This paper details the results of an experimental investigation into the cavitation instabilities created by a circular orifice conducted at the University of Alabama in Huntsville Propulsion Research Center. This experiment was conducted in concert with a computational simulation to serve as a reference point for the simulation. Testing was conducted using liquid nitrogen as a cryogenic propellant simulant. A 1.06 cm diameter thin orifice with a rounded inlet was tested in an approximately 1.25 kg/s flow with inlet pressures ranging from 504.1 kPa to 829.3 kPa. Pressure fluctuations generated by the orifice were measured using a high frequency pressure sensor located 0.64 tube diameters downstream of the orifice. Fast Fourier Transforms were performed on the high frequency data to determine the instability frequency. Shedding resulted in a primary frequency with a cavitation related subharmonic frequency. For this experiment, the cavitation instability ranged from 153 Hz to 275 Hz. Additionally, the strength of the cavitation occurred as a function of cavitation number. At lower cavitation numbers, the strength of the cavitation instability ranged from 2.4 % to 7 % of the inlet pressure. However, at higher cavitation numbers, the strength of the cavitation instability ranged from 0.6 % to 1 % of the inlet pressure.
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机译:本文详细介绍了在阿拉巴马大学亨茨维尔推进研究中心进行的圆形孔造成的空化不稳定性的实验研究结果。该实验是与计算模拟协同进行的,可以作为模拟的参考点。使用液氮作为低温推进剂模拟物进行测试。在入口压力为504.1 kPa至829.3 kPa的情况下,以约1.25 kg / s的流量测试了具有圆形入口的直径为1.06 cm的细孔。孔口产生的压力波动是使用位于孔口下游0.64管道直径的高频压力传感器测量的。对高频数据执行快速傅立叶变换,以确定不稳定性频率。脱落导致主频率具有与气蚀有关的次谐波频率。对于此实验,空化不稳定性的范围为153 Hz至275 Hz。另外,空化强度随空化次数而变。在较低的空化数下,空化不稳定性的强度范围为入口压力的2.4%至7%。但是,在较高的空化次数下,空化不稳定性的强度为入口压力的0.6%至1%。
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