Energy characteristics of saturated Jurassic sandstone in western China under different stress paths

Yi Yang; Jian Lin; Yun Wu; Shilong Peng; Wanhang Shao; Lining Yang

doi:10.1002/dug2.12096

Deep Underground Science and Engineering ›› 2025, Vol. 4 ›› Issue (1) :158 -168. DOI: 10.1002/dug2.12096

RESEARCH ARTICLE

Energy characteristics of saturated Jurassic sandstone in western China under different stress paths

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Abstract

To study the energy evolution and failure characteristics of saturated sandstone under unloading conditions, rock unloading tests under different stress paths were conducted. The energy evolution mechanism of the unloading failure of saturated sandstone was systematically explored from the perspectives of the stress path, the initial confining pressure, and the energy conversion rate. The results show that (1) before the peak stress, the elastic energy increases with an increase in deviatoric stress, while the dissipated energy slowly increases first. After the peak stress, the elastic energy decreases with the decrease of deviatoric stress, and the dissipated energy suddenly increases. The energy release intensity during rock failure is positively correlated with the axial stress. (2) When the initial confining pressure is below a certain threshold, the stress path is the main factor influencing the total energy difference. When the axial stress remains constant and the confining pressure is unloading, the total energy is more sensitive to changes in the confining pressure. When the axial stress remains constant, the compressive deformation ability of the rock cannot be significantly improved by the increase in the initial confining pressure. The initial confining pressure is positively correlated with the rock's energy storage limit. (3) The initial confining pressure increases the energy conversion rate of the rock; the initial confining pressure is positively correlated with the energy conversion rate; and the energy conversion rate has a high confining pressure effect. The increase in the axial stress has a much greater impact on the elastic energy than the confining pressure. (4) When the deviatoric stress is small, the confining pressure mainly plays a protective role. Compared with the case of triaxial compression paths, the rock damage is more severe under unloading paths, and compared with the case of constant axial stress, the rock damage is more severe under increasing axial stress.

Keywords

energy evolution / failure characteristics / sandstone / stress path / unloading

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Yi Yang, Jian Lin, Yun Wu, Shilong Peng, Wanhang Shao, Lining Yang. Energy characteristics of saturated Jurassic sandstone in western China under different stress paths. Deep Underground Science and Engineering, 2025, 4(1): 158-168 DOI:10.1002/dug2.12096

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References

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

[1]	Arzúa J, Alejano LR. Dilation in granite during servo-controlled triaxial strength tests. Int J Rock Mech Min Sci. 2013; 61: 43-56.

[2]	Arzúa J, Alejano LR, Walton G. Strength and dilation of jointed granite specimens in servo-controlled triaxial tests. Int J Rock Mech Min Sci. 2014; 69: 93-104.

[3]	Bagde MN, Petroš V. The effect of machine behaviour and mechanical properties of intact sandstone under static and dynamic uniaxial cyclic loading. Rock Mech Rock Eng. 2005; 38: 59-67.

[4]	Cheng H, Lin J, Yao Z, et al. Study on the external load of a single layer wall of the vertical shaft in the pore type water-bearing bedrock section in western China. Chin J Rock Mech Eng. 2019; 38(3): 542-550.

[5]	Dai B, Zhao G, Yang C, et al. Energy evolution law of rocks in process of unloading failure under different paths. J Min Saf Eng. 2016; 33(2): 367-374.

[6]	Deng L, Li X, Wu Y, et al. Influence of cooling speed on the physical and mechanical properties of granite in geothermal-related engineering. Deep Undergr Sci Eng. 2022; 1(1): 40-57.

[7]	Duan M, Jiang C, Yin W, et al. Experimental study on mechanical and damage characteristics of coal under true triaxial cyclic disturbance. Eng Geol. 2021; 295:106445.

[8]	Feng XT, Kong R, Zhang X, Yang C. Experimental study of failure differences in hard rock under true triaxial compression. Rock Mech Rock Eng. 2019; 52(7): 2109-2122.

[9]	Feng XT, Xu H, Yang C, Zhang X, Gao Y. Influence of loading and unloading stress paths on the deformation and failure features of jinping marble under true triaxial compression. Rock Mech Rock Eng. 2020; 53(1): 3287-3301.

[10]	Fu J, Chen W, Tan Y, Wang J, Song W. Experimental study on pore variation and meso-samage of saturated sandstone under unloading condition. Rock Mech Rock Engg. 2023; 56: 4669-4695.

[11]	Geranmayeh Vaneghi R, Thoeni K, Dyskin AV, Sharifzadeh M, Sarmadivaleh M. Strength and damage response of sandstone and granodiorite under different loading conditions of multistage uniaxial cyclic compression. Int J Geomech. 2020; 20(9):04020159.

[12]	Gu L, Feng XT, Kong R, Yang C, Xia Y. Evolution of mechanical parameters of Shuangjiangkou granite under different loading cycles and stress paths. J Rock Mech Geotech Eng. 2023.

[13]	Jiang J, Chen S, Xu J, et al. Mechanical properties and energy characteristics of mudstone under different containing moisture states. J China Coal Soc. 2018; 43(8): 2217-2224.

[14]	Labiouse V, Vietor T. Laboratory and in-situ simulation tests of the excavation damaged zone around galleries in Opalinus clay. Rock Mech Rock Eng. 2014; 47: 57-70.

[15]	Li J, Zhu Z, Yu L. Dissipative characteristics investigation of marble during reloading process considering pre-peak unloading damage. Chin J Rock Mech Eng. 2020; 39(12): 2429-2438.

[16]	Li T, Chen Z, Chen G, et al. An experimental study of energy mechanism of sandstone with different moisture contents. Rock Soil Mech. 2015; 36(Supp 2): 229-236.

[17]	Li Y, Huang D, Li X. Strain rate dependency of coarse crystal marble under uniaxial compression: strength, deformation and strain energy. Rock Mech Rock Eng. 2014; 47: 1153-1164.

[18]	Lin J. Study on formation mechanism of external load of frozen shaft in water-bearing bedrock section in western China. Chin J Rock Mech Eng. 2022; 41(6): 1296.

[19]	Liu XS, Ning JG, Tan YL, Gu QH. Damage constitutive model based on energy dissipation for intact rock subjected to cyclic loading. Int J Rock Mech Min Sci. 2016; 85: 27-32.

[20]	Luo S, Gong F, Peng K, Liu Z. Influence of water on rockburst proneness of sandstone: insights from relative and absolute energy storage. Eng Geol. 2023; 323:107172.

[21]	Mahanta B, Singh TN, Ranjith PG, Vishal V. Experimental investigation of the influence of strain rate on strength; failure attributes and mechanism of Jhiri shale. J Nat Gas Sci Eng. 2018; 58: 178-188.

[22]	Mahanta B, Tripathy A, Vishal V, Singh TN, Ranjith PG. Effects of strain rate on fracture toughness and energy release rate of gas shales. Eng Geol. 2017; 218: 39-49.

[23]	Mahmutoğlu Y. The effects of strain rate and saturation on a micro-cracked marble. Eng Geol. 2006; 82: 137-144.

[24]	Meng Q, Zhang M, Han L, Pu H, Nie T. Effects of acoustic emission and energy evolution of rock specimens under the uniaxial cyclic loading and unloading compression. Rock Mech Rock Eng. 2016; 49: 3873-3886.

[25]	Munoz H, Taheri A. Local damage and progressive localisation in porous sandstone during cyclic loading. Rock Mech Rock Eng. 2017; 50(12): 3253-3259.

[26]	Munoz H, Taheri A, Chanda EK. Pre-peak and post-peak rock strain characteristics during uniaxial compression by 3D digital image correlation. Rock Mech Rock Eng. 2016; 49: 2541-2554.

[27]	Peng R, Ju Y, Wang JG, Xie H, Gao F, Mao L. Energy dissipation and release during coal failure under conventional triaxial compression. Rock Mech Rock Eng. 2015; 48: 509-526.

[28]	Qin T, Duan Y, Sun H, et al. Mechanical characteristics and energy dissipation characteristics of sandstone under triaxial stress conditions. J China Coal Soc. 2020; 45(Supp 1): 255-262.

[29]	Qiu SL, Feng XT, Xiao JQ, Zhang CQ. An experimental study on the pre-peak unloading damage evolution of marble. Rock Mech Rock Eng. 2014; 47: 401-419.

[30]	Si X, Gong F. Strength-weakening effect and shear-tension failure mode transformation mechanism of rockburst for fine-grained granite under triaxial unloading compression. Int J Rock Mech Min Sci. 2020; 131:104347.

[31]	Taheri A, Hamzah N, Dai Q. Degradation and improvement of mechanical properties of rock under triaxial compressive cyclic loading. Jpn Geotech Soc Spec Publ. 2017; 5: 71-78.

[32]	Walton G, Gaines S. Evaluation of stress path and load rate effects on rock strength using compression testing data for Stanstead granite. Int J Rock Mech Min Sci. 2023; 169:105455.

[33]	Wasantha PLP, Ranjith PG, Shao SS. Energy monitoring and analysis during deformation of bedded-sandstone: use of acoustic emission. Ultrasonics. 2014; 54: 217-226.

[34]	Yang Y, Xie H, Xiao M, et al. Deformation failure and energy characteristics of transverse-isotropic rock under unloading of high confining pressure. Chin J Rock Mech Eng. 2017; 36(8): 1999-2006.

[35]	Yin G, Ma B, Liu C, et al. Effect of loading and unloading rates on mechanical properties and energy characteristics of sandstone under true triaxial stress. J China Coal Soc. 2019; 44(2): 454-462.

[36]	Zhang J, Du R, Chen Y, Huang Z. Experimental investigation of the mechanical properties and energy evolution of layered phyllite under uniaxial multilevel cyclic loading. Rock Mech Rock Eng. 2023; 56: 4153-4168.

[37]	Zhang Y, Feng XT, Yang C, Zhang X, Sharifzadeh M, Wang Z. Fracturing evolution analysis of Beishan granite under true triaxial compression based on acoustic emission and strain energy. Int J Rock Mech Min Sci. 2019; 117: 150-161.

[38]	Zhao K, Yu X, Zhou Y, Wang Q, Wang J, Hao J. Energy evolution of brittle granite under different loading rates. Int J Rock Mech Min Sci. 2020; 132:104392.

[39]	Zhao Y, Dang S, Bi J, Wang C, Gan F, Li J. Energy evolution characteristics of sandstones during confining pressure cyclic unloading conditions. Rock Mech Rock Eng. 2023; 56: 953-972.

[40]	Zhou HW, Wang ZH, Ren WG, Liu ZL, Liu JF. Acoustic emission based mechanical behaviors of Beishan granite under conventional triaxial compression and hydro-mechanical coupling tests. Int J Rock Mech Min Sci. 2019; 123:104125.

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