참고문헌
- AASHTO (American Association of State Highway and Transportation Officials) (2011) Case Studies on the Rehabilitation of Historic Bridges.
- Arya, A.S., Thakkar, S.K. and Bakir S.M. (1992), "Retrofitting of an earthquake damaged bridge", Tenth World Conference in Earthquake Engineering, Madrid, July.
- Caglayan, O., Ozakgul, K. and Tezer, O. (2012), "Assessment of existing steel railway bridges", J. Constr. Steel Res., 69(1), 54-63. https://doi.org/10.1016/j.jcsr.2011.08.001
- Edward Zhou, Y., Beecher, J.B., Guzda, M.R. and Cunningham, D.R. (2014), "Investigation and retrofit of distortion-induced fatigue cracks in a double-deck cantilever-suspended steel truss bridge", J. Struct. Eng., 141(1), D4014011.
- Ganesan, T.P. (2005), Model Analysis of Structures, 2nd Edition, Universities Press.
- Goel, R.K. and Sanyal, A.K. (1999), "Rehabilitation of distressed road over bridge at FirozpurCantt-a case study", IIBE Seminar, Vigyan Bhawan, New Delhi.
- Hatfield, F.J. (2001), Engineering for Rehabilitation of Historic Metal Truss Bridges, Welding Innovation, XVIII(3).
- Hibbeler, R.C. (2008), Structural Analysis, 6th Edition, Prentice Hall.
- IS 800 (2007), Indian Standard Code of Practice for General Construction in Steel, Bureau of Indian Standards, New Delhi.
- Jagadish, R. (1995), Structural Failures - Case Histories, Oxford & IBH Publishing Co., New Delhi.
- Lima1, K., Robson, N., Oosterhof, S., Kanji, S., DiBattista, J. and Montgomery, C.J. (2008), "Rehabilitation of a 100-Year-Old Steel Truss Bridge", CSCE Annual Conference, Quebec, June.
- McKeel, W.T. Jr., Miller, A.B., Clark, K.S., Saufley, R.W. Jr., Bushman, W.H. and Lester, T.F. (2006), "Best Practices for the Rehabilitation and Moving of Historic Metal Truss Bridges", Virginia Transportation Research Council, Final Report VTRC 06-R31.
- Mehta, S. (2010), "Evaluation and retrofit issues for steel truss bridges in Eastern United States", Bridge Eng., ASCE, 15(5), 581-96. https://doi.org/10.1061/(ASCE)BE.1943-5592.0000086
- Peterson, F.J. (2011), "The rehabilitation alternative Huey P. Long Bridge- case study", Bridge Engineering Program, University of Buffalo.
- Subramanian, N. (2014), "The failures that changed the perception of our designs", Bridge Struct. Eng., J. ING/IABSE, 44(4), 29-51.
- Thakkar, S.K. (2008), "Retrofitting techniques for bridges and flyovers", New Build. Mater. Constr. World, 13(9), 180-192.
- Kumar, R., Ghanekar, V.K., Sahu, G.K., Pandey, A.K., Rao, M.V.B., Sharma, S.K. and Rao, V.V.L.K. (1999), "Structural integrity and rehabilitation of Khalghat Bridge", Bridge Struct. Eng., J. ING/IABSE, 29(1), March.
- SP 6(1)-1964, Handbook for Structural Engineers, Bureau of Indian Standards, New Delhi.
- Schodek, D.L. (2000), Structures, 4th Edition, Prentice Hall.
- Stamatopoulos, G.N. (2013), "Fatigue assessment and strengthening measures to upgrade a steel railway bridge", J. Constr. Steel Res., 80, 346-354. https://doi.org/10.1016/j.jcsr.2012.10.004
- Subramanian, N. (2008), Design of Steel Structures, Oxford University Press, New Delhi.
- Subramanian, N. (2014), "Codification and methods to improve the process", Bridge Struct. Eng., J. ING/IABSE, 44(2), 1-12.
- Williams, W. (2013), "Retrofit bridge rail design and testing for a historic Texas Steel Truss Bridge", Tran. Res. Record: J. Tran. Res. Board, 2377, 29-37. https://doi.org/10.3141/2377-04
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