Yue Zhang, Xuanye Liang, Zixuan Wang, Lijun Yang, Jingxuan Li
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The perturbations led by the ADF propagate along the flame front with a hydrodynamic wavelength, while those driven by the ADA are more likely to periodically squeeze and extend the flame region from the lateral interfaces, leading to a global periodic motion along the longitudinal direction. Both types of perturbation are difficult to propagate downstream due to the damping of flow perturbation. In addition, the flame oscillation patterns driven by the ADA remain the same under different disturbance frequencies. When the diffusion flame is simultaneously subjected to both ADF and ADA, the perturbations of them are mutually coupled at this time, but the oscillation patterns of the flame are dominated by the ADF. Due to the different mechanisms of two disturbances, the oscillation patterns after coupling are related to the disturbance frequency. 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引用次数: 0
摘要
本文通过实验研究了层流扩散火焰在燃料管(ADF)和环绕气流(ADA)受到声学干扰时的动态响应。通过保持 ADF 和 ADA 的速度扰动振幅相同,在不同频率下进行了实验。利用高速强化照相机测量的化学发光数据(CH* 和 OH*)和马赫-泽恩德干涉仪(MZI)测量的密度扰动来详细识别火焰的动态响应。结果表明,ADF 和 ADA 都能通过刺激燃料流中的扰动引起火焰振荡,但方式不同。由 ADF 引发的扰动以流体动力波长沿火焰前沿传播,而由 ADA 引发的扰动则更有可能从横向界面周期性地挤压和扩展火焰区域,从而导致沿纵向的整体周期性运动。由于流动扰动的阻尼作用,这两种扰动都很难向下游传播。此外,在不同的扰动频率下,由 ADA 驱动的火焰振荡模式保持不变。当扩散火焰同时受到 ADF 和 ADA 扰动时,此时两者的扰动是相互耦合的,但火焰的振荡模式是由 ADF 主导的。由于两种扰动的机理不同,耦合后的振荡模式与扰动频率有关。根据上述结果,提出了受 ADF 和 ADA 影响的扩散火焰振荡模型。
Comparisons of the dynamic responses of diffusion flames subjected to acoustic disturbances in the fuel and air lines
In this paper, the dynamic responses of a laminar diffusion flame subjected to acoustic disturbances in the fuel line (ADF) and surrounded air flow (ADA) were experimentally studied. Experiments were conducted at different frequencies by keeping the velocity perturbation amplitudes for both ADF and ADA the same. Chemiluminescence data (CH* and OH*) measured by an intensified high-speed camera and density perturbations measured by a Mach–Zehnder interferometer (MZI) were used to identify the flame dynamic responses in detail. Results show that both ADF and ADA can induce flame oscillations by stimulating disturbances in the fuel flow but in different manners. The perturbations led by the ADF propagate along the flame front with a hydrodynamic wavelength, while those driven by the ADA are more likely to periodically squeeze and extend the flame region from the lateral interfaces, leading to a global periodic motion along the longitudinal direction. Both types of perturbation are difficult to propagate downstream due to the damping of flow perturbation. In addition, the flame oscillation patterns driven by the ADA remain the same under different disturbance frequencies. When the diffusion flame is simultaneously subjected to both ADF and ADA, the perturbations of them are mutually coupled at this time, but the oscillation patterns of the flame are dominated by the ADF. Due to the different mechanisms of two disturbances, the oscillation patterns after coupling are related to the disturbance frequency. Based on the above results, a model of the diffusion flame oscillation subjected to ADF and ADA was proposed.
期刊介绍:
The Proceedings of the Combustion Institute contains forefront contributions in fundamentals and applications of combustion science. For more than 50 years, the Combustion Institute has served as the peak international society for dissemination of scientific and technical research in the combustion field. In addition to author submissions, the Proceedings of the Combustion Institute includes the Institute''s prestigious invited strategic and topical reviews that represent indispensable resources for emergent research in the field. All papers are subjected to rigorous peer review.
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