A Coupled Frequency and Time Domain Approach for Hydroelastic Analysis of Very Large Floating Structure

Dengshuo Chen, Xingya Feng, Chao Hou, Jian-Fei Chen
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Abstract

This paper develops a practical approach based on Python that couples the hydrodynamic analysis with the structural analysis, in order to solve the hydroelastic problem of Very Large Floating Structure (VLFS). The hydrodynamic analysis is carried out by solving linear 3D diffraction and radiation problems in the frequency domain, while the structural analysis is performed by a time-domain nonlinear finite element model. The coupling is realized by a generalized mode expansion method where the elastic deformation of the VLFS is regarded as extended radiation mode in the water. We consider a pontoon-type floating plate in regular waves. Analytical mode shape functions are used for representing the VLFS elastic deformations. The Mindlin plate theory is used for the finite element model. Convergence study of structure mode shape numbers, hydrodynamic model mesh and finite element model mesh is carefully carried out. Good agreements of the vertical displacement of the floating plate are found compared with experimental data and numerical results in the literature. Our simulation results show that the dynamic response of the VLFS is significantly influenced with consideration of its elastic deformation in the waves, and we see the influence is more pronounced in relatively shorter waves. The proposed approach is shown promising for hydroelastic analysis for more complex VLFS in realistic ocean seastates.
超大型浮体结构水弹性分析的频域-时域耦合方法
为了解决超大型浮体结构的水弹性问题,提出了一种基于Python的水动力分析与结构分析相结合的实用方法。水动力分析通过求解频域线性三维衍射和辐射问题进行,结构分析采用时域非线性有限元模型进行。该耦合采用广义模态展开方法,将VLFS的弹性变形视为水中的扩展辐射模态。我们考虑在规则波中的浮桥型浮板。采用解析模态振型函数表示VLFS弹性变形。有限元模型采用Mindlin板理论。对结构模态振型数、水动力模型网格和有限元模型网格进行了收敛性研究。通过与实验数据和数值计算结果的比较,发现浮板的垂向位移与文献吻合较好。仿真结果表明,考虑VLFS在波浪中的弹性变形对其动态响应有显著影响,并且在相对较短的波浪中影响更为明显。所提出的方法对实际海相中更复杂的VLFS的水弹性分析显示出良好的前景。
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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