Time Domain Modelling of Nonlinear Hydroelastic Problems for Sea Ice and Very Large Floating Structures by Finite Element Methods

Weir, Philip Thomas

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Time Domain Modelling of Nonlinear Hydroelastic Problems for Sea Ice and Very Large Floating Structures by Finite Element Methods

Weir, Philip Thomas

Cite this item: Weir, P. T. (2012). Time Domain Modelling of Nonlinear Hydroelastic Problems for Sea Ice and Very Large Floating Structures by Finite Element Methods (Thesis, Doctor of Philosophy). University of Otago. Retrieved from http://hdl.handle.net/10523/2567

Permanent link to OUR Archive version: http://hdl.handle.net/10523/2567

Date: 2012

Advisor: Squire, Vernon; Bennetts, Luke

Degree Name: Doctor of Philosophy

Degree Discipline: Mathematics and Statistics

Publisher: University of Otago

Keywords: hydroelastic; ice; floating; vlfs; floating structures; nonlinear; finite element method; FEM; elasticity

Research Type: Thesis

Languages: English

Abstract:

This research project develops an adaptable framework for simulating hydroelastic interaction using acceleration potential techniques. Finite Element Methods are used to solve for the motion of the fluid and of an elastic beam, which are coupled through Bernoulli’s nonlinear pressure equation and a nonlinear acceleration potential. Sensitivity tests are presented to quantify the effects of changes to the numerical parameters of the method, and to demonstrate that such effects are acceptably small for the type of configurations that we consider.

An extended discussion and comparison of a variety of nonlinear beam models is included, both to show the adaptability of this approach and to quantitatively establish the impact on the hydroelastic problem of various assumptions in the standard, linear beam theory. Additional research pathways under investigation are presented, alongside some initial findings, to further demonstrate the potential scope of this approach.

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