三体船在规则头波中运动响应的CFD模拟

Royal Institution of Naval Architects Transactions Pub Date : 2020-03-01 DOI:10.3940/rina.ijme.2020.a1.595

L. Nowruzi, H. Enshaei, J. Lavroff, S. Kianejad, Davis

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引用次数: 15

摘要

计算流体力学(CFD)已被证明是求解船舶自由表面粘性流动中的非定常reynolds - average Navier-Stokes (RANS)方程的有效方法。本文的研究旨在更好地理解影响高速三体船运动响应的参数。求解RANS方程时进行了系统网格化、时间步长分析和可靠性分析。研究了不同的湍流模型，证明了SST Menter K Omega湍流模型比Realizable K-epsilon模型更精确。为了验证CFD方法的有效性，将高速三体船的运动响应结果与1.6 m三体船模型在不同顶海条件下的实验和数值结果进行了比较。结果表明，与传统的条形理论方法相比，CFD提供了一种可靠的方法来预测三体船在规则头波中的俯仰和升沉运动。与条形理论不同，CFD应用中考虑了破浪、水线以上船体形状和绿海的影响。观察到波浪共振现象，并确定了CFD中波浪-流-风相互作用导致的波浪变形是差异的主要来源。这项工作的结果为未来分析斜海中三体船的运动奠定了基础，以便更好地理解影响耐波响应和乘客舒适度的参数。

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CFD Simulation of Motion Response of a Trimaran in Regular Head Waves

CFD has proved to be an effective method in solving unsteady Reynolds–Averaged Navier-Stokes (RANS) equations for analysing ships in free surface viscous flow. The research reported in this paper is intended to develop a better understanding of the parameters influencing high-speed trimaran motions responses. Gridding system, time step and reliability analysis were performed in solving RANS equations. Different turbulence models were investigated, and the SST Menter K Omega turbulence model proved a more accurate model than Realizable K-epsilon model. In order to validate the CFD method, the results of the motions response of a highspeed trimaran are compared against a set of experimental and numerical results from a 1.6 m trimaran model tested in various head seas conditions. The results suggest that CFD offers a reliable method for predicting pitch and heave motions of trimarans in regular head waves when compared to traditional Strip Theory methods. Unlike strip theory, the effect of breaking waves, hull shape above waterline and green seas are considered in CFD application. A wave resonance phenomenon was observed and Wave deformation as a result of wave-current-wind interaction in CFD was identified as the main source of discrepancy. The results from this work form the basis for future analysis of trimaran motions in oblique seas for developing a better understanding of the parameters influencing the seakeeping response, as well as passenger comfort.

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Royal Institution of Naval Architects Transactions

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