Interaction of uniform current with a circular cylinder submerged below an ice sheet

The problem of a uniform current passing through a circular cylinder submerged below an ice sheet is considered. The fluid flow is described by the linearized velocity potential theory, while the ice sheet is modelled through a thin elastic plate floating on the water surface. The Green function due...

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Bibliographic Details
Main Authors: Li, ZF, Wu, GX, Shi, YY
Format: Article in Journal/Newspaper
Language:English
Published: ELSEVIER SCI LTD 2019
Subjects:
Ice sheet deflection
Uniform current
Circular cylinder
Critical Froude number
Resistance and lift
Ice Sheet
Online Access:https://discovery.ucl.ac.uk/id/eprint/10074006/1/Manuscript_revised_unmarked_APOR_2018_632.pdf
https://discovery.ucl.ac.uk/id/eprint/10074006/
Description
Summary:The problem of a uniform current passing through a circular cylinder submerged below an ice sheet is considered. The fluid flow is described by the linearized velocity potential theory, while the ice sheet is modelled through a thin elastic plate floating on the water surface. The Green function due to a source is first derived, which satisfies all the boundary conditions apart from that on the body surface. Through differentiating the Green function with respect to the source position, the multipoles are obtained. This allows the disturbed velocity potential to be constructed in the form of an infinite series with unknown coefficients which are obtained from the boundary condition. The result shows that there is a critical Froude number which depends on the physical properties of the ice sheet. Below this number there will be no flexural waves propagating to infinity and above this number there will be two waves, one on each side of the body. When the depth based Froude number is larger than 1, there will always be a wave at far upstream of the body. This is similar to those noticed in the related problem and is different from that in the free surface problem without ice sheet. Various results are provided, including the properties of the dispersion equation, resistance and lift, ice sheet deflection, and their physical features are discussed.

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