Authors: Sadia Rahman, Shatirah Akib, M. T. R. Khan, R. Triatmadja

Abstract:

Tsunami disaster poses a great threat to coastal infrastructures. Bridges without adequate provisions for earthquake and tsunami loading is generally vulnerable to tsunami attack. During the last two disastrous tsunami event (i.e. Indian Ocean and Japan Tsunami) a number of bridges were observed subsequent damages by tsunami waves. In this study, laboratory experiments were conducted to study the effects of perforations in bridge girder in force reduction. Results showed that significant amount of forces were reduced using perforations in girder. Approximately 10% to 18% force reductions were achieved by using about 16% perforations in bridge girder. Subsequent amount of force reductions revealed that perforations in girder are effective in reducing tsunami forces as perforations in girder let water to be passed through. Thus, less bridge damages are expected with the presence of perforations in girder during tsunami period.

Keywords: Bridge, force, girder, perforation, tsunami, wave.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1090687

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References:

[1] A. Ghobarah, M. Saatcioglu, and I. Nistor, "The impact of 26 December 2004 earthquake and tsunami on structures and infrastructure,” Engineering Structures, Elsevier, 2006, Vol. 28, pp. 312-326.
[2] I. Nistor, M. Saatcioglu and A. Ghobarah, "The 26 December 2004 Earthquake and Tsunami- Hydrodynamic forces on physical infrastructure in Thailand and Indonesia,” Proceedings 2005 Canadian Coastal Engineering Conference., Halifax, Canada, CD-ROM, 2005, pp 15.
[3] M. Saatcioglu, A. Ghobarah, I. Nistor, "Performance of structures in Indonesia during the 2004 Sumatra earthquake and tsunami,” Earthquake Spectra, Earthquake Engineering Research Institute, 2006 ASCE, Vol. 22(S3), pp. 295-320.
[4] T. Tomita, F. Imamura, T. Arikawa, T. Yasuda, and Y. Kawata, "Damage caused by the 2004 Indian Ocean Tsunami on the south-western coast of Sri Lanka,” Coastal Engineering Journal, JSCE, 2006, Vol. 48(2), pp. 99-116.
[5] Yamamoto, H. Takanashi, S. Hettiarachchi, and S. Samarawickrama, "Verification of the destruction mechanism of structures in Sri Lanka and Thailand due to the Indian Ocean tsunami,” Coastal Engineering Journal, JSCE, 2006, Vol. 48(2), pp.117-146.
[6] Akib. S, Mashodi. N, and Rahman. S, (2013), Semi-Integral Bridge Scour Countermeasure Using Gabion and Crushed Concrete Mixed with Palm Shell: A Review, Journal of Science and Technology 51 (2B) (2013) 59-68.
[7] Akib, S., Mohammadhassani, M., Jahangirzadeh, A., (2013), Application of ANFIS and LR in Prediction of Scour Depth in Bridges, Computers & Fluids, doi: http://dx.doi.org/10.1016/j.compfluid.2013. 12.004.
[8] Akib. S, Shirazi. SM, Sholichin. M, Othman. F, Fayyadh. MM, Primasari. B, (2011), Influence of Flow Shallowness on Scour Depth at Semi-Integral Bridge Piers, Advanced Materials Research 243, 4478-4481.
[9] Akib. S, Othman. F, Othman. I, Amini. A, Marzuki. MS, (2009), Local Scour at Integral Bridges with Single and Double Row Piles in a Two-Stage Channel. H2009: 32nd Hydrology and Water Resources Symposium.
[10] Akib, S., Fayyadh, M. M., Othman, I., (2011), Structural Behaviour of A Skewed Integral Bridge Affected by Different Parameters, J. Road Bridge Eng., 6(2), 107 114.
[11] Fayyadh. M, Akib. S, Othman. I, Razak.HA, (2011), Experimental investigation and finite element modelling of the effects of flow velocities on a skewed integral bridge. Simulation Modelling Practice and Theory 19 (9), 1795-1810.
[12] S.C. Yim, "Modeling and Simulation of Tsunami and Storm Surge Hydrodynamics Loads on Coastal Bridge Structures, "Proceedings of the 21st US-Japan Bridge Engineering Workshop, Tsukuba, Japan, October 3-5, 2005 (2005).
[13] S. Unjoh, "Bridge Damage Caused by Tsunami,” Bulletin of Japan Association for Earthquake Engineering, 2007, Vol. 6, pp. 26-28 (in Japanese).
[14] S. Unjoh, "Damage to transportation facilities. The damage induced by Sumatra earthquake and associated tsunami of December 26, 2004, A report of the reconnaissance team of Japan Society of Civil Engineers, 2005, pp 66-76.
[15] A. Sheth, S. Sanyal, A. Jaiswal and P. Gandhi, "Effects of the December 2004 Indian Ocean Tsunami on the Indian Mainland,” Earthquake Spectra, 2006, Vol. 22(S3), pp. 435-473.
[16] D. Ballantyne, "Sri Lanka Lifelines after the December 2004 Great Sumatra Earthquake and Tsunami,” Earthquake Spectra, 2006, Vol. 22(S3), pp. 545-559.
[17] B. K. Maheshwari, M.L. Sharma and J.P. Narayan, "Geotechnical and structural damage in Tamil Nadu, India, from the December 2004 Indian Ocean Tsunami,” Earthquake Spectra, 2006, Vol. 22(S3), pp. 475-493.
[18] C. Scawthorn, T. Ono, H. Iemura, M. Ridha and B. Purwanto, "Performance of lifelines in Banda Aceh, Indonesia, during the December 2004 Great Sumatra Earthquake and Tsunami,” Earthquake Spectra, 2006, Vol. 22(S3), pp. 511-544.
[19] P. Lukkunaprasit and A. Ruangrassamee, "Buildings damage in Thailand in 2004 Indian Ocean tsunami and clues for tsunami-resistant design,” The Institution of Engineers Singapore Journal, Part A: Civil and Structural Engineering, 2008, Vol. 1(1), pp. 17-30.
[20] S. Kataoka, T. Kusakabe and K. Nagaya, "Wave force acts on a bridge girder struck by tsunami. Proceedings of the 12th Japan Earthquake Engineering Symposium, 2006, pp. 154-157.
[21] Japan Port and Harbour Association, "Technical standards and commentaries of port and harbour facilities, 1999.
[22] G. Shoji and Y. Mori, "Hydraulic model experiment to simulate the damage of a bridge deck subjected to tsunamis,” Annual Journal of Coastal Engineering, 2006, Vol. 53, no.2, pp. 801-805 (in Japanese).
[23] H. Iemura, M.H. Pradono and T.Tada, "Experiments of tsunami force acting on bridge models,” Journal of Earthquake Engineering, Japan Society of Civil Engineers, 2007, Vol. 29, pp. 902-911.
[24] P. Lukkunaprasit and T. L. Lau, "Influence of Bridge Deck on Tsunami Loading on Inland Bridge Piers,” The IES Journal Part A: Civil & Structural Engineering, 2011, Vol. 4(2), pp. 115-121.
[25] H Matsutomi, "The pressure Distribution and the Total wave force,” Coastal Engineering in Japan, 1991, Vol. 38, pp.626-630.
[26] S. Mizutani and F. Imamura, "Hydraulic experimental study on wave force of a bore acting on a structure,” Proceedings of Coastal Engineering, JSCE, 2000, Vol. 47, pp. 946-950 (in Japanese).
[27] R. Asakura, R., K. Iwase, T. Ikeya, M. Takao, T. Kaneko, N. Fujii and M. Omori, "An experimental study on wave force acting on on-shore structures due to overflowing tsunamis,” Proceedings of Coastal Engineering, JSCE, 2000, Vol. 47, pp. 911-915 (in Japanese).
[28] R. Triatmadja and A. Nurhasanah, "Tsunami force on buildings with openings and protection,” Journal of Earthquake and Tsunami, 2012, Vol. 6(4).
[29] H. Arnason, C. Petroff, and H. Yeh, "Tsunami bore impingement onto a vertical column,” J. Disaster Res, 2009, Vol. 4(6).