纵向燃烧不稳定性低阶模型的驱动机理

IF 1.7 4区工程技术 Q2 ENGINEERING, AEROSPACE

Journal of Propulsion and Power Pub Date : 2023-09-01 DOI:10.2514/1.b39048

Simone D’Alessandro, Maria Luisa Frezzotti, Bernardo Favini, Francesco Nasuti

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引用次数: 0

摘要

文献中的几个测试案例表明，喷油器动力学可以驱动横向和纵向高频燃烧不稳定性。在这些情况下，压力振荡导致推进剂质量流量的波动，从而产生脉冲热释放。这一基本机制是目前工作的重点，目的是将这种效应包括在适合研究纵向燃烧不稳定性的欧拉方程的准一维非线性模型中。特别是，注入动力学是通过一个简化的公式来表示的，这是所提出的响应函数的核心。分析还讨论了燃烧效率对极限循环的主要特性(频率和振幅)的影响。在考虑三种不同的几何构型和不同氧化柱长度的情况下，将所得模型的准一维模拟结果与文献中已有的连续变共振燃烧室的实验数据进行了比较。所提出的公式能够合理地再现不稳定行为，并提供一个简单的模型来解释导致不稳定运行时平均燃烧效率低的机制。

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Driving Mechanisms in Low-Order Modeling of Longitudinal Combustion Instability

Several test cases in the literature have shown that both transverse and longitudinal high-frequency combustion instability can be driven by the injector dynamics. In these cases, pressure oscillations result in fluctuations in propellant mass flow rate, which yields pulsing heat release. This fundamental mechanism is the focus of the present work, with the aim of including this effect in a quasi-1D nonlinear model of Euler equations suited to studies of longitudinal combustion instability. In particular, the injection dynamics is represented through a simplified formulation, which is the core of the proposed response function. The analysis also addresses the influence of combustion efficiency on the main characteristics of the resulting limit cycle (frequency and amplitude). The obtained model is tested comparing the quasi-1D simulations against the experimental data of the continuously variable resonance combustor available in the literature, considering three different geometrical configurations, with different lengths of the oxidizer post. The proposed formulation is capable of reasonably reproducing the unstable behavior, as well as providing a simple model that explains the mechanism that leads to a low average combustion efficiency during unstable operation.

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来源期刊

Journal of Propulsion and Power 工程技术-工程：宇航

CiteScore

4.20

自引率

21.10%

发文量

审稿时长

6.5 months

期刊介绍： This Journal is devoted to the advancement of the science and technology of aerospace propulsion and power through the dissemination of original archival papers contributing to advancements in airbreathing, electric, and advanced propulsion; solid and liquid rockets; fuels and propellants; power generation and conversion for aerospace vehicles; and the application of aerospace science and technology to terrestrial energy devices and systems. It is intended to provide readers of the Journal, with primary interests in propulsion and power, access to papers spanning the range from research through development to applications. Papers in these disciplines and the sciences of combustion, fluid mechanics, and solid mechanics as directly related to propulsion and power are solicited.