斜流中船后螺旋桨水动力数值分析

基于CFD对国际标模KCS斜航状态进行了数值模拟,分析了不同漂角时螺旋桨在纵向、横向、垂向三个方向上的力和力矩的变化规律,并探讨了漂角对推力偏心矩的影响。数值模拟采用RANS(Reynolds-Averaged Navier Stokes)方法,结合SST k-ω湍流模型和滑移网格。计算考虑了±20o,±10o以及0o漂角,结果表明：由于横向水流改变了螺旋桨桨盘面上的载荷分布,漂角对螺旋桨的横向和垂向的力和力矩有显著影响,漂角方向对螺旋桨推力偏心矩的偏移有较大影响。     

绕船体自由面周围三维粘性流场的数值模拟

本文采用有限体积法通过求解不可压缩的雷诺平均(RANS)方程数值模拟了包括兴波的三维船体周围的粘性流场,湍流模式使用了子网格尺度模式(SGS)和Baldwin-Lomax模式相结合的混合模式.对于自由表面的处理,采用了任意拉格朗日-欧拉方法,网格为不仅与物体表面贴体,而且与自由表面贴体的动网格,即随着自由表面的变化要不断地重新划分网格.虽然此方法需要很长的计算时间,但能较好地描述船体的兴波情况.本文计算了系列60船模在Fn=0.316,Re=1.9×106时带自由面的粘性流场,计算结果与试验结果吻合较好.，An finite - volume method solving of incompressible RANS Equations is developed for the numeri-cal simulation of three - dimensional viscous flow with free - surface about a ship. A hybrid turbulence mod-el by combining the sub - grid scale (SGS) model and the Baldwin- Lomax model is used in this pa-per. The arbitrary - Lagrange - Euler formulation is devised for the treatment of free surface boundary condi-tion. The boundary - fitted coordinate system is fitted not only to the ship hull surface but also to the freesurface, so the computational grid is regenerated to follow the free surface deformation. Although this methodneeds spend much longer computational time, but it can fairly display wave pattern made by a ship. The nu-merical simulation has been carried out for viscous flow with free surface past Series 60 ship hull at Fn =0. 316, Re = 1.9 × 106. The computed results are in reasonable agreement with experimental measure-ments.     

顶浪规则波中小水线面双体船纵向运动特性数值分析

基于RANS方程和VOF模型求解船体粘性兴波流场,采用Overset技术处理船体运动,开展了小水线面双体船(Small Waterplane Area Twin Hulls,SWATH)迎浪规则波中运动响应特性及其产生机理的研究.通过数值计算结果与模型试验结果的对比分析,验证了本文方法的有效性;在此基础上,分析了船体运动响应曲线中各峰值产生的原因及片体间相互干扰对SWATH船在波浪中运动响应的影响,发现其中一个峰值出现的原因为遭遇频率接近船体运动固有频率,由此发生共振;另一个峰值的出现则可能与SWATH特殊的船型及附体配置有关.由于SWATH船片体间的水动力干扰效应,SWATH船在波浪中运动响应峰值较单个片体响应峰值明显减小,且出现的位置向低频方向移动.     

二维边界层流动转捩过程的数值计算(英文)

As a basic problem in many engineering applications, transition from laminar to turbulence still remains a difficult problem in computational fluid dynamics(CFD). A numerical study of one transitional flow in two-dimensional is conducted by Reynolds averaged numerical simulation(RANS) in this paper. Turbulence model plays a significant role in the complex flows' simulation, and four advanced turbulence models are evaluated. Numerical solution of frictional resistance coefficient is compared with the measured one in the transitional zone, which indicates that Wilcox(2006) k-ω model with correction is the best candidate. Comparisons of numerical and analytical solutions for dimensionless velocity show that averaged streamwise dimensionless velocity profiles correct the shape rapidly in transitional region. Furthermore, turbulence quantities such as turbulence kinetic energy, eddy viscosity, and Reynolds stress are also studied, which are helpful to learn the transition's behavior.     

螺旋桨在均匀流场中的非定常水动力数值模拟

采用滑移网格技术,使用基于求解RANS方程的CFD软件数值模拟均匀流场中的螺旋桨非定常水动力性能.为了真正实现螺旋桨的旋转运动,在计算过程中采用定长多运动参考系模型计算出初始流场,再用滑移网格模型完成整个计算.数值计算得到的推力系数和转矩系数与实验结果吻合良好,验证了该方法应用于螺旋桨水动力性能研究的可行性.     

CFD理论黏性流场中三维振动水翼的非定常水动力性能(英文)

The motion of the fins and control surfaces of underwater vehicles in a fluid is an interesting and challenging research subject. Typically the effect of fin oscillations on the fluid flow around such a body is highly unsteady, generating vortices and requiring detailed analysis of fluid-structure interactions. An understanding of the complexities of such flows is of interest to engineers developing vehicles capable of high dynamic performance in their propulsion and maneuvering. In the present study, a CFD based RANS simulation of a 3-D fin body moving in a viscous fluid was developed. It investigated hydrodynamic performance by evaluating the hydrodynamic coefficients (lift, drag and moment) at two different oscillating frequencies. A parametric analysis of the factors that affect the hydrodynamic performance of the fin body was done, along with a comparison of results from experiments. The results of the simulation were found in close agreement with experimental results and this validated the simulation as an effective tool for evaluation of the unsteady hydrodynamic coefficients of 3-D fins. This work can be further be used for analysis of the stability and maneuverability of fin actuated underwater vehicles.