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Journal of Engineering Mathematics

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01-04-2024

Analyses of aerodynamic forces on a three-dimensional pitching plate above surface waves

Author: Meng-Yu Lin

Published in: Journal of Engineering Mathematics | Issue 1/2024

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Abstract

Since a floating solar panel is set above a water surface, the ground effect due to the small gap between the panel and the free surface may be induced by the wind load, in turn causing a high lift force on the panel. In this paper, the wind load on a three-dimensional thin flat plate floating on surface waves is studied analytically under linear assumptions. The clearance between the panel and the free surface is set to be smaller than the panel length and the effects of the base of the floating system are ignored. The pitch motion of the plate due to linear surface waves is considered and the effects of the aspect ratio of the plate, wave number, and wave speed of the free surface are discussed. The analytical solution shows that, if the plate is stationary and the free surface is flat (no waves), then the lift coefficient increases with aspect ratio. For a pitching plate above surface waves, lift coefficient increases with aspect ratio for longer wavelengths, but decreases when the aspect ratio increases for shorter wavelengths. Minimum lift and the associated wave number and aspect ratio for different wave speeds are also discussed. The findings of this study are anticipated to enhance the design of floating solar panels, improving their capacity to withstand substantial wind and waves.

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World Bank Group (2018) ESMAP, SERIS: where sun meets water: floating solar marker report—executive summary. Technical report, World Bank, Washington

Wang Q-X (1992) Analysis of slender bodies of revolution with curved-ground effect and waving-water effect. Fluid Dyn Res 9(5–6):235–254CrossRef

Rozhdestvensky KV (2006) Wing-in-ground effect vehicles. Prog Aerosp Sci 42(3):211–283CrossRef

Widnall SE, Barrows TM (1970) An analytic solution for two- and three-dimensional wings in ground effect. J Fluid Mech 41(4):769–792CrossRef

Tuck EO (1980) A nonlinear unsteady one-dimensional theory for wings in extreme ground effect. J Fluid Mech 98(1):33–47MathSciNetCrossRef

Tuck EO (1983) Nonlinear extreme ground effect on thin wings of arbitrary aspect ratio. J Fluid Mech 136:73–84CrossRef

Newman JN (1982) Analysis of small-aspect-ratio lifting surfaces in ground effect. J Fluid Mech 117:305–314CrossRef

Wang Q-X (1991) Flow around an unsteady thin wing close to curved ground. J Fluid Mech 226:175–187MathSciNetCrossRef

Wang QX (2005) Analyses of a slender body moving near a curved ground. Phys Fluids 17(9):097102–18MathSciNetCrossRef

10.

Katz J, Plotkin A (2001) Low-speed aerodynamics, 2nd edn. Cambridge University Press, CambridgeCrossRef

11.

Kwag S-H (2001) Lift/drag prediction of 3-dimensional WIG moving above free surface. KSME Int J 15(3):384–391CrossRef

12.

Barber TJ (2007) A study of water surface deformation due to tip vortices wing-in-ground effect. J Ship Res 51(02):182–186CrossRef

13.

Zong Z, Liang H, Zhou L (2012) Lifting line theory for wing-in-ground effect in proximity to a free surface. J Eng Math 74(1):143–158CrossRef

14.

Im Y-H, Chang K-S (2012) Unsteady aerodynamics of a wing-in-ground-effect airfoil flying over a wavy wall. J Aircr 37(4):690–696CrossRef

15.

Liang H, Zong Z, Zou L, Zhou L, Sun L (2013) Vortex shedding from a two-dimensional cylinder beneath a rigid wall and a free surface according to the discrete vortex method. Eur J Mech-B/Fluids 43:110–119MathSciNetCrossRef

16.

Liang H, Zong Z, Zou L (2013) Nonlinear lifting theory for unsteady WIG in proximity to incident water waves. Part 1: two-dimension. Appl Ocean Res 43:99–111CrossRef

17.

Liang H, Zong Z, Zou L (2013) Nonlinear lifting theory for unsteady WIG in proximity to incident water waves. Part 2: three-dimension. Appl Ocean Res 43:88–98CrossRef

18.

Liang H, Wang X, Zou L, Zong Z (2014) Numerical study of two-dimensional heaving airfoils in ground effect. J Fluids Struct 48(C):188–202CrossRef

19.

Bal S (2016) Free surface effects on 2-D airfoils and 3-D wings moving over water. Ocean Syst Eng 6(3):245–264CrossRef

20.

Sahu A, Yadav N, Sudhakar K (2016) Floating photovoltaic power plant: a review. Renew Sustain Energy Rev 66:815–824CrossRef

21.

Fukuda K, Balachandar R, Barron RM (2020) Analysis of the ground effect on development of flow structures around an inclined solar panel. Environ Fluid Mech 20(6):1463–1489CrossRef

22.

Shademan M, Balachandar R, Barron RM (2014) Detached eddy simulation of flow past an isolated inclined solar panel. J Fluids Struct 50:217–230CrossRef

23.

Jubayer CM, Hangan H (2014) Numerical simulation of wind effects on a stand-alone ground mounted photovoltaic (PV) system. J Wind Eng Ind Aerodyn 134:56–64CrossRef

24.

Gayathri R, Behera H (2020) Mitigation of wave force on a circular flexible plate by a surface-piercing flexible porous barrier. Proc Inst Mech Eng Part M 235(2):586–599

25.

Michele S, Zheng S, Greaves D (2022) Wave energy extraction from a floating flexible circular plate. Ocean Eng 245:110275CrossRef

26.

Li Z, Chen D, Feng X (2023) Hydroelastic and expansibility analysis of a modular floating photovoltaic system with multi-directional hinge connections. Ocean Eng 289:116218CrossRef

27.

Michele S, Zheng S, Buriani F, Borthwick AGL, Greaves DM (2023) Floating hydroelastic circular plate in regular and irregular waves. Eur J Mech B Fluids 99:148–162MathSciNetCrossRef

28.

Rozhdestvensky KV (2000) Aerodynamics of a lifting system in extreme ground effect. Springer, BerlinCrossRef

Title: Analyses of aerodynamic forces on a three-dimensional pitching plate above surface waves
Author: Meng-Yu Lin
Publication date: 01-04-2024
Publisher: Springer Netherlands
Published in: Journal of Engineering Mathematics / Issue 1/2024
Print ISSN: 0022-0833
Electronic ISSN: 1573-2703
DOI: https://doi.org/10.1007/s10665-024-10337-3

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