Abstract
Soil-rock mixture (SRM) shows complicated mechanical behaviors due to their complex compositions and structures, leading to challenging instability problems during the construction process. Typical SRM are composed of rocks with high strength and fine grained soils, and the mechanical characteristic is largely controlled by the rock block proportion (RBP) and component properties. It is noted that the rock sizes of natural SRM make it difficult for laboratory or in situ tests. There are few studies on empirical formulas to predict the mechanical characteristics of SRM. In this study, the nonlinear relationship between SRM shear strength and RBP was investigated, and an empirical formula predicting the shear strength of mixtures consisted of strong rocks and a weak soil matrix was proposed. For this purpose, a database of shear strength and uniaxial compressive strength (UCS) of SRM with different RBPs was built firstly on the basis of the laboratory test results from previous literatures. In order to focus on the interactions of rock blocks and soil matrix in SRM, a RBP range of 30–90% was set as the applicable range of the empirical formula and both of the compositions are held to provide shear resistance in the applicable range. Subsequently, a nonlinear equation to calculate the shear strength of SRM with RBP range of 30–90% was proposed using regression analysis considering the strengths of components and soil-rock contact faces. Several representative properties of rocks and soil matrix, such as RBP, UCS of the matrix (UCSm), and the friction angle of the blocks (φblock), were chosen as the input parameters based on the mechanical properties of SRM. An additional parameter “A” was used to describe the connect strengths of the soil-rock contact faces. In addition, uniaxial compression tests and large-scale direct shear tests were performed on the Taoyuan SRM samples. The test results and other measured data from the database were used to compare with the corresponding estimated values. The results demonstrated that the empirical approach could predict the shear strength with R2 = 0.75 and can be considered a practical tool in engineering designs when mechanical tests are not available.
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References
Afifipour M, Moarefvand P (2014) Mechanical behavior of bimrock shaving high rock block proportion. Int J Rock Mech Min Sci 65:40–48
Altinsoy H (2006) A Physical based model investigation for determination of shear strength of block in matrix rocks (MSc Thesis). Hacettepe University, Geological Engineering Department, Ankara, Turkey (91 pp)
Avsar E, Ulusay R, Mutluturk M (2015) An experimental investigation of the mechanical behavior and microstructural features of a volcanic soil (Isparta, Turkey) and stability of cut slopes. Eng Geol 189:68–63
Basu A, Celestino TB, Bortolucci AA (2009) Evaluation of rock mechanical behaviors under uniaxial compression with reference to assessed weathering grades. Rock Mech Rock Eng 42(1):73–93
Catane SG, Cabria HB, Zarco MAH, Saturay RM Jr, Mirasol-Rober A (2008) The 17 February 2006 Guinsaugon rock slide-debris avalanche, Southern Leyte, Philippines: deposit characteristics and failure mechanism. Bull Eng Geol Environ 67:305–320
Chang KT, Cheng MC (2014) Estimation of the shear strength of gravel deposits based on field investigated geological factors. Eng Geol 171:70–80
Chang WJ, Phantachang T (2016) Effects of gravel content on shear resistance of gravelly soils. Eng Geol 207:78–90
Coli N, Berry P, Boldini D (2011) In situ non-conventional shear tests for the mechanical characterisation of a bimrock (BimTest). Int J Rock Mech Min Sci 48:95–102
Coli N, Berry P, Boldini D, Bruno R (2012) The contribution of geostatistics to the characterization of some bimrock propertes. Eng Geol 137-138:53–63
Coskun A (2010) Development of an empirical approach to overcome the problems for boundary condition between bimrocks and jointed Rock Masses (MSc Thesis). Hacettepe University, Geological Engineering Department, Ankara, Turkey
Dasaka SM, Zhang LM (2012) Spatial variability of in situ weathered soil. Geotechnique 62:374–384
Deng XC (2014) The tunnel excavation and its slope stability in the accumulation body. Chongqing Jiaotong University, Chongqing
Deng HF (2016) Test research on the shear strength characteristics of rock-soil aggregate mixture. East China University of Technology, Jiangxi
Deng HF, Yuan XF, Li JL, Luo Q, Zhu M (2013) Research on failure characteristics and determination method for shear strength of earth-rock aggregate in direct shear tests. Chin J Rock Mech Eng 32:4065–4072
Donaghe RT, Torrey VH (1979) Scalping and replacement effects on strength parameters of earth–rock mixtures. Des Parameters Geotech Eng Lond 2:29–34
Dupla JC, Pedro LS, Canou J, Dormieux L (2007) Mechanical behavior of coarse-grained soils reference. Bulletin de Liaison des Laboratories des Ponts et Chaussees 268-269:31–57
Fei K (2016) Experimental study of the mechanical behavior of clay–aggregate mixtures. Eng Geol 210:1–9
Feng C, Li ZG, Li SH (2018) Study on uniaxial compression characteristics of brittle rock and soil aggregate. Chin J Comput Mech 35:356–363
Gao W, Hu R, Oyediran IA, Li ZQ, Zhang XY (2014) Geomechanical characterization of zhangmu soil-rock mixture deposit. Geotech Geol Eng 32:1329
Hoek E, Brown ET (1980) Underground excavations in rock. Inst. Min. Metall. Stephen Austin and Sons, London
Hoek E, Brown ET (1997) Practical estimates of rock mass strength. Int J Rock Mech Min Sci 34:1165–1186
Hoek E, Marinos P, Benissi M (2002) Applicability of the geological strength index (GSI) classification for very weak and sheared rock masses. The case of the Athens Schist Formation. Bull Eng Geol Environ 57(2):151–160
Holtz WG, Willard M (1956) Triaxial shear characteristics of clayey gravel soils. J Soil Mech Found Div 820(SM1):1–22
Hong K, Han E, Kang K (2017) Determination of geological strength index of jointed rock mass based on image processing. J Rock Mech Geotech Eng 9(4):702–708
Hu W (2014) Experimental study on shear strength of soil-rock-mixture in Xiluodu reservoir. Inst. Rock and Soil Mechanics, Chinese Academy of Sciences, Wuhan, China (in Chinese)
Hu W, Min H, Chen J, Sheng Q (2015) Study on the effect of gravel on unconfined mechanical properties of soil-rock mixture. J Yangtze River Sci Res Inst 11:55–61
Iannacchione AT (1997) Shear strength saturated clays with floating rock particles. University of Pittsburgh, Oakland
Kahraman S, Alber M (2006) Estimating unconfined compressive strength and elastic modulus of a fault breccia mixture of weak blocks and strong matrix. Int J Rock Mech Min Sci 43:1277–1287
Kalender A, Sonmez H, Medley E, Tunusluoglu C, Kasapoglu KE (2014) An approach to predicting the overall strengths of unwelded bimrocks and bimsoils. Eng Geol 183:65–79
Khalili A, Wijewickreme D, Wilson GW (2010) Mechanical response of highly gap-graded mixtures of waste rock and tailings. Part I: monotonic shear response. Can Geotech J 47:552–565
Le TM, Dang LC, Khabbaz H (2019) Combined effects of bottom ash and lime on behaviour of expansive soil. In: McCartney J, Hoyos L (eds) Recent advancements on expansive soils. GeoMEast 2018. Sustainable Civil Infrastructures. Springer, Cham
Li YR (2013) Effects of particle shape and size distribution on the shear strength behavior of composite soils. Bull Eng Geol Environ 72:371–381
Lindquist ES, Goodman RE (1994) The strength and deformation properties of a physical model mélange. Proc. 1st North American Rock Mech. Symp., Austin, Texas, pp 843–850
Liu XR, Tu YL, Wang P, Zhong ZL, Tang WB, Du LB (2017) Particle breakage of soil-rock aggregate based on large-scale direct shear tests. Chin J Geotech Eng 39:1425–1434
Ma C, Zhan HB, Zhang T, Yao WM (2019) Investigation on shear behavior of soft interlayers by ring shear tests. Eng Geol 254:34–42
MalllkarJuna Rao K, Rama Subba Rao GV (2018) Influence of coarse fraction on characteristics of expansive soil–sand mixtures. Int J Geosyn Ground Eng 4:19. https://doi.org/10.1007/s40891-018-0136-8
Medley EW, Goodman RE (1994) Estimating the block volumetric proportions of melanges and similar block-in-matrix rocks (bimrocks). Proc. 1st North American Rock Mechanics Symposium, Austin
Monkul MM, Ozden G (2007) Compressional behavior of clayey sand and transition fines content. Eng Geol 89:195–205
Qi D (2016) Experimental study on the mechanical properties of soil-rock mixture. North China University of Water Resources and Electric Power, Henan (in Chinese)
Raharadjo H, Indrawan IGB, Lenog EC, Yong WK (2008) Effects of coarse-grained material on hydraulic properties and shear strength of top soil. Eng Geol 101:165–173
Raymond LA (1984) Classification of melanges. In: Raymond LA, Boulder LA (eds) Melanges: their nature, origin and significance. Geol. Soc. of America, pp 7–20
Singh HK, Basu A (2016) Shear behaviors of ‘real’ natural un-matching joints of granite with equivalent joint roughness coefficients. Eng Geol 211:120–134
Sun SR, Xu PL, Wu LM, Wei JH, Fu WG, Liu J, Kangungo DP (2014) Strength parameter identification and application of soil–rock mixture for steep-walled talus slopes in southwestern China. Bull Eng Geol Environ 73:123–140
Tian YC, Liu QS, Ma H, Liu Q, Deng PH (2018) New peak shear strength model for cement filled rock joints. Eng Geol 233:269–280
Ulusay R, Erguler ZA (2012) Needle penetration test: evaluation of its performance and possible uses in predicting strength of weak and soft rocks. Eng Geol 149-150:47–56
Usefzadeh A, Yousefzadeh H, Salari-Rad H, Sharifzadeh M (2013) Empirical and mathematical formulation of the shear behavior of rock joints. Eng Geol 164:243–252
Vallejo LE (2001) Interpretation of the limits in shear strength in binary granular mixtures. Can Geotech J 38:1097–1104
Vallejo LE, Zhou Y (1994) The mechanical properties of simulated soil-rock mixtures. In: Proceedings of the 13th International Conference on Soil Mechanics and Foundation Engineering, New Delhi, India. pp 365–368
Wang Y, Li X (2015) Experimental study on cracking damage characteristics of a soil and rock mixture by UPV testing. Bull Eng Geol Environ 74:775–788
Wang Y, Li CH, Hu YZ (2018) X-ray computed tomography (CT) observations of crack damage evolution in soil-rock mixture during uniaxial deformation. Arab J Geosci 11:199
Wang Y, Li CH, Hu YZ (2019) 3D image visualization of meso-structural changes in a bimsoil under uniaxial compression using X-ray computed tomography (CT). Eng Geol 248:61–69
Wei HZ, Wang R, Hu MJ, Zhao HY, Meng QS (2008) Strength behavior of gravelly soil with different coarse-grained contents in Jiangjiagou Ravine. Rock Soil Mech 29(1):48–51
Wei HZ, Xv WJ, Wei CF, Meng QS (2018) Influence of water content and shear rate on the mechanical behavior of soil-rock mixtures. Sci China Technol Sci 51(8):1127–1136
Weibel ER (1980) Stereological Method, vol 2. Academic Press, London
Wickland BE, Wilson GW, Wijewickreme D, Klein B (2006) Design and evaluation of mixtures of mine waste rock and tails. Can Geotech J 43:928–945
Wu R (2015) Study on the strength experiment of gravel soil in the slope of Daqianshiling Tunnel. China University of Geosciences, Wuhan
Wu RA, Zhang YS, Wang XL, Yao X, Yang ZH, Du GL (2017) In situ direct shearing test on landslide accumulation body intensity of Wenchuan earthquake region. J Geom 23:105–114
Xu WJ, Xv Q, Hu RL (2011) Study on the shear strength of soil–rock mixture by large scale direct shear test. Int J Rock Mech Min Sci 48(8):1235–1247
Xu DS, Tang JY, Zou Y, Rui R, Liu HB (2019) Macro and micro investigation of gravel content on simple shear behavior of sand-gravel mixture. Constr Build Mater 221:730–744
Yang JH, Dong JY, Liu HD, Huang ZQ, Jiang T (2010) In situ direct shear tests on the large scale accumulation body and three dimensional stability analysis of the slope. J China Coal Soc 35:392–396
Zhang YS, Guo CB, Yao X, Qu YX, Zhou NJ (2013) Engineering geological characterization of clayey diatomaceous earth deposits encountered in highway projects in the Tengchong region, Yunnan, China. Eng Geol 167(17):98–104
Zhang HY, Xv WJ, Yu YZ (2016) Triaxial tests of soil-rock mixtures with different rock block distributions. Soils Found 56(1):44–56
Zhao YL, Gao Y, Zhang YL, Wang Y (2016) Effect of fines on the mechanical properties of composite soil stabilizer-stabilized gravel soil. Constr Build Mater 126(15):701–710
Funding
The authors gratefully acknowledge the support given by National Key R&D Program of China (2018YFC0809400), the National Natural Science Foundation of China (No. 51779250, No. U1402231, No. 51679232, No. 51609240, No. 51909259), and the Traffic Science, Technology and Education Project of Yunnan Province (2017) No. 33.
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Zhang, Z., Sheng, Q., Fu, X. et al. An approach to predicting the shear strength of soil-rock mixture based on rock block proportion. Bull Eng Geol Environ 79, 2423–2437 (2020). https://doi.org/10.1007/s10064-019-01658-0
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DOI: https://doi.org/10.1007/s10064-019-01658-0