Hydroelastic waves propagating in an ice-covered channel
Hydroelastic waves propagating in an ice-covered channel
The hydroelastic waves in a channel covered by an ice sheet, without or with crack and subject to various edge constraints at channel banks, are investigated based on the linearized velocity potential theory for the fluid domain and the thin-plate elastic theory for the ice sheet. An effective analytical solution procedure is developed through expanding the velocity potential and the fourth derivative of the ice deflection to a series of cosine functions with unknown coefficients. The latter are integrated to obtain the expression for the deflection, which involves four constants. The procedure is then extended to the case with a longitudinal crack in the ice sheet by using the Dirac delta function and its derivatives at the crack in the dynamic equation, with unknown jumps of deflection and slope at the crack. Conditions at the edges and crack are then imposed, from which a system of linear equations for the unknowns is established. From this, the dispersion relation between the wave frequency and wavenumber is found, as well as the natural frequency of the channel. Extensive results are then provided for wave celerity, wave profiles and strain in the ice sheet. In-depth discussions are made on the effects of the edge condition, and the crack.
Ren, K.
d579a21f-df53-4646-b697-5314e79d82e0
Wu, G.X.
39f0a2aa-f4c2-48a3-a544-63b702988850
Li, Z.F.
ef5d9bc5-4f03-4eac-85b8-4b908166b0b0
10 March 2020
Ren, K.
d579a21f-df53-4646-b697-5314e79d82e0
Wu, G.X.
39f0a2aa-f4c2-48a3-a544-63b702988850
Li, Z.F.
ef5d9bc5-4f03-4eac-85b8-4b908166b0b0
Ren, K., Wu, G.X. and Li, Z.F.
(2020)
Hydroelastic waves propagating in an ice-covered channel.
Journal of Fluid Mechanics, 886, [A18].
(doi:10.1017/jfm.2019.1042).
Abstract
The hydroelastic waves in a channel covered by an ice sheet, without or with crack and subject to various edge constraints at channel banks, are investigated based on the linearized velocity potential theory for the fluid domain and the thin-plate elastic theory for the ice sheet. An effective analytical solution procedure is developed through expanding the velocity potential and the fourth derivative of the ice deflection to a series of cosine functions with unknown coefficients. The latter are integrated to obtain the expression for the deflection, which involves four constants. The procedure is then extended to the case with a longitudinal crack in the ice sheet by using the Dirac delta function and its derivatives at the crack in the dynamic equation, with unknown jumps of deflection and slope at the crack. Conditions at the edges and crack are then imposed, from which a system of linear equations for the unknowns is established. From this, the dispersion relation between the wave frequency and wavenumber is found, as well as the natural frequency of the channel. Extensive results are then provided for wave celerity, wave profiles and strain in the ice sheet. In-depth discussions are made on the effects of the edge condition, and the crack.
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Accepted/In Press date: 9 December 2019
e-pub ahead of print date: 14 January 2020
Published date: 10 March 2020
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Local EPrints ID: 493478
URI: http://eprints.soton.ac.uk/id/eprint/493478
ISSN: 0022-1120
PURE UUID: fad90714-1fcf-4df9-9eec-c279fffe5d34
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Date deposited: 03 Sep 2024 16:52
Last modified: 04 Sep 2024 02:10
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Author:
K. Ren
Author:
G.X. Wu
Author:
Z.F. Li
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