Upper bound solutions for supporting pressures of shallow tunnels with nonlinear failure criterion

Xiao-li Yang; Dao-bing Zhang; Zuo-wei Wang

doi:10.1007/s11771-013-1705-6

Journal of Central South University ›› 2013, Vol. 20 ›› Issue (7) : 2034 -2040. DOI: 10.1007/s11771-013-1705-6

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Upper bound solutions for supporting pressures of shallow tunnels with nonlinear failure criterion

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Abstract

Linear failure criterion is widely used in calculation of earth pressure acting on shallow tunnels. However, experimental evidence shows that nonlinear failure criterion is able to represent fairly well the failure of almost all types of rocks. A nonlinear Hoek-Brown failure criterion is employed to estimate the supporting pressures of shallow tunnels in limit analysis framework. Two failure mechanisms are proposed for calculating the work rate of external force and the internal energy dissipation. A tangential line to the nonlinear failure criterion is used to formulate the supporting pressure problem as a nonlinear programming problem. The objective function formulated in this way is minimized with respect to the failure mechanism and the location of tangency point. In order to assess the validity, the supporting pressures for the proposed failure mechanisms are calculated and compared with each other, and the present results are compared with previously published solutions when the nonlinear criterion is reduced to linear criterion. The agreement supports the validity of the proposed failure mechanisms. An experiment is conducted to investigate the influences of the nonlinear criterion on collapse shape and supporting pressures of shallow tunnels.

Keywords

shallow tunnel / nonlinear criterion / limit analysis / supporting pressure / failure mechanism

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Xiao-li Yang, Dao-bing Zhang, Zuo-wei Wang. Upper bound solutions for supporting pressures of shallow tunnels with nonlinear failure criterion. Journal of Central South University, 2013, 20(7): 2034-2040 DOI:10.1007/s11771-013-1705-6

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References

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

[1]	DavisE H, DunnM J, MairR J. The stability of shallow tunnels and underground openings in cohesive material [J]. Geotechnique, 1980, 30(3): 397-416

[2]	WangZ-weiSupporting pressures of shallow tunnels with nonlinear failure criterion [D], 2010ChangshaCentral South University

[3]	ChenW FLimit analysis and soil plasticity [M], 1975AmsterdamElsevier Science

[4]	ChenW F, LiuX LLimit analysis and soil plasticity [M], 1990AmsterdamElsevier Science

[5]	AgarJ G, MorgensternN R, ScottJ. Shear strength and stress-strain behavior of Athabasca oil sand at elevated temperatures and pressure [J]. Canadian Geotechnical Journal, 1987, 24(1): 1-10

[6]	BakerR. Nonlinear Mohr envelopes based on triaxial data [J]. Journal of Geotechnical and Geoenvironmental Engineering, 2004, 130(5): 498-506

[7]	CaiM, KaiserP K, TasakaY, MinamiM. Determination of residual strength of jointed rock masses using the GSI system [J]. International Journal of Rock Mechanics and mining Sciences, 2007, 44(2): 247-265

[8]	GoodmanR EIntroduction to Rock Mechanics [M], 19892nd EditionNew YorkJohn Wiley & Sons78-90

[9]	HobbsD. A study of the behaviour of broken rock under triaxial compression and its application to mine roadways [J]. International Journal of Rock Mechanics and Mining Sciences, 1966, 3(1): 11-43

[10]	LadanyiB. Use of the long-term strength concept in the determination of ground pressure of tunnel lining [C]. Proceeding of the 3rd Congress of International Society of Rock Mechanics on Advances in Rock Mech, 1970Washington DCNational Academy of Science1150-1156

[11]	SerranoA, OlallaC. Ultimate bearing capacity of an anisotropic discontinuous rock mass, Part one: Basic modes of failure [J]. International Journal of Rock Mechanics and Mining Sciences, 1998, 35(3): 301-324

[12]	SerranoA, OlallaC, GonzalecJ. Ultimate bearing capacity of rock masses based on the modified Hoek-Brown criterion [J]. International Journal Rock Mechanics Science & Geomechanics Abstract, 2000, 37(7): 1013-1018

[13]	SofianosA I, HalakatevakisN. Equivalent tunnelling Mohr-Coulomb strength parameters from given Hoek-Brown ones [J]. International Journal of Rock Mechanics and Mining Sciences, 2002, 39(1): 131-137

[14]	SofianosA I. Tunnelling Mohr-Coulomb strength parameters for rock masses satisfying the generalized Hoek-Brown criterion [J]. International Journal of Rock Mechanics and Mining Sciences, 2003, 40(5): 435-440

[15]	MaghousS, BuhanP, BekaertA. Failure design of jointed rock structure by means of a homogenization approach [J]. Mechanics of Cohesive-Frictional Materials, 1998, 13(2): 207-228

[16]	PerryJ. A technique for defining nonlinear shear strength envelopes and their incorporation in a slope stability method of analysis [J]. Quarterly Journal of Engineering Geology, 1994, 27(2): 231-241

[17]	YangF, YangJ S. Limit Analysis method for determination of earth pressure on shallow tunnel [J]. Engineering Mechanics, 2008, 25: 179-184

[18]	HoekE, Carranza-torresC, CorkumB. Hoek-Brown failure criterion-2002 edition [C]. Proceedings of the North American Rock Mechanics Society Meeting. Toronto, 2002267-273