Practical evaluation of the drag of a ship for design and optimization 被引量：4

Practical evaluation of the drag of a ship for design and optimization

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摘要 We consider two major components of the drag of a ship, the ＂friction drag＂ and the ＂wave drag＂, that are related to viscous friction at the hull surface and wavemaking, and mostly depend on the Reynolds number and the Froude number, respectively. We also consider the influence of sinkage and trim, viscosity, and nonlinearities on the drag. The sum of the friction drag given by the classical ITTC friction formula and the wave drag predicted by the modification, called Neumann-Michell （NM） theory, of the classical Neumann-Kelvin theory of ship waves is found to be within about 10% of experimental drag measurements for four ship hulls for which theoretical predictions and experimental measurements are compared. The sum of the ITTC friction drag and the NM wave drag can then be expected to yield realistic practical estimates that can be useful for routine applications to design and hull- form optimization of a broad range of displacement ships. Furthermore, we note several simple extensions of this highly simplified approach that can be expected to significantly improve accuracy. We consider two major components of the drag of a ship, the ＂friction drag＂ and the ＂wave drag＂, that are related to viscous friction at the hull surface and wavemaking, and mostly depend on the Reynolds number and the Froude number, respectively. We also consider the influence of sinkage and trim, viscosity, and nonlinearities on the drag. The sum of the friction drag given by the classical ITTC friction formula and the wave drag predicted by the modification, called Neumann-Michell （NM） theory, of the classical Neumann-Kelvin theory of ship waves is found to be within about 10% of experimental drag measurements for four ship hulls for which theoretical predictions and experimental measurements are compared. The sum of the ITTC friction drag and the NM wave drag can then be expected to yield realistic practical estimates that can be useful for routine applications to design and hull- form optimization of a broad range of displacement ships. Furthermore, we note several simple extensions of this highly simplified approach that can be expected to significantly improve accuracy.

作者 YANG Chi HUANG Fuxin NOBLESSE Francis

机构地区 Center for Computational Fluid DynamicsGeorge Mason University State Key Laboratory of Ocean Engineering and School of Naval Architecture

出处《Journal of Hydrodynamics》 SCIE EI CSCD 2013年第5期645-654,共10页 水动力学研究与进展B辑（英文版）

基金 partly supported by the Office of Naval Research

关键词 friction drag wave drag Neumann-Michell （NM） theory sinkage and trim nonlinear effects friction drag, wave drag, Neumann-Michell （NM） theory, sinkage and trim, nonlinear effects

分类号 U661.311 [交通运输工程—船舶及航道工程]

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参考文献16

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Practical evaluation of the drag of a ship for design and optimization 被引量：4

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