Top

Meccanica

Published in:

09-04-2021

Analytical study for oblique wave interaction with a submerged horizontal perforated plate near a partially reflecting vertical wall

Authors: Y. Zhao, K. G. Vijay, S. Neelamani, Y. Liu

Published in: Meccanica | Issue 7/2021

Activate our intelligent search to find suitable subject content or patents.

search-config

AI-assisted search

Off

Abstract

A novel iterative analytical solution is developed to study the oblique wave interaction with a horizontally submerged perforated plate near a partially reflecting vertical wall. The boundary condition on the perforated plate is considered as a quadratic pressure drop to incorporate the effect of wave height on the wave energy dissipation. The boundary value problem is analyzed analytically under the assumptions of small amplitude wave theory. To validate the analytical model, an iterative solution based on MBEM (multi-domain boundary element method) is independently developed, and the comparison between the analytical solution and the experimental data are given. The performance characteristics of a submerged perforated plate before a partially reflecting vertical wall is studied by analyzing the hydrodynamic coefficients of the system for the effects of plate porosity, relative plate width, spacing, depth of submergence, and the direction of wave attack. The proposed model is expected to act as an effective breakwater in the attenuation of wave energy for the creation of a tranquillity zone in the marine environment. Moreover, the analytical model developed in the present study can be effective and reliable for practical preliminary design.

previous article Analogue tuning of particle focusing in elasto-inertial flow

next article Water wave propagation over multiple porous barriers with variable porosity in the presence of an ice cover

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

inform now

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

inform now

Franco L (1994) Vertical breakwaters: the Italian experience. Coast Eng 22(1–2):31–55CrossRef

Oumeraci H (1994) Review and analysis of vertical breakwater failures—lessons learned. Coast Eng 22(1–2):3–29CrossRef

Cuomo G, Allsop W, Bruce T, Pearson J (2010) Breaking wave loads at vertical seawalls and breakwaters. Coast Eng 57(4):424–439CrossRef

Christie, S., Dong, J. S., and Charles, L. (2001). Ocean Waves Propagating over a Submerged Breakwater in Front of a Vertical Wall. Coasts & Ports 2001, In: Proceedings of the 15th Australasian Coastal and Ocean Engineering Conference, the 8th Australasian Port and Harbour Conference. Barton, A.C.T.: Institution of Engineers, Australia: pp 539–544

Jeng DS, Schacht C, Lemckert C (2005) Experimental study on ocean waves propagating over a submerged breakwater in front of a vertical seawall. Ocean Eng 32(17–18):2231–2240CrossRef

Munireddy MG, Neelamani S (2004) Wave pressure reduction on vertical seawalls/Caisson due to an offshore breakwater. Indian J Mar Sci 33(4):329–337

Muni-Reddy MG, Neelamani S (2006) Wave interaction with caisson defenced by an offshore low-crested breakwater. J Coast Res 3:1767–1770

Koraim AS, Heikal EM, Zaid AA (2014) Hydrodynamic characteristics of porous seawall protected by submerged breakwater. Appl Ocean Res 46:1–14CrossRef

Koley S, Sahoo T (2017) Oblique wave trapping by vertical permeable membrane barriers located near a wall. J Mar Sci Appl 16(4):490–501CrossRef

10.

Zhao Y, Li HJ, Liu Y (2017) Oblique wave scattering by a submerged porous breakwater with a partially reflecting sidewall. J Mar Sci Technol 25(4):383–392

11.

Yu X, Chwang AT (1994) Water waves above submerged porous plate. J Eng Mech 120(6):1270–1282

12.

Yu X (2002) Functional performance of a submerged and essentially horizontal plate for offshore wave control: a review. Coast Eng J 44(02):127–147CrossRef

13.

Neves MDG, Losada IJ, Losada MA (2000) Short-wave and wave group scattering by submerged porous plate. J Eng Mech 126(10):1048–1056

14.

Neelamani S, Reddy MS (1992) Wave transmission and reflection characteristics of a rigid surface and submerged horizontal plate. Ocean Eng 19(4):327–341CrossRef

15.

Liu Y, Li HJ, Li YC (2012) A new analytical solution for wave scattering by a submerged horizontal porous plate with finite thickness. Ocean Eng 42:83–92CrossRef

16.

Neelamani S, Gayathri T (2006) Wave interaction with twin plate wave barrier. Ocean Eng 33(3–4):495–516CrossRef

17.

Liu Y, Li YC (2011) An alternative analytical solution for water-wave motion over a submerged horizontal porous plate. J Eng Math 69(4):385–400MathSciNetMATHCrossRef

18.

Cho IH, Koh HJ, Kim JR, Kim MH (2013) Wave scattering by dual submerged horizontal porous plates. Ocean Eng 73:149–158CrossRef

19.

Cho IH, Kim MH (2008) Wave absorbing system using inclined perforated plates. J Fluid Mech 608:1–20MathSciNetMATHCrossRef

20.

Molin B (1999) Numerical and physical wavetanks-making them fit. The twenty-second Georg Weinblum memorial lecture, Michigan

21.

Chwang AT (1983) A porous-wavemaker theory. J Fluid Mech 132:395–406MATHCrossRef

22.

Yu X (1995) Diffraction of water waves by porous breakwaters. J Waterw Port Coast Ocean Eng 121(6):275–282CrossRef

23.

Chwang AT, Wu J (1994) Wave scattering by submerged porous disk. J Eng Mech 120(12):2575–2587

24.

Wu J, Wan Z, Fang Y (1998) Wave reflection by a vertical wall with a horizontal submerged porous plate. Ocean Eng 25(9):767–779CrossRef

25.

Liu Y, Li YC, Teng B, Dong S (2008) Wave motion over a submerged breakwater with an upper horizontal porous plate and a lower horizontal solid plate. Ocean Eng 35(16):1588–1596CrossRef

26.

Fang Z, Xiao L, Peng T (2017) Generalized analytical solution to wave interaction with submerged multi-layer horizontal porous plate breakwaters. J Eng Math 105(1):117–135MathSciNetMATHCrossRef

27.

Cho IH, Kim MH (2000) Interactions of horizontal porous flexible membrane with waves. J Waterw Port Coast Ocean Eng 126(5):245–253CrossRef

28.

Behera H, Sahoo T (2015) Hydroelastic analysis of gravity wave interaction with submerged horizontal flexible porous plate. J Fluids Struct 54:643–660CrossRef

29.

Williams TD, Meylan MH (2012) The Wiener-Hopf and residue calculus solutions for a submerged semi-infinite elastic plate. J Eng Math 75(1):81–106MathSciNetMATHCrossRef

30.

Smith MJA, Peter MA, Abrahams ID, Meylan MH (2020) On the Wiener-Hopf solution of water-wave interaction with a submerged elastic or poroelastic plate. Proc R Soc A 476(2242):20200360MathSciNetCrossRef

31.

Elchahal G, Younes R, Lafon P (2008) The effects of reflection coefficient of the harbour sidewall on the performance of floating breakwaters. Ocean Eng 35(11–12):1102–1112CrossRef

32.

Goda Y (2010) Random seas and design of maritime structures. World Scientific, SingaporeMATHCrossRef

33.

Molin B, Remy F (2015) Inertia effects in TLD sloshing with perforated screens. J Fluids Struct 59:165–177CrossRef

34.

Liu Y, Li HJ (2017) Iterative multi-domain BEM solution for water wave reflection by perforated caisson breakwaters. Eng Anal Bound Elem 77:70–80MathSciNetMATHCrossRef

35.

Lee JF, & Liu CC (1995). A new solution of waves passing a submerged porous structure. In: Proceedings of the 17th International Conference on Coastal Engineering, pp 593–606

36.

Linton CM, McIver P (2001) Handbook of mathematical techniques for wave/structure interactions. CRC PressMATHCrossRef

37.

Isaacson M, Qu S (1990) Waves in a harbour with partially reflecting boundaries. Coast Eng 14(3):193–214CrossRef

38.

Suh KD, Ji CH, Kim BH (2011) Closed-form solutions for wave reflection and transmission by vertical slotted barrier. Coast Eng 58(12):1089–1096CrossRef

39.

Huang Z, Li Y, Liu Y (2011) Hydraulic performance and wave loadings of perforated/slotted coastal structures: a review. Ocean Eng 38(10):1031–1053CrossRef

40.

Mei CC, Liu PL, Ippen AT (1974) Quadratic loss and scattering of long waves. J Waterw Harb Coast Eng Div 100(3):217–239CrossRef

41.

Flagg CN, Newman JN (1971) Sway added-mass coefficients for rectangular profiles in shallow water. J Ship Res 15(04):257–265CrossRef

42.

Taylor PJ (1973) The blockage coefficient for flow about an arbitrary body immersed in a channel. J Ship Res 17(02):97–105CrossRef

43.

Vijay KG, Neelamani S, Sahoo T (2019) Wave interaction with multiple slotted barriers inside harbour: physical and numerical modelling. Ocean Eng 193:106623CrossRef

44.

Mackay E, Johanning L (2020) Comparison of analytical and numerical solutions for wave interaction with a vertical porous barrier. Ocean Eng 199:107032CrossRef

45.

Wang CD, Meylan MH (2002) The linear wave response of a floating thin plate on water of variable depth. Appl Ocean Res 24(3):163–174CrossRef

46.

Vijay KG, Nishad CS, Neelamani S, Sahoo T (2021) Wave interaction with multiple wavy porous barriers using dual boundary element method. Eng Anal Bound Elem 122:176–189MathSciNetMATHCrossRef

47.

Wang G, Ren B, Wang Y (2016) Experimental study on hydrodynamic performance of arc plate breakwater. Ocean Eng 111:593–601CrossRef

Title: Analytical study for oblique wave interaction with a submerged horizontal perforated plate near a partially reflecting vertical wall
Authors: Y. Zhao
K. G. Vijay
S. Neelamani
Y. Liu
Publication date: 09-04-2021
Publisher: Springer Netherlands
Published in: Meccanica / Issue 7/2021
Print ISSN: 0025-6455
Electronic ISSN: 1572-9648
DOI: https://doi.org/10.1007/s11012-021-01339-x

Springer Professional

Abstract

Please log in to get access to your license.

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Springer Professional "Technik"

Other articles of this Issue 7/2021

The influence of an initial twisting on tapered beams undergoing large displacements

Coupled diffusion and phase transition: Phase fields, constraints, and the Cahn–Hilliard equation

Study on tooth profile design of harmonic drive with deformation model of flexspline

Combined interval analysis - Monte Carlo simulation approach for the analysis of uncertainties in parallel manipulators

An analytical approach for calculating natural frequencies of finite one-dimensional acoustic metamaterials

A note on non-symmetric flow: surface shrinking in mutually orthogonal directions

Premium Partners