Research Article
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Year 2021, , 66 - 74, 30.09.2021
https://doi.org/10.19072/ijet.937666

Abstract

References

  • Bjerrum L (1973) Problems of soil mechanics and construction on soft clays. Proceedings 8th Int. Conf. Soil Mech. and Found. Eng. Moscow, 3: 111–159
  • Lunne T, Berre T, Strandvik S (1997) Sample disturbance effects in soft low plastic Norwegian clay. Conference on Recent Developments in Soil and Pavement Mechanics, Rio de Janeiro, June 1997, 81–102
  • Nearing, M.A and West L.T (1988) Soil strength indices as indicators of consolidation, American society of agricultural engineers, vol. 31(2)
  • Leoni A.J (2009) Characterization of post pampean clays, Proceedings of the 17th International Conference on Soil Mechanics and Geotechnical Engineering Alexandria
  • Vahedifard F, Isaac L. Howard, Walaa H. Badran M., William D. Carruth C., (2016) Strength indices of high-moisture soils using handheld gauges, Proceedings of the Institution of Civil Engineers - Ground Improvement vol 169, No.3
  • Howard, I. & Badran, W. (2011) Comparison of Hand Held Gage and Unconfined Compression Results in Low Strength Cementitious Stabilized Materials. Geo-Frontiers 2011: pp. 2574-2583.
  • Kayabali K. (2011), Consistency limits – A reappraisal, EJGE, vol. 16
  • Mohd J., Mohd A., Taha, R. Ahmed J Abu Kassim A. Jamaludin A, J. & Jaaadil A (1997) Prediction and Determination of Undrained Shear Strength of Soft Clay at Bukit Raja, Pertanika J.Sci. & Technology, (5), pp111-126.
  • Ghosh R. (2013), Effect of soil moisture in the analysis of undrained shear strength of compacted clayey soil, J. civil Eng. & construction technology, vol. 4(1), pp 23-31
  • Velosa, C.L. Remmes, B., and Bik, M. (2013). Strength characterization of soft marine deposits off East Africa using the CPT Stinger method. Report by TDI-Brooks International, Inc., 14391 S. Dowling RD, College Station, TX 77845, USA.
  • Li Y., Hu G., Wu N., Liu C., Chen Q., Li C., (2019) Undrained shear strength evaluation for hydrate-bearing sediment overlying strata in the Shenhu area, northern South China Sea, Acta Oceanologica Sinica -English Edition- 38(3):114-123
  • Ebrahimian B., Movahed V., Nazari A. (2013) Soil charactrisation of South pars field persian gulf, Envirnmental geotechnics Volume 1 Issue 2, May 2014, pp. 96-107.
  • ASTM D3213-91(1997) Standard Practices for Handling, Storing, and Preparing Soft Undisturbed Marine Soil STANDARD by ASTM International.
  • ASTM D4648 -00 (2016) Standard Test Methods for Laboratory Miniature Vane Shear Test for Saturated Fine-Grained Clayey Soil. STANDARD by ASTM International
  • D’Ignazio M. and Phoon K. (2016), Correlations for undrained shear strength of Finnish soft clays, Canadian Geotechnical Journal, 53(10)
  • Vipulanandan C., Ahossin Guezo Y.J. and Bilgin O. (2007) Geotechnical Properties of Marine and Deltaic Soft Clays, Advances in Measurement and Modelling of Soil Behaviour, Geo-Denver: New Peaks in Geotechnics
  • Mesri, G. (1989). A re-evaluation of su(mob) = 0.22σp’ using laboratory shear tests. Canadian Geotechnical Journal, 26(1): 162-164.
  • Barros J. M. C. Amaral C. S & Silveira R. M. S (2009) Geotechnical properties of Brazilian marine clays Proceedings of the 17th International Conference on Soil Mechanics and Geotechnical Engineering Alexandria
  • Mayne p w Coop M R Springman S Huang A B and Zoenberg J 2009, Geomaterial behaviour and testing, 17th ICSMGE EGYPT Vol 4 pp 2777-2872
  • Kamei K. (1996) Undrained shear strength and interrelationships among CIUC, CKoUC, ClUE, and CKoUE tests, Geoscience RepL, Shimane Univ., 15, p. I 37-145
  • O`Kelly B.C. (2013) Atterberg limits and remoulded shear strength – water content relationships ASTM Geotechnical testing journal, vol.36, No 6
  • Wroth C.P. (1984), The interpretation of in situ soil tests, Geotechnique 34, No. 4,
  • Ratananikom W., Yimsiri S., and Likitlersuang S., (2015), Undrained Shear Strength of Very Soft to Medium Stiff Bangkok Clay from Various Laboratory Tests, Geotechnical Engineering, Journal of the SEAGS & AGSSEA Vol. 46 No.1
  • Sharma & Bora B.K. (2003) Plastic Limit, Liquid Limit and Undrained Shear Strength of Soil—Reappraisal ASCE J geotechnical and geoenviromental engineering.
  • Skempton, A.W. (1957) “The Planning and Design of New Hong kong Airport”. Proceeding. London: Institute of Civil Engineering, 7 305–307.
  • Lemos S.G.F.P. and Pires P.J.M. (2017), The Undrained Strength of Soft Clays Determined from Unconventional and Conventional Tests, Soils and Rocks, São Paulo, 40(3): 291-301.
  • Koumoto, T. & Houlsby, G. T. (2001). Theory and practice of the fall cone test, Geootechnique 51, No. 8,
  • Bjerrum, L., & N.E. Simons. (1960) Comparison of Shear Strength Characteristics of Normally Consolidated Clay. Proceedings. Research Conference on Shear Strength of Cohesive Soils, 1771–1726.
  • DeGroot D.J., Lunne T., Shankar R., Knudsen S., Jones C.D. and Yetginer-Tjelta T. I. (2016) Engineering properties of low to medium overconsolidation ratio offshore clays, AIMS Geosciences, 5(3): 535–567.

Laboratory Evaluation of Undrained Shear Strength of a Soft Fine Grained Soils

Year 2021, , 66 - 74, 30.09.2021
https://doi.org/10.19072/ijet.937666

Abstract

The determination of undrained shear strength of soils is commonly achieved using triaxial testing in which specimen is carefully prepared before testing to maintain its original field condition. However, for soft soils preparing and handling specimens without causing any disturbance is a difficult job and may not always be successful. Other laboratory testing techniques can be adopted provided they can produce reliable results for such cases and can overcome the problem of pretest preparation process and hence avoiding any alteration of sample field condition. Extensive laboratory investigation on a soft marine soil recovered from sea bed offshore of Benghazi city, the testing program involves investigation of the basic geotechnical properties, focusing specifically on the determination of the undrained shear strength of such soils as determined by both the conventional unconsolidated undrained triaxial testing (UU) and the simple laboratory vane shear testing device (Miniature shear vane MV). The resulting shear strength obtained by UU-triaxial test, and resulting shear strength measured by Miniature shear vane MV were examined, compared and discussed on the light of other research works. Furthermore, the problems faced during testing soft samples in triaxial apparatus was also presented. The resulting undrained shear strength obtained by UU-triaxial test was found generally lower than that produced by Miniature shear vane MV which is attributed to sample disturbance before testing in triaxial. The study also demonstrates that despite of high scatter, the undrained shear strength obtained by MV can be reasonably comparable with the results of other investigations on soft soils.

References

  • Bjerrum L (1973) Problems of soil mechanics and construction on soft clays. Proceedings 8th Int. Conf. Soil Mech. and Found. Eng. Moscow, 3: 111–159
  • Lunne T, Berre T, Strandvik S (1997) Sample disturbance effects in soft low plastic Norwegian clay. Conference on Recent Developments in Soil and Pavement Mechanics, Rio de Janeiro, June 1997, 81–102
  • Nearing, M.A and West L.T (1988) Soil strength indices as indicators of consolidation, American society of agricultural engineers, vol. 31(2)
  • Leoni A.J (2009) Characterization of post pampean clays, Proceedings of the 17th International Conference on Soil Mechanics and Geotechnical Engineering Alexandria
  • Vahedifard F, Isaac L. Howard, Walaa H. Badran M., William D. Carruth C., (2016) Strength indices of high-moisture soils using handheld gauges, Proceedings of the Institution of Civil Engineers - Ground Improvement vol 169, No.3
  • Howard, I. & Badran, W. (2011) Comparison of Hand Held Gage and Unconfined Compression Results in Low Strength Cementitious Stabilized Materials. Geo-Frontiers 2011: pp. 2574-2583.
  • Kayabali K. (2011), Consistency limits – A reappraisal, EJGE, vol. 16
  • Mohd J., Mohd A., Taha, R. Ahmed J Abu Kassim A. Jamaludin A, J. & Jaaadil A (1997) Prediction and Determination of Undrained Shear Strength of Soft Clay at Bukit Raja, Pertanika J.Sci. & Technology, (5), pp111-126.
  • Ghosh R. (2013), Effect of soil moisture in the analysis of undrained shear strength of compacted clayey soil, J. civil Eng. & construction technology, vol. 4(1), pp 23-31
  • Velosa, C.L. Remmes, B., and Bik, M. (2013). Strength characterization of soft marine deposits off East Africa using the CPT Stinger method. Report by TDI-Brooks International, Inc., 14391 S. Dowling RD, College Station, TX 77845, USA.
  • Li Y., Hu G., Wu N., Liu C., Chen Q., Li C., (2019) Undrained shear strength evaluation for hydrate-bearing sediment overlying strata in the Shenhu area, northern South China Sea, Acta Oceanologica Sinica -English Edition- 38(3):114-123
  • Ebrahimian B., Movahed V., Nazari A. (2013) Soil charactrisation of South pars field persian gulf, Envirnmental geotechnics Volume 1 Issue 2, May 2014, pp. 96-107.
  • ASTM D3213-91(1997) Standard Practices for Handling, Storing, and Preparing Soft Undisturbed Marine Soil STANDARD by ASTM International.
  • ASTM D4648 -00 (2016) Standard Test Methods for Laboratory Miniature Vane Shear Test for Saturated Fine-Grained Clayey Soil. STANDARD by ASTM International
  • D’Ignazio M. and Phoon K. (2016), Correlations for undrained shear strength of Finnish soft clays, Canadian Geotechnical Journal, 53(10)
  • Vipulanandan C., Ahossin Guezo Y.J. and Bilgin O. (2007) Geotechnical Properties of Marine and Deltaic Soft Clays, Advances in Measurement and Modelling of Soil Behaviour, Geo-Denver: New Peaks in Geotechnics
  • Mesri, G. (1989). A re-evaluation of su(mob) = 0.22σp’ using laboratory shear tests. Canadian Geotechnical Journal, 26(1): 162-164.
  • Barros J. M. C. Amaral C. S & Silveira R. M. S (2009) Geotechnical properties of Brazilian marine clays Proceedings of the 17th International Conference on Soil Mechanics and Geotechnical Engineering Alexandria
  • Mayne p w Coop M R Springman S Huang A B and Zoenberg J 2009, Geomaterial behaviour and testing, 17th ICSMGE EGYPT Vol 4 pp 2777-2872
  • Kamei K. (1996) Undrained shear strength and interrelationships among CIUC, CKoUC, ClUE, and CKoUE tests, Geoscience RepL, Shimane Univ., 15, p. I 37-145
  • O`Kelly B.C. (2013) Atterberg limits and remoulded shear strength – water content relationships ASTM Geotechnical testing journal, vol.36, No 6
  • Wroth C.P. (1984), The interpretation of in situ soil tests, Geotechnique 34, No. 4,
  • Ratananikom W., Yimsiri S., and Likitlersuang S., (2015), Undrained Shear Strength of Very Soft to Medium Stiff Bangkok Clay from Various Laboratory Tests, Geotechnical Engineering, Journal of the SEAGS & AGSSEA Vol. 46 No.1
  • Sharma & Bora B.K. (2003) Plastic Limit, Liquid Limit and Undrained Shear Strength of Soil—Reappraisal ASCE J geotechnical and geoenviromental engineering.
  • Skempton, A.W. (1957) “The Planning and Design of New Hong kong Airport”. Proceeding. London: Institute of Civil Engineering, 7 305–307.
  • Lemos S.G.F.P. and Pires P.J.M. (2017), The Undrained Strength of Soft Clays Determined from Unconventional and Conventional Tests, Soils and Rocks, São Paulo, 40(3): 291-301.
  • Koumoto, T. & Houlsby, G. T. (2001). Theory and practice of the fall cone test, Geootechnique 51, No. 8,
  • Bjerrum, L., & N.E. Simons. (1960) Comparison of Shear Strength Characteristics of Normally Consolidated Clay. Proceedings. Research Conference on Shear Strength of Cohesive Soils, 1771–1726.
  • DeGroot D.J., Lunne T., Shankar R., Knudsen S., Jones C.D. and Yetginer-Tjelta T. I. (2016) Engineering properties of low to medium overconsolidation ratio offshore clays, AIMS Geosciences, 5(3): 535–567.
There are 29 citations in total.

Details

Primary Language English
Subjects Engineering
Journal Section Makaleler
Authors

Suleiman Khatrush 0000-0001-5586-0233

Ghassan El-gehanı This is me

Publication Date September 30, 2021
Acceptance Date December 15, 2021
Published in Issue Year 2021

Cite

APA Khatrush, S., & El-gehanı, G. (2021). Laboratory Evaluation of Undrained Shear Strength of a Soft Fine Grained Soils. International Journal of Engineering Technologies IJET, 7(3), 66-74. https://doi.org/10.19072/ijet.937666
AMA Khatrush S, El-gehanı G. Laboratory Evaluation of Undrained Shear Strength of a Soft Fine Grained Soils. IJET. September 2021;7(3):66-74. doi:10.19072/ijet.937666
Chicago Khatrush, Suleiman, and Ghassan El-gehanı. “Laboratory Evaluation of Undrained Shear Strength of a Soft Fine Grained Soils”. International Journal of Engineering Technologies IJET 7, no. 3 (September 2021): 66-74. https://doi.org/10.19072/ijet.937666.
EndNote Khatrush S, El-gehanı G (September 1, 2021) Laboratory Evaluation of Undrained Shear Strength of a Soft Fine Grained Soils. International Journal of Engineering Technologies IJET 7 3 66–74.
IEEE S. Khatrush and G. El-gehanı, “Laboratory Evaluation of Undrained Shear Strength of a Soft Fine Grained Soils”, IJET, vol. 7, no. 3, pp. 66–74, 2021, doi: 10.19072/ijet.937666.
ISNAD Khatrush, Suleiman - El-gehanı, Ghassan. “Laboratory Evaluation of Undrained Shear Strength of a Soft Fine Grained Soils”. International Journal of Engineering Technologies IJET 7/3 (September 2021), 66-74. https://doi.org/10.19072/ijet.937666.
JAMA Khatrush S, El-gehanı G. Laboratory Evaluation of Undrained Shear Strength of a Soft Fine Grained Soils. IJET. 2021;7:66–74.
MLA Khatrush, Suleiman and Ghassan El-gehanı. “Laboratory Evaluation of Undrained Shear Strength of a Soft Fine Grained Soils”. International Journal of Engineering Technologies IJET, vol. 7, no. 3, 2021, pp. 66-74, doi:10.19072/ijet.937666.
Vancouver Khatrush S, El-gehanı G. Laboratory Evaluation of Undrained Shear Strength of a Soft Fine Grained Soils. IJET. 2021;7(3):66-74.

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