Dynamics of Thermoacoustic Oscillations in Swirl Stabilized Combustor without and with Porous Inert Media

IF 1.5 Q3 ENGINEERING, CHEMICAL

Journal of Combustion Pub Date : 2022-02-21 DOI:10.1155/2022/5440457

Cody Dowd, Joseph Meadows

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Abstract

Lean premixed (LPM) combustion processes are of increased interest to the gas turbine industry due to their reduction in harmful emissions. These processes are susceptible to thermoacoustic instabilities, which are produced when energy added by an in-phase relationship between unsteady heat release and acoustic pressure is greater than energy dissipated by loss mechanisms. To better study these instabilities, quantitative experimental resolution of heat release is necessary, but it presents a significant challenge. Most combustion systems are partially premixed and therefore will have spatially varying equivalence ratios, resulting in spatially variant heat release rates. For laminar premixed flames, optical diagnostics, such as OH chemiluminescence, are proportionally related to heat release. This is not true for turbulent and partially premixed flames, which are common in commercial combustors. Turbulent eddies effect the strain on flame sheets which alter light emission, such that there is no longer a proportional relationship. In this study, phased, averaged, and spatially varying heat release measurements are performed during a self-excited thermoacoustic instability without and with porous inert media (PIM). Previous studies have shown that PIM can passively mitigate thermoacoustic instabilities, and to the best of the authors’ knowledge, this is the first-time that heat release rates have been quantified for investigating the mechanisms responsible for mitigating instabilities using PIM. Heat release is determined from high-speed PIV and Abel inverted chemiluminescence emission. OH ∗ chemiluminescence is used with a correction factor, computed from a chemical kinetics solver, to calculate heat release. The results and discussion show that along with significant acoustic damping, PIM eliminates the direct path in which heat release regions can be influenced by incoming perturbations, through disruption of the higher energy containing flow structures and improved mixing.

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有无多孔惰性介质时旋流稳定燃烧室热声振荡动力学

精益预混(LPM)燃烧过程是越来越感兴趣的燃气轮机行业，因为他们的有害排放的减少。这些过程容易受到热声不稳定性的影响，当非定常热释放和声压之间的同相关系所增加的能量大于损失机制所消耗的能量时，就会产生热声不稳定性。为了更好地研究这些不稳定性，需要对热释放进行定量的实验解析，但这是一个重大的挑战。大多数燃烧系统是部分预混的，因此会有空间变化的当量比，从而导致空间变化的热释放率。对于层流预混火焰，光学诊断，如OH化学发光，与热释放成比例相关。对于商用燃烧器中常见的湍流和部分预混火焰来说，情况并非如此。湍流涡流影响火焰片上的应变，从而改变光的发射，这样就不再有比例关系。在本研究中，在无多孔惰性介质(PIM)和有多孔惰性介质(PIM)的自激热声不稳定性过程中，进行了相位、平均和空间变化的热释放测量。先前的研究表明，PIM可以被动地减轻热声不稳定性，据作者所知，这是第一次量化热释放率，以研究使用PIM减轻不稳定性的机制。热释放由高速PIV和Abel倒化学发光发射确定。OH *化学发光与从化学动力学解算器计算的校正因子一起使用，以计算热释放。结果和讨论表明，随着显著的声阻尼，PIM消除了热释放区可能受到传入扰动影响的直接路径，通过破坏高能量流结构和改善混合。

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