Evaluation of Stress Thresholds in Crack Development and Corrected Fracture Toughness of KURT Granite under Dry and Saturated Conditions

Jin-Seop Kim; Chang-Ho Hong; Geon-Young Kim

doi:10.7474/TUS.2020.30.3.256

All Issue

2020 Vol.30, Issue 3 Preview Page

Research Article

Evaluation of Stress Thresholds in Crack Development and Corrected Fracture Toughness of KURT Granite under Dry and Saturated Conditions 포화유무에 따른 KURT 화강암의 균열손상 기준 및 수정 파괴인성 측정 (Level II Method)

30 June 2020. pp. 256-269

PDF XML

Abstract

The objective of this study is to evaluate the stress thresholds in crack development and the corrected fracture toughness of KURT granite under dry and saturated conditions. The stress thresholds were identified by calculation of inelastic volumetric strain from an uniaxial compression test. The corrected fracture toughness was estimated by using the Level II method (Chevron Bend specimen), suggested by ISRM (1988), in which non-linear behaviors of rock was taken into account. Average crack initiation stress(σ_ci) and crack damage stress(σ_cd) under a dry condition were 91.1 MPa and 128.7 MPa. While, average crack initiation stress(σ_ci) and crack damage stress(σ_cd) under a saturated condition were 58.2 MPa and 68.2 MPa. The crack initiation stress and crack damage stress of saturated ones decreased 36% and 47% respectively compared to those of dry specimens. A decrease in crack damage stress is relatively larger than that of crack initiation stress under a saturated condition. This indicates that the unstable crack growth can be more easily generated because of the saturation effect of water compared to the dry condition. The average corrected fracture toughness of KURT granite was 0.811 MPa·m^0.5. While, the fracture toughness of saturated KURT granite(K_CB) was 0.620 MPa·m^0.5. The corrected fracture toughness of rock in saturated condition decreases by 23.5% compared to that in dry condition. It is found that the resistance to crack propagation decreases under the saturated geological condition.

Keywords

KURT granite

Stress thresholds in crack development

Corrected fracture toughness

Uniaxial compression test

Chevron Bend three point bending test

본 연구의 목적은 KURT 화강암 시료의 포화유무에 따른 균열손상 기준과 파괴인성의 변화를 측정하는 것이다. 이를 위하여 일축압축시험을 이용한 소성체적변형률을 통해 KURT 화강암의 균열손상 기준을 도출하였다. 또한 암석의 파괴인성을 보다 신뢰성 있게 측정하기 위해 암석의 비선형적 변형에 대한 보정(Level II Method; ISRM, 1988) 을 통해 포화유무에 따른 KURT 화강암의 수정 파괴인성(corrected fracture toughness)을 측정하였다. 시험결과 건조시료의 평균 균열개시 응력(σ_ci)과 균열손상 응력(σ_cd)은 91.1 MPa과 128.7 MPa이었으며, 포화시료의 평균 균열개시 응력(σ_ci)과 균열손상 응력(σ_cd)은 58.2 MPa과 68.2 MPa이었다. 건조시료에 비해 포화시료의 균열개시 응력은 36% 감소하였으며 균열손상 응력은 건조시료 대비 47%나 감소되는 결과를 나타내었다. 균열손상 응력(σ_cd)이 상대적으로 더욱 감소하였음을 감안할 때 시료의 포화로 인해 더 낮은 응력조건에서 구조물에 대한 손상이 쉽게 발생할 수 있음을 알 수 있다. KURT 화강암의 비선형성을 고려한 수정 파괴인성은 0.811 MPa·m^0.5이었으며 포화시료의 수정 파괴인성은 0.620 MPa·m^0.5이었다. 즉 암석의 비선형성을 고려함으로써 파괴인성의 증가를 확인할 수 있었으며, 암석의 포화시 수정 파괴인성은 24% 감소하였다. 따라서 지하수 포화로 인해 암석 내 균열의 생성과 진전에 대한 저항성이 감소함을 알 수 있다.

키워드

KURT 화강암

균열손상 기준

수정 파괴인성

일축압축시험

Chevron Bend 3점 굽힘시험

References

Atkinson, B.K., 1987, Fracture mechanics of rock, University College London, Academic Press, London.

Bieniawski, Z.T. 1967, Mechanism of brittle rock fracture. Part I. Theory of the fracture process. International Journal of Rock Mechanics and Mining Sciences & Geomechanical Abstracts, 4(4), 395-406.

10.1016/0148-9062(67)90030-7

Brace, W.F., Paulding, B.W., Jr., and Scholz, C., 1966, Dilatancy in the fracture of crystalline rocks. Journal of Geophysical Research, 71(16), 3939-3953.

10.1029/JZ071i016p03939

Cai, M, Kaiser, P.K., Tasaka, Y., Maejima T., Morioka, J., and Minami, M., 2004, Generalized crack initiation and crack damage stress thresholds of brittle rock masses near underground excavation, Int J Rock Mech. Min. Sci. 41, 833-847.

10.1016/j.ijrmms.2004.02.001

Chandler, M.R., Meredith, P.G., Brantut N., and Crawford B.R., 2017, Effect of temperature on the fracture toughness of anisotropic shale and other rocks, Geological Society of London, Special Publications, 454.

10.1144/SP454.6

Eberhardt, E, Stead D, Stimpson, B., and Read R.S., 1998, Identifying crack initiation and propagation thresholds in brittle rock. Can Geotech J 35(2), 222-233.

10.1139/t97-091

Eberhardt, E., Stead, D., and Stimpson, B., 1999, Quantifying progressive pre-peak brittle fracture damage in rock during uniaxial compression, Int J Rock Mech Min Sci, 36(3), 361-380.

10.1016/S0148-9062(99)00019-4

ISRM, 1988, Suggested Methods for Determining the Fracture Toughness of Rock, Int. J. Rock Mech. Min. Sci. & Geomech. Abstr. 25(2), 71-96.

10.1016/0148-9062(88)91871-2

ISRM, 2007, The complete ISRM suggested methods for rock characterization, testing and monitoring: 1974-2006, ISRM Commission on Testing Methods.

Jung, Y.B., Cheon D.S., Park, E.S., Park, C.W, Lee Y., Park, C., and Choi, B.H, 2014, Estimation of the characteristics of delayed failure and long-term strength of granite by Brazilian disc test, Tunnel & Underground Space, 24(1), 67-80.

10.7474/TUS.2014.24.1.067

Kim, G.Y., Kim, S.J., Koh, Y.K., and Bae, D.S., 2004, Mineralogical characteristics and genesis of phlogopite in the talc deposits of the Chungnam area, Korea, Journal of the Mineralogical Society of Korea, 17(3), 221-233.

Kim, J.D. and Baik, S.K., 1992, The size effect in measuring the fracture toughness of rock using Chevron Bend specimen, Tunnel & Underground Space, 2, 251-264.

Kim, J.S., Kwon, S.K., Sanchez, M., and Cho, G.C., 2011, Geological Storage of High Level Nuclear Waste, KSCE Journal of Civil Engineering, 15(4), 721-737.

10.1007/s12205-011-0012-8

Kim, J.S., Lee K.S., Cho, W.J., Choi, H.J., and Cho, G.C., 2015, A Comparative Evaluation of Stress-Strain and Acoustic Emission Methods for Quantitative Damage Assessments of Brittle Rock, Rock Mech Rock Eng, 48(2), 495-508.

10.1007/s00603-014-0590-0

Lee, C.S., Yoon, S., Cho, W.J., Jo, Y.G., Lee, S.D., Jeon, S.W., and Kim, G.Y., 2019, Study on thermal, hydraulic, and mechanical properties of KURT granite and Gyeongju bentonite, Journal of Nuclear Fuel Cycle and Waste Technology, 17(S), 65-80.

10.7733/jnfcwt.2019.17.S.65

Martin, C.D. and Chandler, N.A., 1994, The progressive fracture of Lac du Bonnet granite, Int J Rock Mech Min Sci Geomech Abstr, 31, 643-659.

10.1016/0148-9062(94)90005-1

Michalske, T.A. and Freiman, S.W., 1983, A Molecular Mechanism for Stress Corrosion in Vitreous Silica, J. Am. Ceram. Soc., 66, 284-288.

10.1111/j.1151-2916.1983.tb15715.x

Paterson, M.S. and Wong, T. Experimental rock deformation - The brittle field, 2005, 2nd edition, Springer, Berlin.

Ranjith, P.G., Jasinge, D., Song, J.Y. and Choi, S.K., 2008, A study of the effect of displacement rate and moisture content on the mechanical properties of concrete: Use of acoustic emission, Mechanics of Materials, 40, 453-469.

10.1016/j.mechmat.2007.11.002

Roy, D.G., Singh, T.N., Kodikara, J., and Das R.E, 2017, Effect of water saturation on the fracture and mechanical properties of sedimentary rocks, Rock Mech Rock Eng , 50, 2585-2600

10.1007/s00603-017-1253-8

Van Eeckhout, E.M., 1976, The mechanisms of strength reduction due to moisture in coal mine shales, International Journal of Rock Mechanics and Mining Sciences & Geomechanical Abstracts, 13, 61-67.

10.1016/0148-9062(76)90705-1

Watchtman J.B., Cannon W.R., and Matthewson M.J., 2009, Mechanical properties of ceramics, 2nd Ed. John Wiley & Sons, Rutgers University.

10.1002/9780470451519

Zhou, Z., Cai, X., Zhao, Y., Chen, L., Xiong, C., and Li, X., 2016, Strength characteristics of dry and saturated rock at different strain rates, Transactions of Nonferrous Metals Society of China, 26(7), 1919-1925.

10.1016/S1003-6326(16)64314-5

Information

Publisher :Korean Society for Rock Mechanics and Rock Engineering
Publisher(Ko) :한국암반공학회
Journal Title :Tunnel and Underground Space
Journal Title(Ko) :터널과 지하공간
Volume : 30
No :3
Pages :256-269
Received Date : 2020-06-12
Revised Date : 2020-06-24
Accepted Date : 2020-06-24
DOI :https://doi.org/10.7474/TUS.2020.30.3.256

Tunnel and Underground Space ISSN:1225-1275(Print) 2287-1748(Online) 터널과 지하공간

All Issue