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Dams in many countries including India were primarily designed on the basis of approximate hand calculation based method. A frequent occurrence of floods due to a failure of such dams and embankments clearly points to the need of a review of the procedure of dam analysis methodologies and to suggest a reasonably accurate one. The paper is a limited effort for the same, based on three Indian dams. As a very preliminary step of the whole plan of checking the safety of Indian dams, an analysis of three dams having similar features as that of Chirpatia Dam (Rajasthan), an earthen embankment dam, Koyna Dam (Maharastra), a concrete gravity dam and the earthen embankment surrounding Ash Pond of Bakreswar Thermal Power Project (West Bengal), have been carried out with the help of two-dimensional and three-dimensional finite element discretisation under static loading conditions. The result is then compared with the corresponding results obtained from a conventional hand calculation based on approximate gravity method of analysis. The comparison of the results exhibited a considerable increase in compressive stresses in two-dimensional finite element analysis with respect to what is obtained in the conventional hand calculation based approximate gravity method. Both of these methods considered an in-plane stress distribution along a cross-section of the dam and hence, could not recognize any possibility of stress generation perpendicular to the cross-section. In this context, a three-dimensional study reveals that considerable stresses may generate even in the longitudinal direction of a dam that is generally ignored in hand calculation based gravity method of analysis and two-dimensional analysis due to the assumption of the two-dimensional nature of the problem. A rigorous finite element analysis also shows that even tensile stress may generate under static loading conditions which can hardly be predicted from the conventional method. It is also observed that hand calculation based on slip-circle method and two-dimensional analysis cannot adequately recognize the possibility of shear failure at many points in the body of the dam though their vulnerability due to itself and so it is necessary to point out by a rigorous three-dimensional modeling and analysis. Thus, the study suggests the unavoidable necessity of three-dimensional analysis for a safe design of dams.
Rocznik
Tom
Strony
461--482
Opis fizyczny
Bibliogr. 18 poz., rys., tab.
Twórcy
autor
- Department of Applied Mechanics, Bengal Engineering College (Deemed University) Howrah 711 103, West Bengal, INDIA
autor
- Department of Applied Mechanics, Bengal Engineering College (Deemed University) Howrah 711 103, West Bengal, INDIA
autor
- Department of Applied Mechanics, Bengal Engineering College (Deemed University) Howrah 711 103, West Bengal, INDIA
Bibliografia
- [1] Adhikari D.P. and Chattopadhyay A. (1996): Behaviour of Earth and rockfill dam under Symposium on Earthquake Effects on Structures, Plant and Machinery, November 13-15, 1996, New Delhi pp.IVl.l-IV1.10.
- [2] Bhattacharjee S.S. and Leger P. (1994): Application of NLFM models to predict cracking in concrete gravity dam. - Journal of Structural Engineering, ASCE, vol,120, No.4, pp.1255-1271.
- [3] Bhattacharjee S.S. and Leger P. (1995): Fracture response of gravity dam due to rise of reservoir elevation. - Journal of Structural Engineering, ASCE, vol,121, No.9, pp. 1298-1305.
- [4] Bowles J.E. (1996): Foundation Analysis and Design. - 4-th International Edition, McGraw-Hill, Inc.
- [5] Cervera M., Oliver J. and Prato T. (2000a): Simulation of construction of RCC dams 1: Temperature and aging. - Journal of Structural Engineering, ASCE, vol.l26, No.9, pp.1053-1061.
- [6] Cervera M., 01iver J. and Prato T. (2000b): Simulation of construction of RCC dams. U: Stress and damage. - Journal of Structural Engineering, ASCE, vol.l26, No.9, pp.1062-1069.
- [7] Chavez J.W. and Fenves G.L. (1995): Earthquake response of concrete gravity dam including base sliding. - Journal of Structural Engineering, ASCE, vol.l21, No.5, pp.865-875.
- [8] Chopra A.K. and Chakraborty P. (1972): The earthquake experiences at Koyna dam and stresses in concrete gravity dams. - Earthquake Engg. and Structural Dynamics, vol.l, pp. 151-164.
- [9] Chopra A.K. and Zhang L. (1991): Earthquake induced base sliding of concrete gravity dams. - Journal of Structural Engineering, ASCE, vol.ll7, No. 12, pp.3698-3719.
- [10] Cook R.D. (1995): Finite Element Modelling for Stress Analysis. - USA: John Wiley & Sons, Inc.
- [11] Dhariwal A. and Purohit D.G. (2000): Failure philosophy of embankment dams. - IGC 2000 The Millennium Conference, December 13-15, 2000, Mumbai, India, pp.371-374.
- [12] Garg S.K. (1996): Irrigation Engineering and Hydraulic Structure. - Delhi, India: Khanna Publishers.
- [13] Ghobarah A., El-Nady A. and Aziz T. (1994): Simplified dynamic analysis for gravity dams. - Journal of Structural Engineering, ASCE, vol.l20, No.9, pp.2697-2716.
- [14] Huang T.K. (1996): Stability analysis of an Earth dam under steady State seepage. - Journal of Computers and Structures, vol.58, No.6, pp. 1075-1082.
- [15] Indian National Committee on Large Dams (1979): Major Dams in India. - Publication No. 137, Central Board of Irrigation and Power, New Delhi, India.
- [16] Jain S.K. and Lettis W.R. (2001): Preliminary Observations on the Origin and Effect of the January 26, 2001 Bhuj (Gujarat, India) Earthąuake. - EERI Special Earthąuake Report supported by EERTs Learning from Earthąuake Project funded by National Science Foundation.
- [17] Zeghal M. and Abdel-Ghaffar A.M. (1992): Local-global finite element analysis of the seismic response of Earth dams. - Journal of Computers and Structures, vol.42, No.4, pp.569-580.
- [18] Zhao C., Xu T.P. and Valliappan S. (1995): Seismic response of concrete gravity dams including water-dam-sediment- foundation interaction. - Journal of Computers and Structures, vol.54, No.4, pp.705-716.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-article-BPZ2-0003-0022