Evolution behaviors of triaxial shearing parameters are very important for geo-technical re- sponse analysis during the process of extracting natural gas from hydrate-bearing reservoirs. In order to explore the effects of hydrate formation/decomposition on triaxial shearing behaviors of intermediate fine sediment, natural beach sand in Qingdao, China, which was sieved from 0.1 to 0.85 mm, was used and a series of triaxial shear tests were carried out in this paper. The principle of critical state was firstly used to explain the mechanism of strain softening and/or hardening failure mode. Moreover, an empirical model was provided for axial-lateral strain and corresponding model parameters calculation. Evolution rules of critical strength parameters were analyzed prominently. The results show that failure mode of sediment is controlled by several parameters, such as effective confining pressure, hydrate saturation, etc. Different axial-lateral strain model coefficients’ effect on strain relationships are different, probing into the physical meaning of each coefficient is essential for further understanding of strain relationships. Complex geo-technical response should be faced with the progress of producing natural gas from hydrate-bearing reservoir, because of sudden change of failure pattern and formation modulus. Further compressive study on critical condition of failure pattern is needed for proposed promising hydrate-bearing reservoirs.

Cited as: Li, Y., Liu, C., Liu, L., Sun, J., Liu, H., Meng, Q. Experimental study on evolution behaviors of triaxial-shearing parameters for hydrate-bearing intermediate fine sediment. Advances in Geo-Energy Research, 2018, 2(1): 43-52, doi: 10.26804/ager.2018.01.04

Hyodo, M., Li, Y., Yoneda, J., et al. Effects of dissociation on the shear strength behavior of methane hydrate-bearing sediments. Mar. Pet. Geol. 2013, 51(2): 52-62.

Hyodo, M., Nakata, Y., Yoshimoto, N., et al. Shear behavior of methane hydrate-bearing sand. Paper ISOPE-I-07-428 Presented at the Proceedings of the Seventeenth International Offshore and Polar Engineering Conference, Lisbon, Portugal, 1-6 July, 2007.

Li, L.D., Cheng, Y.F., Sun, X.J., et al. Experimental sample preparation and mechanical properties study of hydrate-bearing sediments. Journal of China University of Petroleum (Edition of Natural Science) 2012a, 36(4): 97-101. (in Chinese)

Li, Y.H., Song, Y.C., Liu, W.G., et al. Temperature and shear rate influences on hydrate-bearing soils. Natural Gas Exploration and Development 2012b, 35(1): 50-53. (in Chinese)

Li, Y.H., Song, Y.C., Yu, F., et al. Effect of confining pres-sure on mechanical behavior of methane hydrate-bearing sediments. Pet. Explor. Dev. 2011, 38(5): 637-640.

Li, Y.L., Liu, C.L., Liu, L.L. Damage statistic constitutive model of hydrate-bearing sediments and the determination method of parameters. Acta Petrolei Sinica 2016a, 37(10): 1273-1279. (in Chinese)

Li, Y.L., Liu, C.L., Liu, L.L., et al. Key Issues for triaxial test of hydrate-bearing sediment. Advance in New and Renewable Energy 2016b, 4(4): 279-285. (in Chinese)

Li, Y.L., Liu, C.L., Liu, L.L., et al. The mechanical properties of methane hydrate-bearing unconsolidated sediment. J. Univ. Pet., China (Ed. Nat. Sci.) 2017a, 41(3): 1-9.

Li, Y.L., Liu, C.L., Liu, L.L., et al. Triaxial shear test and strain analysis of unconsolidated hydrate-bearing sedi-ments. Natural Gas Geoscience 2017b, 28(3): 383-390.

(in Chinese) Liu, F., Kou, X.Y., Jiang, M.J., et al. Triaxial shear strength of synthetic hydrate-bearing sediments. Chinese Journal of Geotechnical Engineering 2013, 35(8): 1565-1572. (in Chinese)

Liu, W., Chen, Y., Zhu, Y., et al. Effects of different mining methods on the strength behavior of gas hydrate-bearing sediments. Energy Procedia 2014a, 61: 547-551.

Liu, W.T., Shi, Y.H., Zhang, X.H., et al. Geo-technical features of the seabed soils in the east of Xisha trough and the me-chanical properties of gas hydrate-bearing fine deposits. Marine Geology and Quaternary Geology 2014b, 34(3): 39-47. (in Chinese)

Lu, X.B., Wang, L., Wang, S.Y., et al. Triaxial test on THF hydrate-bearing sediment. Presented at 13th China national ocean science symposium, Nanjing, Jiangsu Province, China, 19-20 September, 2007.

Masui, A., Haneda, H., Ogata, Y., et al. Mechanical properties of sandy sediment containing marine gas hydrates in deep sea offshore Japan. Paper ISOPE-M-07-015 Presented at the Proceedings of the International Society of Offshore and Polar Engineers Ocean Mining Symposium, Lisbon, Portugal, 1-6 July, 2007.

Miyazaki, K., Masui, A., Sakamoto, Y., et al. Triaxial com-pressive properties of artificial methane-hydrate-bearing sediment. J. Geophys. Res. 2011, 116(B6): B06102.

Miyazaki, K., Tenma, N., Aoki, K., et al. A nonlinear elas-tic model for triaxial compressive properties of artifi-cial methane-hydrate-bearing sediment samples. Energies 2012, 5(10): 4057-4075.

Priest, J.A., Clayton, C.R.I., Rees, E.V.L. Potential impact of gas hydrate and its dissociation on the strength of host sediment in the Krishna-Godavari Basin. Mar. Pet. Geol. 2014, 58: 187-198.

Shi, Y.H., Zhang, X.H., Lu, X.B., et al. Experimental study on the static mechanical properties of hydrate-bearing silty-clay in China South Sea. Chinese Journal of Theoretical and Applied Mechanics 2015, 47(3): 521-528. (in Chi-nese)

Sun, X.J., Cheng, Y.F., Li, L.D., et al. Triaxial compression test on synthetic core sample with simulated hydrate-bearing sediments. Petroleum Drilling Techniques 2012, 40(4): 52-57. (in Chinese)

Wei, H.Z., Yan, R.T., Chen, P., et al. Deformation and failure behavior of carbon dioxide hydrate-bearing sands with different hydrate contents under triaxial shear tests. Rock and Soil Mechanics 2011, S2: 198-203. (in Chinese)

Winters, W.J., Waite, W.F., Mason, D.H., et al. Methane gas hydrate effect on sediment acoustic and strength properties. J. Pet. Sci. Eng. 2007, 56(s1-3): 127-135.

Winters, W.J., Wilcox, C.R.W., Long, P., et al. Comparison of the physical and geotechnical properties of gas-hydrate-bearing sediments from offshore India and other gas-hydrate-reservoir systems. Mar. Pet. Geol. 2014, 58: 139-167.

Wu, N.Y., Huang, L., Hu, G.W., et al. Geological controlling factors and scientific challenges for offshore gas hy-drate exploration. Marine Geology & Quaternary Geology 2017, 37(5): 1-11. (in Chinese)

Yan, R.T., Wei, C.F., Wei, H.Z., et al. Effect of hydrate for-mation on mechanical strength of hydrate-bearing sand. Chinese Journal of Geotechnical Engineering 2012, 7: 1234-1240. (in Chinese)

Yan, R.T., Wei, H.Z., Fu, X.H., et al. Influence of occurrence mode of hydrate on mechanical behavior of hydrate-bearing soils. Chinese Journal of Rock Mechanics and Engineering 2013, z2: 4115-4122. (in Chinese)

Yoneda, J., Masui, A., Konno, Y., et al. Mechanical behavior of hydrate-bearing pressure core sediments visualized under triaxial compression. Mar. Pet. Geol. 2015, 66: 451-459.

Yu, F., Song, Y.C., Li, Y.H., et al. A study on stress-strain relations of methane hydrates. Acta Petrolei Sinica 2011, 32(4): 687-692. (in Chinese)

Yun, T.S., Santamarina, J.C., Ruppel, C. Mechanical properties of sand, silt, and clay containing tetrahydrofuran hydrate. J. Geophys. Res. 2007, 112(B4): 93-101.

Zhang, H.T., Zhang, H.Q., Zhu, Y.H. Gas hydrate investiga-tion and research in China: Present status and progress. Geology in China 2007, 34(6): 953-961. (in Chinese)

Zhang, X.H., Lu, X.B., Wang, S.Y., et al. Experimental study of static and dynamic properties of tetrahydrofu-ran hydrate-bearing sediments. Rock and Soil Mechanics 2011, 32(S1): 303-308. (in Chinese)

Zhang, X.H., Wang, S.Y., Li, Q.P., et al. Experimental study of mechanical properties of gas hydrate deposits. Rock and Soil Mechanics 2010, 31(10): 3069-3074. (in Chinese)