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Geotechnical and Geological Engineering

Erschienen in:

16.02.2018 | Original paper

Prediction of Time to Soil Failure Based on Creep Strength Reduction Approach

verfasst von: Thi Thanh Thuy Tran, Hemanta Hazarika, I. Gde Budi Indrawan, Dwikorita Karnawati

Erschienen in: Geotechnical and Geological Engineering | Ausgabe 4/2018

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Abstract

Soils experience the unrecoverable, continuous deformation known as creep when they are subjected to a stage of constant deviator stress. Creep deformation is due to extrusion of adsorbed water in clay particles, causing the non-recoverable deformation and eventually reduction in the soil shear strength. This study aims to develop a method to determine the creep strength reduction behaviour of soils and prediction of time to occurrence of the creep failure. Case studies on clayey soils including halloysite-rich soil and smectite-rich soil were chosen. A series of triaxial creep tests were conducted in order to obtain the necessary experimental data. Based on the results, the ultimate long-term creep strength or critical stress level of halloysite-rich soil and smectite-rich soil was 85 and 55% of the soil peak strength, respectively. The ultimate time of creep strength reduction in halloysite-rich soil and smectite-rich soil was 10.34 and 46.08 years, respectively. The maximum creep strength reduction ratio of halloysite-rich soil and smectite-rich soil was 0.2 and 0.45, respectively. The developed method allowed predicting time to creep failure of soil specimens.

Vorheriger Artikel Full-Scale Hydro-Mechanical Properties of Vertical Flow Bed Treatment Soils

Nächster Artikel Effects of Asperity Angle and Infill Thickness on Shear Characteristics Under Constant Normal Load Conditions

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Allen DL (1973) The creep response of cohesive soils: a method of design using rheological strength parameters. In: Final report 382, KYHPR65-38, HPR-1(9), Part II, Devision of Research, Bureau of Highways, Department of Transportation, Commonwealth of Kentucky

Anderson EW (1977) Soil creep: an assessment of certain controlling factors with special reference to upper Weardale England. Thesis (Ph.D.), Durham University. Durham E-Theses Online: http://etheses.dur.ac.uk/8394/, 1–585

Emery JJ (1966) Finite element analysis of creep problems in soil mechanics. Thesis (Ph.D.), Department of Civil Engineering, The University of British Columbia, pp 1–155

Franca FAN, Bueno BS (2011) Creep behavior of geosynthetics using confined-accelerated tests. Geosynthetics Int 18(5):242–254CrossRef

Fredrik K, Anders P (2003) Modeling non-linear dynamics of rubber bushings – parameter identification and validation. KFS I Lund AB, Lund, Sweden, pp 1–144

Fukuzono T (1985) A new method for predicting the failure time of a slope. In: Proceeding IV, international conference and field workshop on landslides, Tokyo, pp 145–150

Goldstein MN, Babitskaya SS (1959) Methods of determining the long term strength of soils. Osn Fund I Mekh Gruntov 4:11–14

Highland LM, Bobrowsky P (2008) The landslide handbook—a guide to understanding landslides. U.S. Geological Survey, Reston, pp 1–129

Johnson LD (1967) Consolidated-undrained triaxial creep test of ST. Charles Parish Lakefront clays, US. Army Engineer Waterways Experiment Station Soils and Pavements Laboratory, pp 1–50

Kwork CY, Bolton MD (2010) DEM simulations of thermally activated creep in soils. Geotechnique 60(6):425–433

Owens IF (1967) Mass movement in the Chilton valley. Thesis (Master), Arts in Geography, pp 1–92

Purushothama PR (2008) Soil mechanics and foundation engineering—chapter 9: shear strength of soils. Dorling Kindersley Pvt. Ltd., Noida, pp 243–286

Quantin P (1991) Specificity of the halloysite-rich tropical or subtropical soil. O.R.S.T.O.M. Fonas Documentare, No. 31994, pp 16–21

Saito M, Uezawa H (1960) An experimental study on creep rupture of soil. In: Railway technical research report, no. 128

Sayles FH (1973) Triaxial and creep tests on frozen Ottawa sand. Permafrost: North American contribution [to the] second international conference, pp 384–391

Singh A, Mitchell JK (1968) A general stress–strain–time function for soils. J Soil Mech Found Div ASCE 94:21–46

Soga K (2005) Lecture 3: time effects observed in granular materials. Socioenvironmental engineering, COE Hokkaido University, Hokkaido, Japan, http://www.eng.hokudai.ac.jp/COE-area/workshop/pdf/05feb_lec_soga3.pdf, pp 1–22. Accessed 8 Oct 2017

Suhonen K (2010) Creep of soft clay. Thesis (Master), Faculty of Engineering and Architecture, Allto University, pp 1–103

Terzaghi K (1950) Mechanism of landslides—application of geology to engineering practice. Berkey volume. Geological Society of America, New York, pp 83–123

Van Asch TWJ, Genuchten PMBV (1990) A comparison between theoretical and measured creep profiled of landslides. Geomorphology 3:45–55CrossRef

Van Asch TWJ, Deimel MS, Haak WJ, Simon J (1989) Viscous creep component in shallow clayey soil and the influence of tree load on creep rates. Earth Surf Proc Land 14:557–564CrossRef

Vermeer PA, Neher HP (2000) A soft soil model that accounts for creep. Beyond 2000. In: Computational geotechnics—10 years of Plaxis international, ISBN 905809040, pp 1–13

Vyalov SS (1966) Methods of determining creep, long-term strength and compressibility characteristics of frozen soils. Natl Res Counc Can Tech Transl, TT, p 1364

Vyalov SS (1986) Chapter 9: long-term strength of soil—rheological fundamentals of foil mechanics. In: Developments in geotechnical engineering, vol 36. Elsevier Science Publishers B.V., pp 285–338

Weisstein EW (2017) Least squares fitting-logarithmic. From MathWorld–a wolfram web resource. http://mathworld.wolfram.com/LeastSquaresFittingLogarithmic.html. Accessed 30 Sept 2017

Ye Y, Zhang Q, Cai D, Chen F, Yao J, Wang L (2013) Study on new method of accelerated clay creep characteristics test. In: Proceedings of the 18th international conference on soil mechanics and geotechnical engineering, Paris, pp 461–464

Ziemer RR (1977) Measurement of soil creep by inclinometer. In: Engineering technical report, forest service, U.S. Department of Agriculture Washington, D.C. 20013, pp 1–10

Titel: Prediction of Time to Soil Failure Based on Creep Strength Reduction Approach
verfasst von: Thi Thanh Thuy Tran
Hemanta Hazarika
I. Gde Budi Indrawan
Dwikorita Karnawati
Publikationsdatum: 16.02.2018
Verlag: Springer International Publishing
Erschienen in: Geotechnical and Geological Engineering / Ausgabe 4/2018
Print ISSN: 0960-3182
Elektronische ISSN: 1573-1529
DOI: https://doi.org/10.1007/s10706-018-0496-9

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