Authors: Shatirah Akib, Sadia Rahman

Abstract:

Scouring around a bridge pier is a complex phenomenon. More laboratory experiments are required to understand the scour mechanism. This paper focused on time development of local scour around piers and piles in semi integral bridges. Laboratory data collected at Hydraulics Laboratory, University of Malaya was analyzed for this purpose. Tests were performed with two different uniform sediment sizes and five ranges of flow velocities. Fine and coarse sediments were tested in the flume. Results showed that scour depths for both pier and piles increased with time up to certain levels and after that they became almost constant. It had been found that scour depths increased when discharges increased. Coarser sediment also produced lesser scouring at the piers and combined piles.

Keywords: Pier, pile, scour, semi integral bridge, time.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1087488

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References:

[1] H.H. Chang, “Fluvial processes in river engineering” John Wiley & Sons, pp. 432 , (1988)
[2] A. J. Raudkivi, R. Ettema, “Clear Water Scour at Cylindrical Piers, Journal of Hydraulics Engineering,” ASCE, 109(3), pp 338-350 (1983)
[3] P. F. Lagasse, P. L. Thompson, and S. A. Sabol, “Guarding against scour”. Civil Engineering, June, 1995
[4] P. A. Johnson and D. A. Dock, “Probabilistic bridge scour estimates. Journal of Hydraulic Engineering,” Vol. 124, No. 7, pp. 750–754, (1996)
[5] B. W. Melville and S. E. Coleman, “Bridge, Water Resources” Publications LLC, Littleton, Colorado, (2000)
[6] P.E. Clopper, , P.F. Lagasse and, L.W. Zevenbergen, “Bridge Pier Scour Countermeasures,” Proceedings of the 2007 World Environmental and Water Resources Congress, May 15-19, 2007, Tampa, Florida
[7] A. Masjedi, M.S. Bejestan and A. Esfandi, “Reduction of Local Scour at a Bridge Pier using Collar in a 180 Degree Flume Bend,”Journal of Applied Sciences, 10: 124-13, (2010).
[8] E.M. Laursen, A. Toch, “Scour Around Bridge Piers and Abutments,” Bulletin No. 4, Iowa Highways Research Board, Ames, Iowa, U.S.A, (1956)
[9] E.M. Laursen, ”Analysis of Relief Bridge Scour,” Journal of the Hydraulics Division, ASCE, 89(3) 93-118, (1963)
[10] H.W. Shen, V.R. Schneider, S.S. Karaki, Local Scour around Bridge Piers, Journal of the Hydraulics Division, ASCE, 95(6), 1919-1940., (1969)
[11] H.N.C. Breusers, G. Nicollet, H.W. Shen, Local Scour around Cylindrical Piers. Journal of Hydraulic Research, IAHR, 15(3), 211-252 (1977)
[12] A.J. Raudkivi, Functional Trends of Scour at Bridge Piers, Journal of Hydraulics Engineering, ASCE, 112(1), 1-13 (1986)
[13] H.N.C. Breusers, A.J. Raudkivi, Scouring Hydraulic Structures Design Manual, No. 2, IAHR, Balkema, Rotterdam, 109-116, (1991)
[14] G. W. Parker, L. Bratton, and, D. S. Armstrong , “Stream stability and scour assessments at bridges in Massachusetts.” U.S. Geological Survey Open File Report No. 97-588 (CD-ROM), Massachusetts Highway Dept. Bridge Section, Marlborough, Mass., 53 (1997).
[15] A.T. Moncada - M, J. A.-P. “Scour Protection Of Circular Bridge Piers with Collars and Slots.”Journal of Hydraulic Research , 119-126 (2009).
[16] E. V. Richardson, and, S. R. Davis “Evaluating scour at bridges 3rd ed.” Federal Highway Administration Hydraulic Engineering Circular No. 18: FHWA-IP-90–017, U.S. Department of Transportation, Washington, D.C., 203. (2001).
[17] P.F. Lagasse and, E.V. “ASCE compendium of stream stability and bridge scour papers.” Journal of Hydraulic Engineering, ASCE, 127(7): 531-533. Richardson (2001).
[18] J Chabert. and, P. Engeldinger, “Etude des affouillements autour des piles de points (Study of scour at bridge piers).” Bureau Central d’Etudes les Equipment d’Outre-Mer, Laboratoire National d’Hydraulique, France, (1956)
[19] Chiew Yee-Meng, Ng See King and Lim Siow-Yong, “Hydraulic Problem in Malaysia,” Presentation in an International Symposium organized by the International Society of Soil Mechanics and Geotechnical Engineering Technical Committee TC- 33 on Scour of Foundations, Melbourne, Australia, 19 November 2000.
[20] D. A. M. Kueh, “Effects Of Scour On Semi-Integral Bridge In Main Channel” Bachelor Thesis, University of Malaya (2006)
[21] C.S. Lauchlan, S.E. Coleman, B.W. Melville, Temporal Scour Development at Bridge Abutments, 29th Congress of the international Association for Hydraulic Research, Beijing Proceedings (2002)
[22] Y.M. Chiew and, B.W. Melville, “ Temporal development of local scour depth at bridge piers” North American Water and Environment Congress, A.S.C.E., Anaheim, California, U.S.A., June, 1996.
[23] B.W. Melville and, Y.M. Chiew, “ Time scale for local scour at bridge piers,” Journal of Hydraulic Engineering, A.S.C.E., Vol.125(1), pp.59- 65, 1999.
[24] S. Akib, , M. M. Fayyadh and I Othman, “Structural Behavior of a Skewed Integral Bridge Affected by Different Parameters,” The Baltic Journal of Road and Bridge Engineering, 6 (2), 107-114. (2011) DOI: 10.3846/bjrbe.2011.15,
[25] M.M. Fayyadh, S. Akib, I. Othman, H.A. Razak, “Experimental investigation and finite element modeling of the effects of flow velocities on a skewed integral bridge,” Simulation Modeling Practice and Theory, 19, 1975-1810. (2011)
[26] M. Mia, and H. Nago”, Design Method of Time-Dependent Local Scour at Circular Bridge Pier.” J. Hydraul. Eng., 129(6), 420–427., (2003).
[27] U.C. Kothyari, R.J. Garde, K.G.R. Raju, “Temporal variation of scour around circular bridge piers.” J. Hyd. Eng., ASCE, 118(8), 1091-1106, (1992).