A partitioned solution approach for the simulation of the dynamic behaviour of flexible marine propellers

IF 1.4 Q3 ENGINEERING, MARINE

Ship Technology Research Pub Date : 2018-11-08 DOI:10.1080/09377255.2018.1542782

L. Radtke, Tobias Lampe, M. Abdel‐Maksoud, A. Düster

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引用次数: 8

Abstract

ABSTRACT Modern designs of ship-propellers make use of novel materials such as composites, which may show a much lower stiffness than classical material. In order to accurately predict the hydrodynamic characteristics of these propellers in real operating conditions, the structural deformation must be accounted for, which leads to a fluid-structure interaction problem. In the present paper, a partitioned solution approach for such a strongly coupled two-field problem is presented. Owing to the separate modelling of the fluid and the structural problem in such approaches, specialised numerical methods can be applied on either side. Thanks to their superior convergence properties, we use high-order finite elements to discretise the structural problem. On the fluid side, a boundary element method, which is specifically designed to simulate the hydrodynamic behaviour of ship propellers is employed. In order to stabilise the solution procedure, different coupling algorithms and convergence acceleration methods are investigated.

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船用柔性螺旋桨动力特性模拟的分区求解方法

现代船舶螺旋桨设计采用复合材料等新型材料，其刚度可能比传统材料低得多。为了准确地预测螺旋桨在实际工作状态下的水动力特性，必须考虑结构变形，这就导致了流固耦合问题。本文给出了这类强耦合双场问题的一种分区解方法。由于在这些方法中流体和结构问题的建模是分开的，因此可以在任何一方应用专门的数值方法。由于其优越的收敛性，我们使用高阶有限元来离散结构问题。在流体方面，采用了专门用于模拟船舶螺旋桨水动力特性的边界元方法。为了稳定求解过程，研究了不同的耦合算法和收敛加速方法。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Ship Technology Research ENGINEERING, MARINE-

CiteScore

4.90

自引率

4.50%

发文量