Predicting the ignition sequences in a separated stratified swirling spray flame with stochastic flame particle tracking

IF 1.1 Q4 ENGINEERING, MECHANICAL Journal of the Global Power and Propulsion Society Pub Date : 2022-10-12 DOI:10.33737/jgpps/153495
Qing Xie, Siheng Yang, Hao Cheng, Chi Zhang, Zhuyin Ren
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Abstract

Stochastic flame particle tracking in conjunction with non-reacting combustor simulations can offer insights into the ignition processes and facilitate the combustor optimization. In this study, this approach is employed to simulate the ignition sequences in a separated dual-swirl spray flame, in which the newly proposed pairwise mixing-reaction model is used to account for the mass and energy transfer between the flame particle and the surrounding shell layer. Based on the flame particle temperature, the particle state can be classified in to burnt, hot gas, and extinguished. The additional state of hot gas is introduced to allow the flame particles with high temperature to survive from nonflammable region and then potentially to ignite the nearby favourable regions. The simulations of the separated stratified swirl spray flame reveal two different ignition pathways for flame stabilization. The first showed that some flame particles from the spark would directly enter the main recirculation zone resulting from the velocity randomness and then ignite both sides of the combustor simultaneously. The second showed that flame particles from the spark would ignite the traversed regions following the swirl motion inside the combustor. The predicted ignition sequences were compared with the evolution of flame morphology recorded by high-speed imaging from experiments, showing qualitative agreement.
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用随机火焰粒子跟踪方法预测分层旋转喷射火焰的点火顺序
随机火焰粒子跟踪与非反应燃烧室模拟相结合,可以深入了解燃烧过程,促进燃烧室优化。在本研究中,采用该方法模拟分离双旋喷射火焰的点火序列,其中采用新提出的两两混合反应模型来考虑火焰颗粒与周围壳层之间的质量和能量传递。根据火焰颗粒温度,颗粒状态可分为燃烧状态、热气体状态和熄灭状态。引入热气体的附加状态以允许具有高温的火焰颗粒从不可燃区域存活,然后可能点燃附近的有利区域。通过对分层旋流喷雾火焰的模拟,揭示了两种不同的火焰稳定化点火途径。首先,由于速度的随机性,火花产生的部分火焰颗粒会直接进入主再循环区,并同时点燃燃烧室两侧。第二种方法表明,火花产生的火焰粒子会点燃燃烧室内旋转运动后穿过的区域。将预测的点火序列与实验中高速成像记录的火焰形态演变进行了比较,得到了定性一致的结果。
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来源期刊
Journal of the Global Power and Propulsion Society
Journal of the Global Power and Propulsion Society Engineering-Industrial and Manufacturing Engineering
CiteScore
2.10
自引率
0.00%
发文量
21
审稿时长
8 weeks
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