自燃性喷射火焰从传统燃烧到 MILD 燃烧的制度转换动力学

IF 5 Q2 ENERGY & FUELS
Aravind Ramachandran , Abinash Sahoo , Venkateswaran Narayanaswamy , Kevin M. Lyons
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引用次数: 0

摘要

研究了丙烷、乙烯和乙烯-丙烷混合物作为燃料,在燃烧产物的热稀释共流中喷射火焰的湍流燃烧,其喷射雷诺数在一定范围内。研究发现,火焰从传统的自燃过渡到中度或高强度低氧稀释(MILD)燃烧,其特点是火焰几乎不可见。所研究的火焰在低射流速度时发光,在较高射流速度时变成 MILD。甲醛(CH2O)的平面激光诱导荧光(PLIF)是碳氢化合物燃烧中的一个关键中间物种,它与 CH* 化学发光成像和瑞利散射相结合来研究这一现象。研究发现,向 MILD 燃烧的过渡伴随着甲醛区域的扩大,这表明低温反应区的范围更广。随着过渡的临近,还观察到化学发光前沿出现了空洞。这些孔洞的位置和结构与火焰中的甲醛区域之间存在对应关系。这些区域被认为是过渡到完全 MILD 火焰之前的特征。换句话说,向 MILD 燃烧的过渡始于局部,然后 MILD 区域扩散到吞噬整个燃烧混合物。对标量梯度进行了成像,以进一步揭示产生 MILD 开始的局部湍流/化学相互作用。测得的标量梯度与化学动力学模拟中获得的化学计量混合物分数处的标量梯度一致,而其他位置的标量梯度要大一个数量级;这表明 MILD 燃烧的起始点发生在化学计量区域附近。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Dynamics of regime transition of autoignitive jet flames from conventional to MILD combustion

Turbulent combustion of jet flames in a hot diluted coflow of combustion products has been studied across a range of jet Reynolds numbers for propane, ethylene, and an ethylene-propane blend as fuels. The study revealed a transition from conventional autoignitive combustion to a regime of Moderate or Intense Low-oxygen Dilution (MILD) combustion, which is characterized by a nearly invisible flame. The flames studied are luminous at low jet velocities and become MILD at higher jet velocities. Planar Laser-Induced Fluorescence (PLIF) of formaldehyde (CH2O), a key intermediate species in hydrocarbon combustion, is combined with CH*-chemiluminescence imaging and Rayleigh scattering to investigate the phenomena. The transition to MILD combustion is found to accompany a broadening of the formaldehyde region, indicating a broader low-temperature reaction zone. As the transition is approached, the appearance of holes in the chemiluminescent front is also observed. Correspondence between the location and structure of these holes with regions of formaldehyde in the flame are illustrated. These regions are proposed to be signatures that precede the transition to a fully MILD flame. In other words, the transition to MILD combustion begins at a local level and the MILD region spreads to engulf the entire combusting mixture. Scalar gradients were imaged to further unravel the local turbulence/chemistry interactions that yield the MILD inception. The measured scalar gradients were found to be commensurate with scalar gradients obtained from chemical kinetic simulations at the stoichiometric mixture fractions, while being an order of magnitude larger at other locations; this suggests that the inception of MILD combustion occurs near the stoichiometric region.

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