Authors: K. Karuppasamy

Abstract:

In this paper, analysis of an infinite beam resting on multilayer tensionless extensible geosynthetic reinforced granular fill-poor soil system overlying soft soil strata under moving load with constant velocity is presented. The beam is subjected to a concentrated load moving with constant velocity. The upper reinforced granular bed is modeled by a rough membrane embedded in Pasternak shear layer overlying a series of compressible nonlinear winkler springs representing the underlying the very poor soil. The multilayer tensionless extensible geosynthetic layer has been assumed to deform such that at interface the geosynthetic and the soil have some deformation. Nonlinear behaviour of granular fill and the very poor soil has been considered in the analysis by means of hyperbolic constitutive relationships. Governing differential equations of the soil foundation system have been obtained and solved with the help of appropriate boundary conditions. The solution has been obtained by employing finite difference method by means of Gauss-Siedal iterative scheme. Detailed parametric study has been conducted to study the influence of various parameters on the response of soil–foundation system under consideration by means of deflection and bending moment in the beam and tension mobilized in the geosynthetic layer. These parameters include magnitude of applied load, velocity of load, damping, ultimate resistance of poor soil and granular fill layer. Range of values of parameters has been considered as per Indian Railway conditions. This study clearly observed that the comparisons of multilayer tensionless extensible geosynthetic reinforcement with poor foundation soil and magnitude of applied load, relative compressibility of granular fill and ultimate resistance of poor soil has significant influence on the response of soil–foundation system.

Keywords: Infinite beams, multilayer tensionless extensible geosynthetic, granular layer, moving load, nonlinear behavior of poor soil.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1108248

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References:

[1] Alekseyeva.L.A. (2006), “The Dynamic of an Elastic Half Space Under the Action of a Moving Load”, Journal of Applied Mathematics and Mechanics, vol 71, pp. 511-518.
[2] Basu, D. (2001), “Soil Structure Interaction Analysis due to Moving Load”. M.Tech. Thesis, Department of Civil Engineering, Indian Institute of Technology, Kanpur, India.
[3] Chandan Ghosh and Madhav M. R. (1994), “Settlement Response of a Reinforced Shallow Earth Bed”, Geotext. Geomembranes, Vol. 13, pp.643– 656.
[4] Choros, J. and Adams, G. G. (1979). “A Steadily Moving Load on an Elastic Beam Resting on a Tensionless Winkler Foundation”. Journal of Applied Mechanics Division, ASME, Vol. 46, No. 1, pp. 175-180.
[5] Duffy, D.G. (1990), “The Response of an Infinite Railroad Track to a Moving, Vibrating Mass”, Journal of Applied Mechanics Division, ASME, Vol. 57, No. 1, pp. 66-73.
[6] Jaiswal, O.R. and Iyenger, R.N. (1997), “Dynamic Response of Railway Tracks to Oscillatory Moving Masses”, Journal of Engineering Mechanics Division, ASCE, Vol. 123 No. 7, pp. 753-757.
[7] Karuppasamy, K (2010), “Non-Linear Response of Infinite Beams on Reinforced Earth Beds under Moving Load”. M.Tech. Thesis, Department of Civil Engineering, Indian Institute of Technology, Roorkee, India.
[8] Kerr A.D (1964), “Elastic and Visco-Elastic Foundation Models”, Journal of Applied Mechanics Division, Trans. of ASME 1964; 31 (3): 491-498.
[9] Kondner, R.L. and J.S. Zelasko. (1963), “A Hyperbolic Stress-Strain Response: Cohesive Soil”, Journal of the Soil Mechanics and Foundations Division, ASCE, 89(SM1):115-143
[10] Lin, L., and Adams, G.G., (1987), “Beam on Tensionless Elastic Foundation Subjected to Moving Load”, Vol. 113, No. 4.
[11] Sun Lu (2001). “Dynamic Displacement Response of Beam Type Structures to Moving Line Loads”. International Journal of solids and structures, vol 38, pp 8869 - 8878.
[12] Maheshwari, P., Basudhar, P. K., and Chandra, S. (2004b) “Response of Beams on a Tensionless Extensible Geosynthetic-Reinforced Earth Bed Subjected to Moving Loads”. Computer and Geotechnics, Vol. 31, pp. 537 – 548.
[13] Rao N.S.V. Kameswara (1974), “Onset of Separation between a Beam and Tensionless Foundation due to Moving Loads”, Journal of Applied Mechanics Division, Trans. of ASME 41 (1): 303-305.
[14] Saito, H. and Teresawa, T. (1980), “Steady-State Vibrations of a Beam on a Pasternak Foundation for Moving Loads”, Journal of Applied Mechanics Division, Trans. of ASME, Vol. 47, pp. 879-883.
[15] Selvadurai APS (1979), “Elastic Analysis of Soil–Foundation Interaction”. Elsevier Scientific Publication Company, Amsterdam, The Netherlands, 543 pp.
[16] Wang. M.C., Badie. A. and Davids. N. (1984), “Traveling Waves in Beam on Elastic Foundation”, Journal of Engineering Mechanics Division, ASCE, Vol. 110, No. 6, pp. 879-893.
[17] Yin J. H. “Modeling of Geosynthetic-Reinforced Granular Fill over Soft Soil”. Geosynthetic International 1997; 4(2): 165-85.
[18] Yin JH. “A Nonlinear Model of Geosynthetic-Reinforced Granular Fill over Soft Soil”, Geosynthetic International 1997; 4(5): 523-37.
[19] Yin JH, “Closed Form Solution for Reinforced Timoshenko Beam on Elastic Foundation”, J Appl Mech Div Trans, Am Soc. MechEng 2000; 12(8): 868-74.
[20] Islam, M. R., Rahman, M. T. and Tarefder, R. A. (2012). “Laboratory Investigation of the Stiffness and the Fatigue Life of Glass Grid Reinforced Asphalt Concrete.” International Journal of Pavements, Vol. 11, No. 1, pp. 82-91.