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:: Volume 1, Issue 3 (12-2017) ::
ijcoe 2017, 1(3): 19-27 Back to browse issues page
Experimental Study on Wave Transmission and Reflection at Impermeable Submerged Breakwaters
Amin Mahmoudi , Habib Hakimzadeh, Mohammad Javad Ketabdari, Nick Cartwright, Mohammad Vaghefi
Civil Engineering Department, Persian Gulf University, Mahini Street, Bushehr
Abstract:   (1212 Views)
Submerged breakwaters are a special type of breakwater associated with low wave reflection. They can also save large quantities of engineering resources from the view of economics. Although there have been previous investigations on the interaction between waves and rubble mound low-crested breakwaters, performance of impermeable submerged breakwater is somehow different from rubble mound structures. Thus, the accurate estimation of reflection and transmission coefficients is essential in designing of this kind of structures in near shore zone. In this paper, performance of impermeable trapezoidal submerged breakwater was investigated experimentally using regular waves. In the experimental plan, for three submergence depths of breakwaters different wave groups were used to measure transmission and reflection coefficients. Based on the test results, empirical expressions were formulated to describe the transmission and reflection coefficients for solid submerged breakwater   under regular group waves.
Keywords: Wave transmission, Wave reflection, submerged breakwater, impermeable, regular group waves
Full-Text [PDF 521 kb]   (819 Downloads)    
Type of Study: Research | Subject: Coastal Engineering
Received: 2017/10/8 | Accepted: 2018/01/14 | Published: 2018/01/14
1. Jie, Ch., Changbo, J., Shixiong, H., and Wenwei, H. (2010), Numerical study on the characteristics of flow field and wave propagation near submerged breakwater on slope, Acta Oceanol Sin, Vol 29, No 1, pp 88-99. [DOI:10.1007/s13131-010-0011-5]
2. Carevic , D, Prsic , M, and Ocvirk, E. (2009), Modelling of Wave Interaction with Submerged Breakwater Using MIKE 21 BW, International Symposium on Water Management and Hydraulic Engineering ,Ohrid Macedonia.
3. Johnson, H.K., Karambas, T.V., Avgeris, I., Zanuttigh, B., Gonzalez-Marco, D., and Caceres, I. (2005), Modelling of waves and currents around submerged breakwaters, Coastal Engineering, Vol 52, pp 949- 969. [DOI:10.1016/j.coastaleng.2005.09.011]
4. Johnson, J. W., Fuchs, R. A. and Morison, J. R. (1951), The damping action of submerged breakwaters, Transactions, American Geophysical :union: , Vol. 32. No. 5, 704-717. [DOI:10.1029/TR032i005p00704]
5. Adams, C. B. and Sonu, C. J. (1986), Wave transmission across submerged near-surface breakwaters, Proc. 20th Int. Conf. on Coastal Engineering, ASCE. 1730-1738.
6. Van der Meer, J.W., Daemen, I.F.R. (1994), Stability and wave transmission at low crested rubble mound structures, Journal of Waterway, Port Coastal and Ocean Engineering 1, pp. 1 - 19. [DOI:10.1061/(ASCE)0733-950X(1994)120:1(1)]
7. Losada, I. J., Silva, R. and Losada, M.A. (1996a), 3-D non-breaking regular wave interaction with submerged breakwaters, Journal of Coastal Engineering , 28, 229-248. [DOI:10.1016/0378-3839(96)00019-1]
8. D'Angremond, K., Van der Meer, J.W. and De Jong, R.J. (1996), Wave transmission at low-crested structures, Proc. 25th Int. Conf. on Coastal Engineering, ASCE, 2418-2427.
9. Seabrook, S. R. and Hall, K. R. (1998), Wave transmission at submerged rubble mound breakwater, Proc. 26th Int. Conf. on Coastal Engineering, ASCE. 2000-2013. [DOI:10.1061/9780784404119.150]
10. Bleck, M. and Oumeraci, H. (2001), Wave Damping and Spectral Evolution at artificial Reefs, Proceedings 4th International Symposium on Ocean Wave Measurement and Analysis. San Francisco, California, USA.
11. Schlurmann, T. Bleck, M. and Oumeraci, H. (2002), Wave transformation at artificial reefs described by the Hilbert-Huang transformation (NHT), Proc. 28th Int. Conf. on Coastal Engineering , ASCE. 1791-1803.
12. Calabrese, M., Vicinanza, V., Buccino, M. (2002), Large scale experiments on the behaviour of low crested and submerged breakwaters in presence of broken waves, Proc. 28th Int. Conf. on Coastal Engineering, ASCE, pp. 1900 - 1912.
13. Hur, D.S., Kawashima, N., and Iwata, K. (2003), Experimental study of the breaking limit of multi directional random wave passing over an impermeable submerged breakwater, Ocean Engineering ,Vol 30, pp 1923-1940 [DOI:10.1016/S0029-8018(03)00046-5]
14. Hur, D.S. (2004), Deformation of multi-directional random wave passing over an impermeable sub-merged breakwater installed on a sloping bed, Ocean Engineering ,Vol 31, pp 1295-1311. [DOI:10.1016/j.oceaneng.2003.12.005]
15. Cho, Y.S., Lee, J.I. and Kim, Y.T. (2004), Experimental study of strong reflection of regular water wave over submerged breakwaters in tandem, Ocean Engineering, Vol 31, pp 1325-1335. [DOI:10.1016/j.oceaneng.2003.07.009]
16. Cox, R.J., and Tajziehchi, M. (2005), 2D experimental modeling of hydrodynamic effects of submerged breakwaters, Fifth International Conference on Coastal Dynamics , Barcelona, Spain.
17. Van der Meer, J.W., Briganti, R., Zanuttigh, B., Wang, B. (2005), Wave transmission and reflection at low crested structures: design formulae, oblique wave attack and spectral change, Coastal Eng. 52 (10-11), pp.915- 929 [DOI:10.1016/j.coastaleng.2005.09.005]
18. Jie, Ch., Changbo, J., and Yonggang, C. (2008), Experimental study of transmission coefficient of wave s over submerged breakwater on a sloping bed, Science paper Online , Vol 7, pp 516-523.
19. Zanuttigh, B., Van der Meer, J.W. (2006), Wave reflection from coastal structures, Proc. XXX Int. Conf. Coast. Eng. vol. 5, 4337-434 9.
20. Steendam, G.J., Van der Meer, J.W., Verhaeghe, H., Besley, P., Franco, L., Vangent, M., (2004), The international database on wave overtopping , Proc. XXIX Int. Conf. Coast. Eng. pp. 4301-4313.
21. Bruce, T., Van der Meer, J.W., Franco, L., Pearson, J. (2006), A comparison of overtopping performance of different rubble mound breakwater armour, Proc. XXX Int Conf. Coastal Eng vol. 5, 4567 - 4579.
22. Davidson, M.A ., Bird, P.A .D., Bullock, G.N., Huntley, D.A . (1996), A new non dimensional number for the analysis of wave reflection from rubble mound breakwaters, Coastal Eng. 28, 93- 120. [DOI:10.1016/0378-3839(96)00012-9]
23. Cappietti, L., Clementi, E., Aminti, P., Lamberti, A . (2006), Piling-up and filtration at low crested breakwaters of different permeability, Proc. XXX Int Con f. Coastal Eng vol. 5, 4957- 4969.
24. Seelig, W.N., Ahrens, J.P., (1981), Estimation of wave reflection and energy dissipation coefficients for beaches, revetments and breakwaters, CERC Technical paper 81-1, Fort Belvoir, U.S.A .C.E. MS, Vicksburg. [DOI:10.5962/bhl.title.47482]
25. Postma, G.M. (1989), Wave reflection from rock slopes under random wave attacks, PhD thesis, Delft University of Technology.
26. Allsop, N.W.H. and Hettiarachchi, S.S.L. (1989), Wave reflections in harbours; the design, construction and performance of wave absorbing structures, Report OD 89. Hydraulics Research, Wallingford.
27. Zanuttigh, B., Van der Meer, J.W. (2008), Wave reflection from coastal structures in design conditions, Coastal Engineering, 55, 771 -779. [DOI:10.1016/j.coastaleng.2008.02.009]
28. Goda, Y., Suzuki, Y. (1976), Estimation of incident and reflected waves in random wave experiments, In: Proceedings of the 15th International Conference on Coastal Engineering, Hawaii, USA, pp.828-845.
29. De Jong, R.J. (1996), Wave transmission at low-crested structures. Stability of tetra pods at front, crest and rear of a low-crested breakwater, M.Sc.-thesis, Delft University of Technology.
30. Wang, B., Van der Meer, J.W., Otta, A. K., Chadwick, A. J. and J. HorrilloCaraballo, (2005), Reflection of obliquely incident waves at low-crested structures, Proc. Coastal Dynamics'05.
31. Van der Meer, J.W., Regeling, H.J., de Waal, J.P., (2000), Wave transmission: spectral changes and its effects on run up and overtopping, Proc 27th Int. Conf on Coastal Engineering, pp. 2156 - 2168.
32. Shen, Y.M., Ng, C.O., and Zheng, Y.H., (2004), Simulation of Wave Propagation Over a Submerged Bar Using the VOF Method With a Two-Equation k-. Turbulence Modeling, Ocean Eng, Vol 31, pp 87-95. [DOI:10.1016/S0029-8018(03)00111-2]
33. Johnson, H.K., Karambas, T.V., Avgeris, I., Zanuttigh, B., Gonzalez- Marco, D., and Caceres, I., (2005), Modelling of Waves and Currents Around Submerged Breakwaters, Coastal Eng, Vol 52, pp 949-969. [DOI:10.1016/j.coastaleng.2005.09.011]
34. Christou, M., Swan, C., and Gudmestad, O.T., (2008), The Interaction of Surface Water Waves With Submerged Breakwaters, Coastal Eng, Vol 55, pp 945-958. [DOI:10.1016/j.coastaleng.2008.02.014]
35. Careviæ, D., Pršiæ, M., and Ocvirk, E., (2009), Modelling of Wave Interaction with Submerged Breakwater Using MIKE 21 BW, Int Symp Water Manage Hydraul Eng, Ohrid, Macedonia, pp 169-180.
36. Cao, Y., Jiang, C., and Bai, Y., (2010), Numerical Study on Flow Structure Near Two Impermeable Trapezoid Submerged Breakwaters on Slop Bottoms, J. Hydrodyn, Vol 22, No 5, pp 190-196. [DOI:10.1016/S1001-6058(09)60192-X]
37. Mahmoudi, A., Hakimzadeh, H., Ketabdari, M.J., (2013), Simulation of Wave Propagation over a Submerged Breakwater on a Sloped Bed by SPH Method, The International Society of Offshore and Polar Engineers, Vol. 23, No. 4, pp. 286-291.
38. Hajivalie, F., Yeganeh-Bakhtiary, A., Bricker, J.D., (2015), Numerical Study of the Effect of Submerged Vertical Breakwater Dimension on Wave Hydrodynamics and Vortex Generation, Coastal Engineering Journal, Vol. 57, No. 3. [DOI:10.1142/S0578563415500096]
39. Yeganeh-Bakhtiary, A., Houshangi, H., Hajivalie, F., Abolfathi, S., (2017), A Numerical Study on Hydrodynamics of Standing Waves in Front of Caisson Breakwaters with WCSPH Model, Coastal Engineering Journal, Vol. 59, No. 1 [DOI:10.1142/S057856341750005X]
40. Battjes, J.A., (1974), Computation of set-up, long shore currents, run-up, and overtopping due to wind-generated waves, Comm. on Hydraulics, Department of Civil Engineering, Delft University of Technology, Report 74-2.
41. Seelig, W.N., Ahrens, J.P., (1981), Estimation of Wave Reflection and Energy Dissipation Coefficients for Beaches, Revetments, and Breakwaters. CERC Technical Report No. 81-1. Fort Belvoir, Virginia, USA. [DOI:10.5962/bhl.title.47482]
42. Zanuttigh, B., van der Meer, J.W., (2008), Wave reflection from coastal structures in design conditions. Coastal Engineering, (55), pp. 771-779. [DOI:10.1016/j.coastaleng.2008.02.009]
43. Young, D.M., Testik, F.Y., (2011), Wave reflection by submerged vertical and semicircular Breakwaters, Ocean Engineering, 38, 1269-1276.
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Mahmoudi A, Hakimzadeh H, Ketabdari M J, Cartwright N, Vaghefi M. Experimental Study on Wave Transmission and Reflection at Impermeable Submerged Breakwaters. ijcoe. 2017; 1 (3) :19-27
URL: http://ijcoe.org/article-1-57-en.html

Volume 1, Issue 3 (12-2017) Back to browse issues page
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