基于水动力分解的船体-螺旋桨系统多工况优化

IF 0.5 4区工程技术 Q4 ENGINEERING, MARINE

Journal of Ship Production and Design Pub Date : 2022-12-30 DOI:10.5957/jspd.10180038

Hassan Zakerdoost, H. Ghassemi

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引用次数: 0

摘要

在本研究中，开发了一个用于波浪中船体-螺旋桨系统（HPS）分析和设计优化的框架。该框架可作为一种有效的综合工具，在船舶设计的早期阶段确定HPS的主要几何特征。优化是在两个级别和多点操作条件（OC）下进行的。将基于分解的多目标进化算法（MOEA/D）作为一种高效的多目标演化算法，将Michell积分和OpenProp工具作为低保真度流体动力学求解器，将边界元法（BEM）作为中保真度求解器，应用于两个算例研究，以最大限度地减小HPS的有效功率和提高其推进效率。为了估计附加的波浪阻力，还采用了一个有效的半经验公式。原型号为DTMB P4118单螺旋桨的60系列船型和KP505双螺旋桨的S175船型。数值结果表明，该框架可以找到具有更好水动力性能的优化设计。在过去的几年里，基于多种设计条件优化船体和螺旋桨的水动力性能变得相当重要。高昂的燃油成本是造船厂和船东现在比以往任何时候都更关注降低有效功率和推进效率的原因。有效功率和推进效率等水动力性能参数由船体形状和螺旋桨形状决定，因此在船舶早期设计中选择性能良好的船体-螺旋桨系统是非常重要的。在海洋系统的水动力设计优化中，存在两个主要因素。第一个因素是同时考虑影响目标函数的系统的所有组件，第二个因素是选择一个耗时较少、精度令人满意的求解器。在船舶设计过程中，必须考虑这两个因素进行合理的优化。

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Hydrodynamic Decomposition-Based Optimization of Ship’s Hull–Propeller System Under Multiple Operating Conditions

In this research, a framework for the analysis and design optimization of ship hull–propeller systems (HPSs) in waves is developed. This framework can be utilized as an efficient synthesis tool to determine the main geometric characteristics of the HPSs during the early stage of ship design. The optimization is carried out in two levels and under multipoint operating conditions (OC). Multiobjective evolutionary algorithm based on decomposition (MOEA/D) as an efficient multiobjective evolutionary algorithm, Michell integral and OpenProp tool as low-fidelity hydrodynamic solvers and boundary element method (BEM) as medium-fidelity solver are applied on two case studies to minimize the effective power and maximize the propulsive efficiency of HPSs. To estimate the added wave resistance, an efficient semiempirical formula is also employed. The Series 60 hull form with DTMB P4118 single propeller and S175 hull form with KP505 twin-propeller are considered as the original models. The numerical results show that the framework can find optimized designs with better hydrodynamic performance. Optimizing the hydrodynamic performance of ships’ hull and propeller(s) based on multiple design condition has gained considerable importance over the last few years. High fuel oil costs are the reason that shipyards and ship owners are now focusing more than ever on the reduction of effective power and propulsive efficiency. Hydrodynamic performance parameters, such as effective power and propulsive efficiency, are determined by the hull form and propeller shape, so it is very important to choose a hull–propeller system (HPS) with good performance in early stage ship design. There exist two main factors in the hydrodynamic design optimization of marine systems. The first factor is simultaneously considering all components of the system influencing objective function(s) and the second one is selecting a less time-consuming solver with satisfactory accuracy. In the ship design process, these two factors must be taken for conducting a reasonable optimization into consideration.

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来源期刊

Journal of Ship Production and Design ENGINEERING, MARINE-

CiteScore

1.10

自引率

0.00%

发文量

期刊介绍： Original and timely technical papers addressing problems of shipyard techniques and production of merchant and naval ships appear in this quarterly publication. Since its inception, the Journal of Ship Production and Design (formerly the Journal of Ship Production) has been a forum for peer-reviewed, professionally edited papers from academic and industry sources. As such it has influenced the worldwide development of ship production engineering as a fully qualified professional discipline. The expanded scope seeks papers in additional areas, specifically ship design, including design for production, plus other marine technology topics, such as ship operations, shipping economics, and safety. Each issue contains a well-rounded selection of technical papers relevant to marine professionals.