Mechanical properties and energy mechanism of saturated sandstones

Shuang-jian Niu; Shuang-shuang Ge; Da-fang Yang; Yuan-heng Dang; Jin Yu; Sheng Zhang

doi:10.1007/s11771-018-3839-z

Journal of Central South University ›› 2018, Vol. 25 ›› Issue (6) : 1447 -1463. DOI: 10.1007/s11771-018-3839-z

Article

Mechanical properties and energy mechanism of saturated sandstones

Author information +

History +

PDF

Abstract

The effects of saturation on post-peak mechanical properties and energy features are main focal points for sandstones. To obtain these important attributes, post-peak cyclic loading and unloading tests were conducted on sandstone rock samples under natural and saturated states using the RMT-150B rock mechanics testing system. After successful processing of these tests, comparisons of stress-strain, strength, deformation, damage, and degradation of mechanical properties, wave velocity, and energy features of sandstone were conducted between natural and saturated states. The results show that saturation has evident weakening effects on uniaxial cyclic loading and unloading strength and elastic modulus of post-peak fracture sandstone. With the increase of post-peak loading and unloading period, the increases in amplitude of peak axial, lateral, and volumetric strains are all enhanced at approximately constant speed under the natural state. The increase in amplitude of axial peak strain is also enhanced at approximately constant speed, while the amplitudes of lateral and volumetric peak strains increase significantly under the saturated state. Compared with the natural state, the increase in amplitude of saturated samples’ peak lateral and volumetric strains, and the post-peak cyclic loading and unloading period all conform to the linearly increasing relationship. Under natural and saturated states, the damage factor (the plastic shear strain) of each rock sample gradually increases with the increase of post-peak cyclic loading and unloading period, and the crack damage stress of each rock sample declines rapidly at first and tends to reach a constant value later with the increase in plastic shear strain. Under natural and saturated states, the wave velocities of rock samples all decrease in the process of post-peak cyclic loading and unloading with the increase in plastic shear strain. The wave velocities of rock samples and plastic shear strain conform to the exponential relationship with a constant. Saturation reduces the total absorption energy, dissipated energy, and elastic strain energy of rock samples.

Keywords

post-peak / saturation / strength property / damage mechanism / energy

Cite this article

Download citation ▾

Shuang-jian Niu, Shuang-shuang Ge, Da-fang Yang, Yuan-heng Dang, Jin Yu, Sheng Zhang. Mechanical properties and energy mechanism of saturated sandstones. Journal of Central South University, 2018, 25(6): 1447-1463 DOI:10.1007/s11771-018-3839-z

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	DieringD H. Ultra-deep level mining: Future requirements [J]. Journal of the South African Institute of Mining and Metallurgy, 1997, 97(6): 249-255

[2]	GurtuncaR G, KeynoteLMining below 3000 m and challenges for the South African gold mining industry [C]//Proceedings Mechanics of Jointed and Fractured Rock, 1998, Rotterdam, A. A. Balkema

[3]	DieringD H. Tunnels under pressure in an ultra-deep Wifwatersrand gold mine [J]. Journal of the South African Institute of Mining and Metallurgy, 2000, 100(6): 319-324

[4]	VogelM, AndrastH P. Alp transit-safety in construction as a challenge, health and safety aspects in very deep tunnel construction [J]. Tunneling and Underground Space Technology, 2000, 15(4): 481-484

[5]	JohnsonR A SMining at ultra-depth, evaluation of alternatives [C]//Proceedings of the 2nd North America Rock Mechanics Symposium, 1996, Montreal, NARMS’ 96: 359366

[6]	HeM, XieH, PengS, JiangYao. Study on rock mechanics in deep mining engineering [J]. Chinese Journal of Rock Mechanics and Engineering, 2005, 24(16): 2803-2813

[7]	HeManThe theory and practices of soft rock roadway support in China [M], 1996, Beijing, China University of Mining and Technology Press

[8]	ZhangN, LiX, ZhengX, XueFeiDeep mining of coal resources present situation and the technical challenges [C]//Mining technology of kilometer deep well in the national coal, 2013, Xuzhou, China University of Mining and Technology Press: 223

[9]	HeManPresent state and perspective of rock mechanics in deep mining engineering [C]//Proceedings of the 8th Rock Mechanics and Engineering Conference, 2004, Beijing, Science Press: 8894

[10]	QianQiThe current development of nonlinear rock mechanics: The mechanics problems of deep rock mass [C]//Proceedings of the 8th Rock Mechanics and Engineering Conference, 2004, Beijing, Science Press: 1017

[11]	CelikM Y, ErgiilA. The influence of the water saturation on the strength of volcanic tuffs used as building stones [J]. Environ Earth Sci, 2015, 74(4): 3223-3239

[12]	ChengJ, WanZ, ZhangY, LiW P S S, ZhangPeng. Experimental study on anisotropic strength and deformation behavior of a coal measure shale under room dried and water saturated conditions [J]. Shock and Vibration, 2015, 2015(5): 1-13

[13]	DudaM, RennerJ. The weakening effect of water on the brittle failure strength of sandstone [J]. Geophys J Int, 2013, 192(3): 1091-1108

[14]	HashibaK, FukuiK. Effect of water on the deformation and failure of rock in uniaxial tension [J]. Rock Mech Rock Eng, 2015, 48(5): 1751-1761

[15]	ShiX, CaiW, MengY, LiG, WenK, ZhangYun. Weakening laws of rock uniaxial compressive strength with consideration of water content and rock porosity [J]. Arab J Geosci, 2016, 9(5): 369-375

[16]	LiuL, WangG, ChenJ, YangShan. Creep experiment and rheological model of deep saturated rock [J]. Transaction of Nonferrous Metals Society of China, 2013, 23(2): 478-483

[17]	ZhaoY, LiuS, JiangY, WangK, HuangYa. Dynamic tensile strength of coal under dry and saturated conditions [J]. Rock Mech Rock Eng, 2016, 49(5): 1709-1720

[18]	ChenT, YaoQ, WeiF, ChongZ, ZhouJ, WangC, LiJing. Effects of water intrusion and loading rate on mechanical properties of and crack propagation in coal-rock combinations [J]. Journal of central South University, 2017, 24(2): 423-431

[19]	LiuJ, XieH, HouZ, YangC, ChenLiang. Damage evolution of rock salt under cyclic loading in uniaxial tests [J]. Acta Geotechnica, 2014, 9(1): 153-160

[20]	AkessonU, HanssonJ, StighJ. Characterisation of microcracks in the Bohus granite, western Sweden, caused by uniaxial cyclic loading [J]. Engineering Geology, 2004, 72(1): 131-142

[21]	LiuX, NingJ, TanY, GuQing. Damage constitutive model based on energy dissipation for intact rock subjected to cyclic loading [J]. International Journal of Rock Mechanics & Mining Science, 2016, 85: 27-32

[22]	RobertsL A, BuchholzS A, MellegardK D, DusterlohU. Cyclic loading effects on the creep and dilation of salt rock [J]. Rock Mech Rock Eng, 2015, 48(6): 2581-2590

[23]	LiangW, ZhangC, GaoH, YangX, XuS, ZhaoYang. Experiments on mechanical properties of salt rocks under cyclic loading [J]. Journal of Rock Mechanics and Geotechnical Engineering, 2012, 4(1): 54-61

[24]	MaL, LiuX, WangM, XuH, HuaR, FanP, JiangS, WangG, YiQi. Experimental investigation of the mechanical properties of rock salt under triaxial cyclic loading [J]. International Journal of Rock Mechanics & Mining Sciences, 2013, 62(9): 34-41

[25]	FuenkajornK, PhueakphumD. Effects of cyclic loading on mechanical properties of Maha Sarakham salt [J]. Engineering Geology, 2010, 112(1): 43-52

[26]	LiuE, HuangR, HeSi. Effects of frequency on the dynamic properties of intact rock samples subjected to cyclic loading under confining pressure conditions [J]. Rock Mech Rock Eng, 2012, 45(1): 89-102

[27]	FathiA, MoradianZ, RivardP, BallivyG. Shear mechanism of rock joints under pre-peak cyclic loading condition [J]. International Journal of Rock Mechanics & Mining Sciences, 2016, 83: 197-210

[28]	BagdeM N, PetrosV. Fatigue properties of intact sandstone samples subjected to dynamic uniaxial cyclical loading [J]. International Journal of Rock Mechanics & Mining Sciences, 2005, 42(2): 237-250

[29]	WangH, GaoY, LiShu. Uniaxial experiment study on mechanical properties of reinforced broken rock pre-and-post grouting [J]. Chinese Journal of Underground Space and Engineering, 2007, 3(1): 27-31

[30]	YangM, HeYong. On the strength of broken rock [J]. Chinese Journal of Rock Mechanics and Engineering, 1998, 17(4): 379-385

[31]	MartinC D, ChandlerN A. The progressive fracture of Lac du Bonnet granite [J]. International Journal of Rock Mechanics and Mining Sciences and Geomechanics, 1994, 31(6): 643-659

[32]	ZhaoX, LiP, MaL, SuR, WangJu. Damage and dilation characteristics of deep granite at Beishan under cyclic loading-unloading conditions [J]. Chinese Journal of Rock Mechanics and Engineering, 2014, 33(9): 1740-1748

[33]	XieH, JuY, LiLi. Criteria for strength and structural failure of rocks based on energy dissipation and energy release principles [J]. Chinese Journal of Rock Mechanics and Engineering, 2005, 24(17): 3003-3010

[34]	GuoJ, LiuX, QiaoChun. Experimental study of mechanical properties and energy mechanism of karst limestone under natural and saturated states [J]. Chinese Journal of Rock Mechanics and Engineering, 2014, 33(2): 296-308