联合循环发动机中火箭发动机位置的布置

Tatsushi Isono, T. Fujikawa, T. Tsuchiya, Kan Kobayashi, M. Kodera, K. Tani, S. Tomioka
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引用次数: 0

摘要

为了避免嵌入式火箭基联合循环发动机内部存在严重的热负荷,本研究对火箭发动机的位置进行了安排,即在超燃冲压发动机流道上单独安装火箭发动机。火箭发动机从超燃冲压发动机流道中取出并位于超燃冲压发动机外部喷管的斜坡壁上。在这种情况下,坡道壁以钉状喷管的方式作为火箭内部喷管的附加喷管。一维分析表明,存在一个对超燃冲压发动机外喷管有利的最佳膨胀比。在此基础上,对基于特征法的二维波动模型进行了一些改进,部分地进行了更复杂的分析,该模型可以表达排气与环境流之间的压力不匹配。二维分析表明,由于压力不匹配导致的罩唇膨胀波的冲击,超燃冲压发动机外喷管内的推力产生会大大降低。这种压力变化也大大降低了火箭喷管的推力性能。然而,也证明了目前所分析的喷管系统有很大的潜力,可以通过控制罩唇膨胀波的冲击来大幅度提高其推力性能。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Arrangement of Rocket Engine Location in a Combined Cycle Engine
To avoid the severe thermal load within the embeddedly configured Rocket-Based Combined Cycle engine, we arranged the rocket engine location in the present study, that is, the rocket engine was separately mounted for the scramjet flowpath. The rocket engine was taken out from the scramjet flowpath and located on the ramp wall of the scramjet external nozzle. In this case, the ramp wall acted as the additional nozzle in the spike nozzle manner for the rocket internal nozzle. One-dimen-sional analysis showed that there was an optimal expansion ratio favorable for the scramjet external nozzle. Subsequently, more complex analysis was partially performed using Method-of-Characteristics based two-dimensional wave model with some novel modifications, which can express the pressure mismatching between the exhaust and the ambient flows. The two-dimensional analysis showed that thrust production within the scramjet external nozzle could become much lower due to impingement of the cowl lip expansion waves resulting from the pressure mismatching. This pressure change also sizably reduced the thrust performance of the rocket spike nozzle. It was, however, also demonstrated that presently analyzed nozzle system has great potential to drastically improve its thrust performance by means of controlling the impingement of the cowl lip expansion waves.
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