基于计算流体力学方法的水线面大开口工程船阻力性能分析

摘要/Abstract

摘要： 运用计算流体力学（CFD）方法对工程船由船体水线面大开口所引起的船体阻力性能变化进行了分析.通过对某水线面大开口型工程船系列模型的黏性绕流进行数值模拟，得到在低航速下水线面大开口型船舶船艏开口纵向和横向尺寸变化，船艉开口纵向和横向尺寸变化以及艏艉开口相互作用对船体阻力性能的影响，为改善此类船型的船体阻力性能提供了参考依据.

关键词: 工程船, 开口, 计算流体力学, 船舶阻力

Abstract: Variance of ship resistance caused by notches in working ship was studied based on CFD method. By numerically simulating the viscous flow around a series of working ship models with notches, the effects of the variation of notch size in bow in longitudinal and transverse direction, the variation of notch size in stern in longitudinal and transverse direction and the interaction of the notches in bow and stern on ship resistance performance at low speed were obtained. Basis for improving the resistance performance of this kind vessel was provided.

Key words: working ship, notch, computational fluid dynamics (CFD), ship resistance

中图分类号:

U 661.31

石珣, 陈新权, 谭家华. 基于计算流体力学方法的水线面大开口工程船阻力性能分析[J]. 上海交通大学学报（自然版）, 2012, 46(08): 1178-1183.

SHI Xun, CHEN Xin-Quan, TAN Jia-Hua. Study on Resistance Performance of Working Ship with Notches Based on CFD[J]. Journal of Shanghai Jiaotong University, 2012, 46(08): 1178-1183.

参考文献

［1］

王忠复, 黄继昌. 工程船［M］. 北京: 国防工业出版社, 1984.
［2］刘厚恕. 1250m3/h吸盘挖泥船总体设计［J］. 船舶, 1995(2): 1016.
［3］XIE N, DODWORTH K, VASSALOS D, et al. Computation of free surface turbulent flow around a Wigley hull ［J］. Journal of Ship Mechanics, 2001, 5(6): 18.
［4］杨培青, 管义锋. 基于CFD的三维船体摩擦阻力预报与验证［J］. 船舶工程, 2007,29(3): 6164.
YANG Peiqing, GUAN Yifeng. Prediction and validation of frictional resistance of 3D hull based on CFD ［J］. Ship Engineering, 2007,29(3): 6164.
［5］陈康, 黄德波. CFD技术在三体船阻力性能研究中的应用［J］. 哈尔滨工程大学学报, 2006, 27(6): 362366.
CHEN Kang, HUANG Debo. Application of CFD technology to the research of resisitance perfornance of trimaran ［J］. Journal of Harbin Engineering University, 2006, 27(6): 362366.
［6］Tahara Y, Peri D, Campana E F, et al. Singleand multiobjective design optimization of a fast multihull ship: Numerical and experimental results ［J］. Journal of Marine Science and Technology, 2011, 16(4): 412433.
［7］Tabaczek T. Computation of flow around inland waterway vessel in shallow water ［J］. Archives of Civil and Mechanical Engineering, 2008, 8(1): 99107.
［8］ZHANG Zhirong, LIU Hui, ZHU Songping, et al. Application of CFD in ship engineering design practice and ship hydrodynamics ［J］. Journal of Hydrodynamics, 2006,18(3): 315322.
［9］赵峰, 李胜忠, 杨磊. 基于CFD的船型优化设计研究进展综述［J］. 船舶力学, 2010, 14(7): 812821.
ZHAO Feng, LI Shengzhong, YANG Lei. An overview on the design optimization of ship hull based on CFD techniques ［J］. Journal of Ship Mechanics, 2010, 14(7): 812821.
［10］谢玲玲, 陈顺怀, 吴静萍. 应用FLUENT软件优化船舶阻力性能［J］. 华中科技大学学报(自然科学版), 2009, 37(6), 101103.
XIE Lingling, CHEN Shunhuai, WU Jingping. Optimization of the resistance property of ship by FLUENT software ［J］. Journal Huazhong University of Science and Technology (Natural Science Edition), 2009, 37(6): 101103.
［11］SHI Xun, CHEN Xinquan, TAN Jiahua. Study of resistance performance of vessels with notches by experimental and computational fluid dynamics calculation methods ［J］. Journal of Shanghai Jiaotong University (Science), 2010, 115(3): 340345.
［12］MENTER F R. Twoequation eddyviscosity turbulence models for engineering applications ［J］. AIAA Journal, 1994, 32(8): 15981605.
［13］Svennberg U S. On turbulence modelling for bilge vortices: A test of eight models for three cases ［D］. Goteborg: Chalmers University of Technology, 2001.
［14］张志荣, 李百齐, 赵峰. 船舶粘性流动计算中湍流模式应用的比较［J］. 水动力学研究与进展(A辑), 2004, 19(5): 637642.
ZHANG Zhirong, LI Baiqi, ZHAO Feng. The comparison of turbulence models applied to viscous ship flow computation ［J］. Journal of Hydrodynamics（A）, 2004, 19(5): 637642.

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