Evaluating Method of Solitary Wave-Induced Tsunami Force Acting on an Onshore Bridge in Coastal Area

- Journal title : Journal of the Computational Structural Engineering Institute of Korea
- Volume 29, Issue 2, 2016, pp.149-159
- Publisher : The Computational Structural Engineering Institute
- DOI : 10.7734/COSEIK.2016.29.2.149

Title & Authors

Evaluating Method of Solitary Wave-Induced Tsunami Force Acting on an Onshore Bridge in Coastal Area

Kim, Do-Sam; Kyung, Kab-Soo; Lee, Yoon-Doo; Woo, Kyung Hwan;

Kim, Do-Sam; Kyung, Kab-Soo; Lee, Yoon-Doo; Woo, Kyung Hwan;

Abstract

In this study, the solitary wave-induced tsunami force acting on an onshore bridges in coastal area was numerically modelled by means of TWOPM-3D based on Navier-Stokes solver and VOF method which can track free surface effectively. The validity of numerical analysis was verified by comparing the experimental tsunami bore force acting on vertical wall and column structure. In particular, the characteristics of tsunami force with the changing tsunami intensity were surveyed through numerical experiments. The availability of 3-dimensional numerical analysis was reviewed through the comparison between the existing numerical results and design criteria for each drag force coefficient by applying Morison equation considering only drag force. As reasonable and high-precision estimation method of tsunami force, it was suggested to apply the estimation method taking drag and inertial force into consideration at the same time.

Keywords

onshore bridge;solitary waves;tsunami force;morison equation;drag force;inertia force;TWOPM-3D;

Language

Korean

Cited by

References

1.

Amsden, A.A., Harlow, F.H. (1970) The SMAC Method : A Numerical Technique for Calculating Incompressible Fluid Flow. Los Alamos Scientific Laboratory Report LA-4370, Los Alamos, N.M.

2.

Araki, S., Ishino, K., Degochi, I. (2010a) Characteristics of Tsunami Fluid Force Acting on Girder Bridge, Proceedings of 20th International Offshore and Polar Engineering Conference, ISOPE, pp.775-779.

3.

Araki, S., Sakahita, Y., Deguchi, I. (2010b) Characteristics of Horizontal and Vertical Tsunami Force Acting on Bridge Beam, 66(1), pp.796-800.

4.

Arikawa, T., Ikebe, M., Yamada, F., Shimosako, K., Imamura, F. (2005) Large Model Test of Tsunami Force on a Revetment and on a Land Structure, Proc. Coastal Eng., JSCE, 52, pp.746-750.

5.

Arnason, H. (2005) Interactions Between an Incident Bore and a Free-Standing Coastal Structure, Doctoral Dissertation, University of Washington.

6.

Bricker, J., Nakayama, A. (2014) Contribution of Trapped Air, Deck Superelevation and Nearby Structures to Bridge Deck Failure during a Tsunami, J. Hydraul. Eng., ASCE, 140(5), 05014002.

7.

FEMA-CCM (2005) Coastal construction manual. FEMA 55 Report, Edition 3, FEMA, USA.

8.

Fujii, N., Ohmori, M., Ikeya, T., Inagaki, S. (2006) Evaluation of Tsunami Wave Force Acting on Oil Storage Tanks and Predictive Method for Tsunami Damages, J. Coastal Eng.,JSCE, 53, pp.271-275.

9.

Fujima, K., Achmad, F., Shigihara, Y., Mizutani, N. (2009) Estimation of Tsunami force Acting on Rectangular Structures, J. Disaster Res., 4(6), pp.404-409.

10.

Hirt, C.W., Nichols, B.D. (1981) Volume of Fluid (VOF) Method for the Dynamics of Free Boundaries, J. Comput. Phys., 287, pp.299-316.

11.

Iemura, H., Pradono, M.H., Takahashi, Y. (2005) Report on the Tsunami Damage of Bridges in Banda Aceh and Some Possible Countermeasures, Proceedings of 28th Earthquake Engineering Symposium, JSCE.

12.

Korea Society of Civil Engineering, Korea Bridge Design & Engineering Research Center (2008) Bridge Design Criteia of (Korean edition), Kimoondang, Korea, p.1008.

13.

Lee, K.H., Ha, S.W., Lee, K.S., Kim, D.S. (2011) Numerical Analysis for Three-Dimensional Tsunami Force Acting on Multi-onshore Structures, J. Korean Soc. Civil Eng., KSCE, 31(2B), pp.175-185.

14.

Matsutomi, H. (1991) An Experimental Study on Pressure and Total Force due to Bore, Proc. of Coastal Eng., JSCE, 36, pp.626-630.

15.

Nakamura, T., Mizutani, N., Ren, X. (2013) Numerical Analysis of Tsunami-Induced Wave Force acting on a Bridge Deck and its Effects on the Motion of the Bridge Deck, J. Japan Soc. Civil Eng., A1, 69(4) (Journal of Japan Association for Earthquake Engineering, 32), I 20-I 30.

16.

Shigihara, Y., Fujima, K., Kosa, K. (2010) Reevaluation of Tsunami Force acted on the Bridges of the Neighborhood of Banda Aceh in the 2004 Indian Ocean Tsunami, 66(1),pp.231-235.

17.

Shoji, G., Hiraki, Y., Fujima, K., Shigihara, Y. (2010) Experimental study on fluid force acting on a bridge deck subjected to plunging breaker bores and surging breaker bores. (in Japanese)

18.

Shoji, G., Moriyama, T. (2007) Evaluation of the Structural Fragility of a Bridge Structure Subjected to a Tsunami Wave Load, J. Nat. Disaster Sci., 29(2), pp.73-81.

19.

Shoji, G., Moriyama, T., Fujima, K., Shigihara, Y., Kasahara, K. (2009) Experimental Study Associated with a Breaking Tsunami Wave Load acting onto a Single Span Bridge Deck, J. Struct. Eng., JSCE, 55A, pp.460-470.

20.

Smagorinsky, J. (1963) General Circulation Experiments with the Primitive Equations, Mon. Weath. Rev., 91(3), pp.99-164.

21.

Tanabe, S., Asai, M., Sonoda, Y. (2013) Numerical Evaluation of Fluid Force acted on Bridge Girders During Tsunami by using Particle Method. APCOM & ISCM.

22.

Xiao, H., Huang, W. (2008) Numerical Modeling of Wave Runup and Forces on an Idealized Beachfront House, Ocean Eng., 35, pp.106-116.

23.

Xu, G. (2015) Investigating Wave Forces on Coastal Bridge Deck, Ph.D thesis, Louisiana State University.

24.

Yeh, H. (2006) Maximum Fluid Forces in the Tsunami Runup Zone, J. Waterw. Port. Coastal & Ocean Eng, ASCE, 132(6), pp.496-500.

25.

Yeh, H. (2007) Design Tsunami Forces for Onshore Structures, J. Disaster Res., 2(6), pp.1-6.

26.

Yim, S.C., Azadbakht, M. (2013) Tsunami Forces on Selected California Coastal Bridges, Final Report Submitted to the California Department of Transportation (Caltrans) under Contract No. 65A0384.