船体外形表面的直接棱柱系数变化

IF 2.3 3区工程技术 Q2 ENGINEERING, MARINE

International Journal of Naval Architecture and Ocean Engineering Pub Date : 2024-01-01 DOI:10.1016/j.ijnaoe.2024.100615

Dayeon Jeong, Min-Jae Oh

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引用次数: 0

摘要

最初的船舶设计过程旨在优化船体形式，以提高船舶效率。在这一阶段，根据参考船进行船体形状变化，以满足船东的要求，例如改变 CP（棱柱系数）以调整断面线。这些变化完成后，就会生成一个曲面。然而，由于每次曲面创建都必须手动完成，因此这一反复过程非常耗时。因此，我们提出了一种直接将 CP 变化应用于船体曲面的方法，并将变化后的截面线设置为约束条件。在本研究中，我们采用了所提出的方法来修改船体曲面，以满足 CP 要求。然后提取修改后表面的截面线来验证结果。这种方法简化了船体外形的初始设计，缩短了整体设计时间，并有效地生成了高质量的船体外形表面。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Direct prismatic coefficient variation to hull form surface

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Direct prismatic coefficient variation to hull form surface

The initial ship design process aims to optimize the hull form to enhance ship efficiency. During this phase, hull form variations are executed based on a reference ship to meet shipowner requirements, such as altering the

C_{P}

(prismatic coefficient) to adjust the section lines. Once these variations are made, a surface is generated. However, this iterative process can be time-consuming as the surface creation must be done manually each time. Thus, we propose a method to directly apply

C_{P}

variation onto the hull form surface, setting the variated section line as a constraint. In this study, the proposed method is employed to modify the hull form surface to meet

C_{P}

requirements. The section lines of the modified surface are then extracted to validate the results. This streamlines in the initial hull form design, reduces the overall design time, and yields high-quality hull form surfaces efficiently.

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来源期刊

International Journal of Naval Architecture and Ocean Engineering ENGINEERING, MARINE-

CiteScore

4.90

自引率

4.50%

发文量

审稿时长

12 months

期刊介绍： International Journal of Naval Architecture and Ocean Engineering provides a forum for engineers and scientists from a wide range of disciplines to present and discuss various phenomena in the utilization and preservation of ocean environment. Without being limited by the traditional categorization, it is encouraged to present advanced technology development and scientific research, as long as they are aimed for more and better human engagement with ocean environment. Topics include, but not limited to: marine hydrodynamics; structural mechanics; marine propulsion system; design methodology & practice; production technology; system dynamics & control; marine equipment technology; materials science; underwater acoustics; ocean remote sensing; and information technology related to ship and marine systems; ocean energy systems; marine environmental engineering; maritime safety engineering; polar & arctic engineering; coastal & port engineering; subsea engineering; and specialized watercraft engineering.