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本文提供了小水线面双体船(SWATH)结构载荷的解析方法以及用于初步设计的简捷算法经验公式。确定船体运动和波浪载荷的方法是以谐波中船舶的线性响应为基础,按零航速横浪来计算的。根据模型试验结果此种状态是SWATH最危险的载荷状态。以前应用于3000-30000t船的经验算法往往被不正确地用于小吨位的船上,文中提供了一个新的经验算法可将应用界限扩展到小如50t的SWATH船上。 相似文献
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小水线面双体船波浪设计载荷估算方法 总被引:6,自引:1,他引:5
以中国船舶科学研究中心开展的200 t至3 500 t多艘SWATH船模试验结果和美国的15艘从3 000 t至30 000 t小水线面双体船波浪载荷模型试验资料为基础,给出了小水线面双体船波浪设计载荷估算公式.用该估算公式算得的小于3 000 t的小水线面双体船的波浪设计载荷的估算值更加接近模型试验结果,而小于目前常用的ABS公式估算值,从而可较大地减轻结构质量和建造成本.根据小水线面双体船受力特点,还提出了小水线面双体船在进行横向强度、扭转强度、总纵强度校核时各种载荷的组合方案和施加方式,供结构设计人员全面、合理地进行强度分析参考. 相似文献
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设计潜浮式小水线面船的三种控制方案,通过试验验证三种方案的优劣并分析其原因,进一步进行控制方案的优化.试验对比表明采用PID控制结合专家校正系统的控制方案能够很好的保持潜浮式小水线面船的纵倾、深沉的稳定,实现定深航行. 相似文献
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分析了小水线面双体船波浪载荷预报的几种方法,比较了准静态法,刚体动力学法,水弹性法和经验公式法的优缺点,讨论了与有限元离散结构有关的注意事项以及斜支柱结构形式对动载荷和疲劳的有利因素。 相似文献
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针对我国《海港水文规范》中基于线性波浪理论的浅水变形计算现状,本文的第Ⅰ部分提出了建立在椭圆余弦波理论基础上的浅水变形实用计算法(PCM),用于计算沿直线传播的波浪的浅水变形。在其基础上,考虑了海底地形变化引起的波浪折射影响,使得PCM方法能拓展用于缓变水域近岸浅水波要素的计算。最后给出一个算例,采用PCM方法分别计算了不同外界因素(理想情况、风、海底摩擦、风及海底摩擦)作用下的浅水变形结果,并与商业软件DHI-MIKE21的计算结果进行比较,结果比较吻合。 相似文献
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A hybrid boundary element method is suggested to solve the problem of the interaction of floating structures with both waves
and slow current. A pulsating source and its mirror image referring to the sea bottom are adopted as the Green's function.
The velocity potentials are expanded into an eigenfunction expansion in the outer region of the fluid domain while higher
order elements are used to discretize the boundary surface surrounding the inner region. The method is validated by comparing
calculated results for a circular cylinder with the semi-analytical solutions. The method is then applied to ellipsoids of
various breadth and draft to investigate the influence of body shape on the wave drift damping. 相似文献
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Yusuke Tahara Robert V. Wilson Pablo M. Carrica Frederick Stern 《Journal of Marine Science and Technology》2006,11(4):209-228
Steady flow simulations for the Korean Research Institute for Ships and Ocean Engineering (KRISO) container ship (KCS) were
performed for towing and self-propulsion. The main focus in the present article is on the evaluation of computational fluid
dynamics (CFD) as a tool for hull form design along with application of state-of-the-art technology in the flow simulations.
Two Reynolds-averaged Navier-Stokes (RANS) equation solvers were employed, namely CFDShip-Iowa version 4 and Flowpack version
2004e, for the towing and self-propulsion cases, respectively. The new features of CFDShip-Iowa version 4 include a single-phase
level-set method to model the free surface and an overset gridding capability to increase resolution in the flow and wave
fields. The new features of Flowpack version 2004e are related to a self-propulsion scheme in which the RANS solver is coupled
with a propeller performance program based on the infinitely bladed propeller theory. The present work is based on a close
interaction between IIHR-Hydroscience and Engineering of the University of Iowa and Osaka Prefecture University. In the following
article, overviews are given of the present numerical methods and results are presented and discussed for the KCS in towing
and self-propulsion modes, including comparison with available experimental fluid dynamics (EFD) data. Additional evaluation
is provided through discussion of the recent CFD Workshop Tokyo 2005, where both methods appeared to yield very promising
results. 相似文献