Numerical Simulation and Experiment on Fluid Field Characteristic of Planing for Supercavity Vehicle Tail
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摘要: 超空泡航行器尾部滑行升力对运动姿态具有重要影响。文中基于流体体积(VOF)多相流模型, 开展了不同后体攻角下超空泡航行器尾部在空泡内滑行过程的数值仿真, 通过与试验数据对比验证了数值仿真的有效性, 并在此基础上分析了空泡形态及尾部流场压力的变化规律。研究结果表明: 空泡在沾湿面附近由于压差作用会向航行器表面卷曲, 并引起向上的飞溅流动, 沾湿面压力沿空泡轮廓线方向的衰减速度比沿航行器下缘的衰减速度更快。研究结果可为滑行力建模提供参考。Abstract: The planing lift acting on the tail of a supercavitating vehicle has an important influence on its underwater moving posture. In this paper, the volume of fluid (VOF) multiphase flow model was employed to numerically simulate the supercavitating vehicle’s tail planing in cavity at different attack angles. The numerical simulation was verified by comparison with the experimental data. Then, the deformation of the cavity and the variation of the pressure distribution were analyzed. Numerical simulation results showed that the cavity curled towards the vehicle surface near the wetted area with pressure gradient, which produced an upward splashing flow. The decay rate of the pressure along the cavity outline is larger than that along the bottom edge of the vehicle.
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Key words:
- supercavity vehicle /
- tail /
- planing lift /
- numerical simulation /
- fluid field characteristic
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