Investigations on Complex Acoustic Modes of Rocket Engines Combustion Chambers for Damping Allocation

IF 0.9 Q3 ENGINEERING, AEROSPACE
Gustavo Paulinelli Guimarães, R. Pirk, C. Souto, L. Góes
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引用次数: 1

Abstract

Combustion instability can severely impair the operation of many kinds of combustion engines. Acoustic resonators are widely used to suppress the pressure oscillations caused by the coupling between the combustion process and the combustion chamber acoustic modes. Combustion chambers with subsonic flow in its inlets and outlets, like gas turbine combustors, exhibit some acoustical damping due to the presence of openings. In such chambers, the acoustic modes are complex. In a complex mode, the antinode regions can be shifted from its position in the corresponding real mode. In this work an experimental acoustic modal analysis of a cavity with an opening was performed. Acoustic frequency response functions were obtained by using a volume acceleration source, a microphone and a data acquisition system. The PolyMAX algorithm was used to estimate longitudinal modes in its real and complex versions. A comparison was performed and the results show that, for some modes, the antinode region placement could change reasonably. This suggests that the use of complex modes for location of antinode regions provides more accurate results and consequently could be a better way to identify positions, where resonators provide maximum damping in order to minimize combustion instability in subsonic combustion chambers.
用于阻尼分配的火箭发动机燃烧室复杂声学模式研究
燃烧不稳定性会严重损害许多类型的内燃机的运行。声学谐振器被广泛用于抑制由燃烧过程和燃烧室声学模式之间的耦合引起的压力振荡。在其入口和出口具有亚音速流动的燃烧室,如燃气轮机燃烧器,由于开口的存在,表现出一定的声学阻尼。在这样的腔室中,声学模式是复杂的。在复模中,波腹区域可以从其在相应实模中的位置偏移。在这项工作中,对具有开口的空腔进行了实验声学模态分析。通过使用体积加速度源、麦克风和数据采集系统获得了声学频率响应函数。PolyMAX算法用于估计真实和复杂版本的纵向模式。比较结果表明,对于某些模式,波腹区域的位置可以合理地改变。这表明,使用复杂模式来定位波腹区域提供了更准确的结果,因此可能是识别位置的更好方法,其中谐振器提供最大阻尼,以最大限度地减少亚音速燃烧室中的燃烧不稳定性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
2.00
自引率
0.00%
发文量
16
审稿时长
20 weeks
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