Experimental investigation of flame-holding system for the suppression of ramjet rumble

Eugene Lubarsky, Yeshayahou Levy
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引用次数: 5

Abstract

Combustion instabilities often occur in the liquid-fueled ramjet combustors using bluff body or sudden expansion for stabilization. From a practical point of view, the most severe oscillations are at the 100–500-Hz range. This low-frequency rumble is generally characterized by longitudinal acoustic oscillations. It has been shown that combustion oscillations can be stabilized by controlled periodic addition of secondary fuel, usually in the form of premixed gas fuel. The main idea of the present study is to use the air from the oscillating flow of the unstable combustor for the atomization and distribution of part of the main liquid fuel to obtain the required oscillating phase-shifted heat addition for stabilization. The effervescent spray injection, at relatively low operating pressure, was investigated as a model for pressure-dependent atomizer. A special laser light sheet system was used to obtain an integral indication of spray oscillation. Phase Doppler anemometry measurements were performed to determine the droplet velocity and droplet diameter oscillations with the different phase shifts respect to the oscillations of the atomizing air. A special diagnostic system based on the chemiluminescence of CH radicals is used for direct determination of heat addition oscillations.

The measurements revealed very fast response of the combined effervescent atomizer and flame-holding configuration. Response time between pressure perturbations and the heat release, of the order of 1–3 ms, as well as the limited spatial distribution of the control heat release was achieved. These characteristics proved the system's ability to serve as a passive control unit for suppressing low-frequency combustion oscillations in unstable combustors.

抑制冲压发动机轰鸣的火焰保持系统实验研究
采用钝体或突然膨胀稳定化的液体燃料冲压发动机燃烧室经常发生燃烧不稳定现象。从实际的角度来看,最严重的振荡是在100 - 500赫兹范围内。这种低频隆隆声通常以纵向声学振荡为特征。研究表明,通过控制周期性地添加二次燃料(通常以预混气体燃料的形式),可以稳定燃烧振荡。本研究的主要思想是利用不稳定燃烧室振荡气流中的空气对部分主液体燃料进行雾化和分配,以获得稳定所需的振荡相移热添加量。研究了在较低工作压力下的泡腾式喷雾喷射模型。采用一种特殊的激光光片系统来获得喷雾振荡的积分指示。通过相位多普勒风速测量,确定了液滴速度和液滴直径随不同相移相对于雾化空气振荡的变化规律。一种基于CH自由基化学发光的特殊诊断系统用于直接测定热加成振荡。测量结果表明,气泡雾化器和火焰保持结构的组合响应速度非常快。得到了压力扰动与热释放之间的响应时间为1 ~ 3 ms,以及控制热释放的有限空间分布。这些特性证明了该系统作为抑制不稳定燃烧室低频燃烧振荡的被动控制单元的能力。
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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