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http://dx.doi.org/10.1016/j.ijnaoe.2019.12.001

Hydrodynamic performance of a vertical slotted breakwater  

George, Arun (Department of Ocean System Engineering, Jeju National University)
Cho, Il Hyoung (Department of Ocean System Engineering, Jeju National University)
Publication Information
International Journal of Naval Architecture and Ocean Engineering / v.12, no.1, 2020 , pp. 468-478 More about this Journal
Abstract
The wave interaction problem with a vertical slotted breakwater, consisting of impermeable upper, lower parts and a permeable middle part, has been studied theoretically. An analytical model was presented for the estimation of reflection and transmission of monochromatic waves by a slotted breakwater. The far-field solution of the wave scattering involving nonlinear porous boundary condition was obtained using eigenfunction expansion method. The empirical formula for drag coefficient in the near-field, representing energy dissipation across the slotted barrier, was determined by curve fitting of the numerical solutions of 2-D channel flow using CFD code StarCCM+. The theoretical model was validated with laboratory experiments for various configurations of a slotted barrier. It showed that the developed analytical model can correctly predict the energy dissipation caused by turbulent eddies due to sudden contraction and expansion of a slotted barrier. The present paper provides a synergetic approach of the analytical and numerical modelling with minimum CPU time, for better estimation of the hydrodynamic performance of slotted breakwater.
Keywords
Slotted breakwater; Energy dissipation; Nonlinear porous boundary condition; Eigenfunction expansion method; K-epsilon turbulent model;
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  • Reference
1 Mei, C.C., 1989. The applied dynamics of ocean surface waves. In: World Scientific, Singapore. World Scientific, Singapore.
2 Mei, C.C., Liu, P.L.F., Ippen, A.T., 1974. Quadratic loss and scattering of long waves. J. Waterw. Harb. Div. 100 (3), 217-239.
3 Molin, B., Remy, F., 2013. Experimental and numerical study of the sloshing motion in a rectangular tank with a perforated screen. J. Fluids Struct. 43, 463-480.   DOI
4 Sollit, C.K., Cross, R.H., 1972. Wave transmission through permeable breakwaters. In: Proc. 13th Coastal Engineering Conference. ASCE, pp. 1827-1846.
5 Somervell, L.T., Thampi, S.G., Shashikala, A.P., 2017. Hydrodynamic characteristics of vertical cellular breakwater. J. Waterw. Port, Coast. Ocean Eng. 143 (5).
6 Suh, K.D., Park, W.S., 1995. Wave reflection from perforated-wall caisson breakwaters. Coast. Eng. 26 (3-4), 177-196.   DOI
7 Suh, K.D., Shin, S., Cox, D.T., 2006. Hydrodynamic characteristics of pile-supported vertical wall breakwaters. J. Waterw. Port, Coast. Ocean Eng. 132 (2), 83-96.   DOI
8 Suh, K.D., Kim, Y.W., Ji, C.H., 2011. An empirical formula for friction coefficient of a perforated wall with vertical slits. Coast. Eng. 58 (1), 85-93.   DOI
9 Yoon, S.B., Lee, J.I., Nam, D.H., Kim, S.H., 2006. Energy loss coefficient of waves considering thickness of perforated wall. J. Korean Society of Coastal and Ocean Engineers 18 (4), 321-328 (in Korean).
10 Ahmed, H.G., 2011. Wave Interaction with Vertical Slotted Walls as a Permeable Breakwater. PhD. Thesis, Hydro Sciences (IGAW). Bergische University of Wuppertal, Germany.
11 Cho, I.H., Kim, M.H., 2008. Wave absorbing system using inclined perforated plates. J. Fluid Mech. 608, 1-20.   DOI
12 Cho, I.H., Koh, H.J., 2007. Reflection and transmission coefficients by a circular pile breakwater. Journal of Korean Society of Coastal and Ocean Engineers 19 (1), 38-44 (in Korean).
13 Crowley, S., Porter, R., 2012. The effect of slatted screens on waves. J. Eng. Math. 76, 53-76.
14 Huang, Z., 2007. Reflection and transmission of regular waves at a surface-pitching slotted barrier. Appl. Math. Mech. 28 (9), 1153-1162.   DOI
15 Flagg, C.N., Newman, J.N., 1971. Sway added-mass coefficients for rectangular profiles in shallow water. J. Ship Res. 15, 257-265.   DOI
16 Grüne, J., Kohlhase, S., 1974. Wave transmission through vertical slotted walls. In: Proc., 14th Coastal Engineering Conference, ASCE, vol. 3, pp. 1906-1923.
17 Hayashi, T., Hattori, M., Kano, T., Shirai, M., 1966. Hydraulic research on the closely spaced pile breakwater. Coastal Engineering in Japan 9 (1), 107-117.   DOI
18 Isaacson, M., Premasiri, S., Yang, G., 1998. Wave interactions with vertical slotted barrier. J. Waterw. Port, Coast. Ocean Eng. 124 (3), 118-126.   DOI
19 Kakuno, S., Liu, P.L.F., 1993. Scattering of water waves by vertical cylinders. J. Waterw. Port, Coast. Ocean Eng. 119 (3), 302-322.   DOI
20 Kriebel, D.L., 1993. Vertical wave barriers: wave transmission and wave forces. In: Coastal Engineering, pp. 1313-1326.