. The consistency of the deviatoric stress and cell pressure is better than the pore water pressure because the cell pressure was more accurately measured. The single compression test，the oedometer test and the thermal melting test results show that in the ambient temperature condition，the sintering form of particles is totally different from the thermal melting in the high temperature condition. In the ambient temperature condition，due to the action of contacting and compressing，the surface of particles gradually dissolve and then re-precipitate on surrounding surface of glass beads，but with lower sintering strength and small morphologic change of glass beads.

Key words： soil test；stick-slip sintering soda lime glass beads triaxial compression test oedometer test

	Service

	E-mail this article
	Add to my bookshelf
	Add to citation manager
	E-mail Alert
	RSS
	Articles by authors
	CUI Deshan1
	XIANG Wei1
	2
	CHEN Qiong1
	WANG Shun3

Cite this article:

CUI Deshan1,XIANG Wei1,2, et al. Experimental study on stick-slip behaviour and sintering phenomenon of glass beads[J]. , 2016, 35(9): 1924-1935.

URL:

https://rockmech.whrsm.ac.cn/EN/10.13722/j.cnki.jrme.2015.1462 OR https://rockmech.whrsm.ac.cn/EN/Y2016/V35/I9/1924

[1] 王绳祖，张流. 剪切破裂与黏滑——浅源强震发震机制的研究[J]. 地震地质，1984，6(2)：63–73. (WANG Shengzu，ZHANG Liu. Shear fracture and stick-slip——a study on shock-generation mechanism of strong shallow earthquakes[J]. Seismology and Geology，1984，6(2)：63–73.(in Chinese))
[2] BRACE W F，BYERLEE J D. Stick-slip as a mechanism for earthquakes[J]. Science，1966，153(3739)：990–992.
[3] SCUDERI M M，CARPENTER B M，MARONE C. Physicochemical processes of frictional healing：effects of water on stick-slip stress drop and friction of granular fault gouge[J]. Journal of Geophysical Research：Solid Earth，2014，119(5)：4 090–4 105.
[4] DOANH T，DUBUJET P，PROTIERE X. On the undrained strain- induced anisotropy of loose sand[J]. Acta Geotechnica，2013，8(3)：293–309.
[5] HAREB H，DOANH T. Probing into the strain induced anisotropy of Hostun RF loose sand[J]. Granular Matter，2012，14(5)：589–605.
[6] DOANH T，HOANG M T，ROUX J N，et al. Stick-slip behaviour of model granular materials in drained triaxial compression[J]. Granular Matter，2013，15(1)：1–23.
[7] ADJEMIAN F，EVESQUE P. Experimental study of stick-slip behaviour[J]. International Journal for Numerical and Analytical Methods in Geomechanics，2004，28(6)：501–530.
[8] ROUSSEL L E. Experimental investigation of stick-slip behavior in granular materials[M. S. Thesis][D]. Louisiana：Louisiana State University，2005.
[9] KARNER S L，MARONE C. Effects of loading rate and normal stress on stress drop and stick-slip recurrence interval[J]. Geophysical Monograph-American Geophysical Union，2000，120：187–198.
[10] JOHNSON P A，SAVAGE H，KNUTH M，et al. Effects of acoustic waves on stick-slip in granular media and implications for earthquakes[J]. Nature，2008，451(7174)：57–60.
[11] BEN-DAVID O，RUBINSTEIN S M，FINEBERG J. Slip-stick and the evolution of frictional strength[J]. Nature，2010，463(7277)：76–79.
[12] 程海旭，吴开统，张流. 固体围压下完整花岗岩黏滑现象的实验研究[J]. 中国地震，1993，(3)：21–32.(CHENG Haixu，WU Kaitong，ZHANG Liu. Experimental study on the stick-slip phenomenon of intact granite under solid confining pressure[J]. Earthquake Research in China，1993，9(3)：21–32.(in Chinese))
[13] 杨主恩，张流，石桂梅. 黏滑和稳滑实验条件下石英岩的某些显微形貌特征及其地震地质意义[J]. 地震地质，1986，8(2)：22–25. (YANG Zhuen，ZHANG Liu，SHI Guimei. Some sem microtextures of quartzite from stick-slip and steady state slip experiments and their seismogeological significance[J]. Seismology and Geology，1986，8(2)：22–25.(in Chinese))
[14] 李建国，王绳祖，张渤涛，等. 固体三轴高压下红河断裂带周城断层泥力学性质的研究[J]. 岩土工程学报，1987，9(2)：39–48.(LI Jianguo，WANG Shengzu，ZHANG Botao，et al. Studies on the mechanical properties of Zhoucheng fault gouge of Honghe fault zone under high pressures[J]. Chinese Journal of Geotechnical Engineering，1987，9(2)：39–48.(in Chinese))
[15] 刘善军，吴立新，王金庄，等. 遥感–岩石力学(VI)——岩石摩擦滑移特征及其影响因素分析[J]. 岩石力学与工程学报，2004，23(8)：1 247–1 251.(LIU Shanjun，WU Lixin，WANG Jinzhuang，et al. Remote sensing-rock mechanics(VI)—features of rock friction-sliding and analysis on its influence factors[J]. Chinese Journal of Rock Mechanics and Engineering，2004，23(8)：1 247–1 251.(in Chinese))
[16] WILSON B，DEWERS T，RECHES Z E，et al. Particle size and energetics of gouge from earthquake rupture zones[J]. Nature，2005，434(7034)：749–752.
[17] DAS S，BOATWRIGHT J，SCHOLZ C H. Earthquake source mechanics[M]. [S. l.]：American Geophysical Union，1986.
[18] BRUCHON J，PINO-MUNOZ D，VALDIVIESO F，et al. Finite element simulation of mass transport during sintering of a granular packing. part I. surface and lattice diffusions[J]. Journal of the American Ceramic Society，2012，95(8)：2 398–2 405.