Influence of Cavitator Shape on Ventilated Supercavitation in Head Support Mode
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摘要: 目前, 空化器外形对超空泡形态的影响研究都是在空化器前的流场未被干扰时进行的, 当水洞试验因采用头部支撑方式而影响了空化器前的流场时, 通气超空泡形态随空化器外形的变化规律尚不明确。本文应用计算流体力学(CFD)仿真软件FLUENT, 参照头支撑下通气超空泡生成的试验模型, 建立了随空化器直径、连接杆直径和空化器锥角变化的仿真模型。在通气量一定的情况下, 通气超空泡的长度和长径比随头支撑连接杆的增大而增大, 随空化器直径的增大而减小, 随空化器锥角的减小而增大, 并深入研究了空化器外形对空泡尺寸的影响规律, 为水洞超空泡试验在头支撑方式下空化器外形的设计提供参考。Abstract: The research on the influence of cavitator shape on supercavitation is usually conducted in the condition where the front flow of cavitator is not disturbed. However, when the front flow of cavitator is influenced by using of head support mode in water tunnel test, the changing law of ventilated supercavitation with the shape of cavitator is not clear. In this study, a series of simulation models in accordance with the experimental ones are built by means of the computational fluid dynamics (CFD) simulation software FLUENT. These models depend on the diameter of cavitator, the diameter of the connecting rod, and the cone angle of the cavitator. Simulation indicates that under certain ventilation, the length and the length to diameter ratio of the ventilated supercavitation increase with the diameter of connecting rod increasing, decrease with the diameter of cavitator increasing, or increase with the cone angle of cavitator decreasing. Moreover, the influencing laws of the cavitator shape on ventilated supercavitation are also investigated. This study may facilitate the design of cavitator shape for the water tunnel test of supercavitation in head support mode.
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