Threshold Stress of the Soil Subgrade Evaluation for Highway Formations
The objective of this study is to evaluate the threshold
stress of the clay with sand subgrade soil. Threshold stress can be
defined as the stress level above which cyclic loading leads to
excessive deformation and eventual failure. The thickness
determination of highways formations using the threshold stress
approach is a more realistic assessment of the soil behaviour because
it is subjected to repeated loadings from moving vehicles. Threshold
stress can be evaluated by plastic strain criterion, which is based on
the accumulated plastic strain behaviour during cyclic loadings [1].
Several conditions of the all-round pressure the subgrade soil namely,
zero confinement, low all-round pressure and high all-round pressure
are investigated. The threshold stresses of various soil conditions are
determined. Threshold stress of the soil are 60%, 31% and 38.6% for
unconfined partially saturated sample, low effective stress saturated
sample, high effective stress saturated sample respectively.
[1] Shahu, J. T., Yudhbir, and Kameswara Rao, N.S.V. 1999. "Effective
stress behavior of quasi-saturated compacted cohesive soils." Journal of
Geotechnical and Geoenvironmental Engineering, Vol 125 pp. 322-329.
[2] Huang H. Yang. 1993. Pavement Analysis and Design, Prentice Hall
Englewood Cliff, New Jersey.
[3] Ishihara, K. 1993. Liquefaction and Flow Failure During Earthquakes,
The 33rd Rankine Lecture. Geotechnique, Vol. 43, No. 3, pp. 351-415
[4] Wood, D M. 1982 Laboratory investigations of the behaviour of soils
under cyclic loading: A Review. Soil Mechanics- transient and cyclic
loads,"Pande, G.N. and Zienkiewicz, O.C (eds) John Wiley and Sons.,
pp. 513-582
[5] Brown, S. F. and Dawson, A. R. 1992. Two-stage approach to asphalt
pavement design, Proceeding 7th International Conf. Asphalt
Pavements, Nottingham.
[6] ORE. 1970. Question D71; Stresses in the Rails, the Ballast and in the
Formations Resulting from Traffic Load, Report no.12; Repeated
loading of Clay and Track Foundation Design, Report no. D71 / RP12,
Office for Research and Experiments-International Union of Railways
Utrecht, Netherlands.
[7] Cheung, L.W. 1994. Laboratory Assessment of Pavement Foundation
Materials. Ph.D. Thesis, University of Nottingham, Nottingham, UK
[8] Barksdale, R. 1997. Laboratory Determination of Resilient Modulus for
Flexible Pavement Design: Final Report, NCHRP Web Doc 14, National
Cooperative Highway Research Program, Washington DC.
[9] Dobry, R., Ladd, R. S., Yokel, F. Y., Chung, R. M., and Powell, D.
1982. Prediction of pore-water pressure buildup and liquefaction of
sands during earthquakes by the cyclic strain method. National Bureau
of Standards Building Science Series No. 138.
[10] Matasovic, N. and Vucetic, M. 1995. Generalized Cyclic-Degradation-
Pore Pressure Generation Model for Clays, Journal of Geotechnical
Engineering, Vol. 121 No.1.
[11] Shahu, J. T., Yudhbir, and Kameswara Rao, N.S.V. 2000. A Rational
Method for Design of Railroad Track Foundation, Soils and
Foundations, Japanese Geotechnical Society, Soil and Foundation
vol.40.
[12] Frost, M.W., Fleming, P.R and Rogers, C.D.F. 2004. Cyclic Triaxial
Tests on Clay Subgrades for Analytical Pavement Design, Journal
Transport Engineering, Volume 130, Issue 3, pp. 378-386 (May/June
2004)
[13] Attya, A., Indraratna, B., and Rujikiatkamjorn, C. 2007. Cyclic
behaviour of PVD-soft soil subgrade for improvement of railway tracks.
Proceedings of the 10th Australia New Zealand Conference on
Geomechanics, Brisbane, Australia, 21-24 October 2007, 2, 36-41
[14] Brown, S. F., Lashine,A.K.F., and Hyde, A. F.L. 1975. Repeated load
testing of a silty clay. Geotechnique, 25(1) 95-114.
[15] Yudhbir, Kameswara Rao, N. S. V, and Shahu, J. T. 1995. A Rational
Approach to the Design of Railway Formation, Earthquake Geotechnical
Engineering, Ishihara (ed.), Balkema
[16] Elliott, R. P., and Thompson, M. R. 1985. ILLI-PAVE Mechanistic
Analysis of AASHO Road Test Flexible Pavements, TRR 1043, TRB,
Washington D. C. 39-49.
[17] Hyde, A. F. L. and Brown, S. F. 1976. The Plastic Deformation of A
Silty Clay Under Creep and Repeated Loading, Geotechnique, London,
England, 26(1), 173-184.
[18] Shahu, J. T. 1993. Some Analytical and Experimental Investigations to
Study the Behaviour of Soil under Railway Tracks, PhD Thesis of
Indian Institute of Technology, at Kanpur India.
[19] Ansal, A., Iyisan, R, and Yildirim, H. 2001.The Cyclic Behaviour of
Soils and Effects of Geotechnical Factors in Microzonation, Soil
Dynamics and Earthquake Engineering
[20] Elliott, R. P., Dennis N. D., and Qiu, Yanjun. 1998. Permanent
Deformation of Subgrade Soils, A test Protocol, Department of Civil
Engineering University of Arkansas Fayetteville, AR 72701.
[21] Altun, S., and Goktepe, A. B. 2006. Cyclic Stress-Strain Behaviour of
Partially Saturated Soils, ASCE Proceedings of the Fourth International
Conference on Unsaturated Soils
[22] Craig, R.F. 1992. Soil Mechanics, Chapman and Hall, 5th edition,
London, UK
[23] Towhata, Ikuo. 2008. Geotechnical Earthquake Engineering, publisher: ,
ISBN: 3540357823, 9783540357827
[24] Diaz-Rodriguez, J. A and L├│pez-Molina, J. A. 2008. Strain Thresholds
in Soil Dynamics, the 14 World Conference on Earthquake Engineering,
October 12-17, 2008, Beijing, China.
[25] Yudhbir, Kameswara Rao, N. S. V, and Shahu, J. T. 1998. A Rational
View of Track Maintenance, Joint Seminar on Bilateral Co-operation for
Railway Research, European Rail Research Institute and Indian
Railways, Vigyan Bhawan, New Delhi.
[26] Larew, H. G., and Leonards, G. A. 1962. A Strength Criterion for
Repeated Loads. Proceedings of the Highway Research Board, No. 41,
525-556
[1] Shahu, J. T., Yudhbir, and Kameswara Rao, N.S.V. 1999. "Effective
stress behavior of quasi-saturated compacted cohesive soils." Journal of
Geotechnical and Geoenvironmental Engineering, Vol 125 pp. 322-329.
[2] Huang H. Yang. 1993. Pavement Analysis and Design, Prentice Hall
Englewood Cliff, New Jersey.
[3] Ishihara, K. 1993. Liquefaction and Flow Failure During Earthquakes,
The 33rd Rankine Lecture. Geotechnique, Vol. 43, No. 3, pp. 351-415
[4] Wood, D M. 1982 Laboratory investigations of the behaviour of soils
under cyclic loading: A Review. Soil Mechanics- transient and cyclic
loads,"Pande, G.N. and Zienkiewicz, O.C (eds) John Wiley and Sons.,
pp. 513-582
[5] Brown, S. F. and Dawson, A. R. 1992. Two-stage approach to asphalt
pavement design, Proceeding 7th International Conf. Asphalt
Pavements, Nottingham.
[6] ORE. 1970. Question D71; Stresses in the Rails, the Ballast and in the
Formations Resulting from Traffic Load, Report no.12; Repeated
loading of Clay and Track Foundation Design, Report no. D71 / RP12,
Office for Research and Experiments-International Union of Railways
Utrecht, Netherlands.
[7] Cheung, L.W. 1994. Laboratory Assessment of Pavement Foundation
Materials. Ph.D. Thesis, University of Nottingham, Nottingham, UK
[8] Barksdale, R. 1997. Laboratory Determination of Resilient Modulus for
Flexible Pavement Design: Final Report, NCHRP Web Doc 14, National
Cooperative Highway Research Program, Washington DC.
[9] Dobry, R., Ladd, R. S., Yokel, F. Y., Chung, R. M., and Powell, D.
1982. Prediction of pore-water pressure buildup and liquefaction of
sands during earthquakes by the cyclic strain method. National Bureau
of Standards Building Science Series No. 138.
[10] Matasovic, N. and Vucetic, M. 1995. Generalized Cyclic-Degradation-
Pore Pressure Generation Model for Clays, Journal of Geotechnical
Engineering, Vol. 121 No.1.
[11] Shahu, J. T., Yudhbir, and Kameswara Rao, N.S.V. 2000. A Rational
Method for Design of Railroad Track Foundation, Soils and
Foundations, Japanese Geotechnical Society, Soil and Foundation
vol.40.
[12] Frost, M.W., Fleming, P.R and Rogers, C.D.F. 2004. Cyclic Triaxial
Tests on Clay Subgrades for Analytical Pavement Design, Journal
Transport Engineering, Volume 130, Issue 3, pp. 378-386 (May/June
2004)
[13] Attya, A., Indraratna, B., and Rujikiatkamjorn, C. 2007. Cyclic
behaviour of PVD-soft soil subgrade for improvement of railway tracks.
Proceedings of the 10th Australia New Zealand Conference on
Geomechanics, Brisbane, Australia, 21-24 October 2007, 2, 36-41
[14] Brown, S. F., Lashine,A.K.F., and Hyde, A. F.L. 1975. Repeated load
testing of a silty clay. Geotechnique, 25(1) 95-114.
[15] Yudhbir, Kameswara Rao, N. S. V, and Shahu, J. T. 1995. A Rational
Approach to the Design of Railway Formation, Earthquake Geotechnical
Engineering, Ishihara (ed.), Balkema
[16] Elliott, R. P., and Thompson, M. R. 1985. ILLI-PAVE Mechanistic
Analysis of AASHO Road Test Flexible Pavements, TRR 1043, TRB,
Washington D. C. 39-49.
[17] Hyde, A. F. L. and Brown, S. F. 1976. The Plastic Deformation of A
Silty Clay Under Creep and Repeated Loading, Geotechnique, London,
England, 26(1), 173-184.
[18] Shahu, J. T. 1993. Some Analytical and Experimental Investigations to
Study the Behaviour of Soil under Railway Tracks, PhD Thesis of
Indian Institute of Technology, at Kanpur India.
[19] Ansal, A., Iyisan, R, and Yildirim, H. 2001.The Cyclic Behaviour of
Soils and Effects of Geotechnical Factors in Microzonation, Soil
Dynamics and Earthquake Engineering
[20] Elliott, R. P., Dennis N. D., and Qiu, Yanjun. 1998. Permanent
Deformation of Subgrade Soils, A test Protocol, Department of Civil
Engineering University of Arkansas Fayetteville, AR 72701.
[21] Altun, S., and Goktepe, A. B. 2006. Cyclic Stress-Strain Behaviour of
Partially Saturated Soils, ASCE Proceedings of the Fourth International
Conference on Unsaturated Soils
[22] Craig, R.F. 1992. Soil Mechanics, Chapman and Hall, 5th edition,
London, UK
[23] Towhata, Ikuo. 2008. Geotechnical Earthquake Engineering, publisher: ,
ISBN: 3540357823, 9783540357827
[24] Diaz-Rodriguez, J. A and L├│pez-Molina, J. A. 2008. Strain Thresholds
in Soil Dynamics, the 14 World Conference on Earthquake Engineering,
October 12-17, 2008, Beijing, China.
[25] Yudhbir, Kameswara Rao, N. S. V, and Shahu, J. T. 1998. A Rational
View of Track Maintenance, Joint Seminar on Bilateral Co-operation for
Railway Research, European Rail Research Institute and Indian
Railways, Vigyan Bhawan, New Delhi.
[26] Larew, H. G., and Leonards, G. A. 1962. A Strength Criterion for
Repeated Loads. Proceedings of the Highway Research Board, No. 41,
525-556
@article{"International Journal of Architectural, Civil and Construction Sciences:57276", author = "Elsa Eka Putri and N.S.V Kameswara Rao and M. A. Mannan", title = "Threshold Stress of the Soil Subgrade Evaluation for Highway Formations", abstract = "The objective of this study is to evaluate the threshold
stress of the clay with sand subgrade soil. Threshold stress can be
defined as the stress level above which cyclic loading leads to
excessive deformation and eventual failure. The thickness
determination of highways formations using the threshold stress
approach is a more realistic assessment of the soil behaviour because
it is subjected to repeated loadings from moving vehicles. Threshold
stress can be evaluated by plastic strain criterion, which is based on
the accumulated plastic strain behaviour during cyclic loadings [1].
Several conditions of the all-round pressure the subgrade soil namely,
zero confinement, low all-round pressure and high all-round pressure
are investigated. The threshold stresses of various soil conditions are
determined. Threshold stress of the soil are 60%, 31% and 38.6% for
unconfined partially saturated sample, low effective stress saturated
sample, high effective stress saturated sample respectively.", keywords = "threshold stress, cyclic loading, pore water pressure.", volume = "6", number = "8", pages = "613-7", }
