MILD combustion stabilization issues through the analysis of hysteresis behaviors: The case of new energy carriers

P. Sabia , M.V. Manna , F. Mauss , R. Ragucci
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Abstract

MILD combustion processes are renewed to reveal a strong resilience to extinction phenomena and/or instabilities, whereas the oxidation process is stabilized trough ignition phenomena. Under MILD conditions, igni-diffusive and/or perfectly mixed kernels, forming during the mixing process between hot products and fresh reactants, are so much diluted and pre-heated to escape classical feed-back flammable flames stabilization mechanisms, while ignition and extinction events merge in a unique condition through “anhysteretic” behaviors. So far, considering methane as reference fuel, it has been largely demonstrated the mentioned “anhysteretic” condition is very conservative and defines a sub-domain of MILD combustion processes, following Cavaliere and de Joannon's definition. Furthermore, the coincidence of ignition and extinction phenomena can occur also preserving hysteresis phenomena. In turns, this condition strongly enlarges the stabilization domain of MILD combustion processes, starting from the upper branch of the hysteresis behaviors to the real extinction, with characteristic unstable loci to consider as further/last opportunity to promote stable operative conditions through the formation of local thermo-kinetic conditions in the combustion chamber during hot products/fresh reactants mixing process (injection configuration/burner design), or by forced ignition events. The hysteresis behaviors of renewable/alternative fuels, relevant within the decarbonization policies of several energy sectors, are thoroughly discussed under MILD conditions through numerical studies in model reactors in order to shed light on common and/or different features, and outline practical rules towards the definition of stable MILD combustion domains. Results show that, as MILD combustion is a chemical kinetics-driven processes, stability issues have to be discussed in relation to fuel nature, albeit with common behavior can be derived. The coincidence between extinction/ignition phenomena is reached for extremely diluted conditions, already ascribable to MILD combustion conditions, thus defining a small sub-domain of the process. This condition can be reached through “hysteretic” or “anhysteretic” behaviors.

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通过分析滞后行为解决 MILD 燃烧稳定问题:新能源载体案例
MILD 燃烧过程经过更新后,对熄灭现象和/或不稳定性具有很强的适应能力,而氧化过程则通过点火现象得到稳定。在 MILD 条件下,热产物和新鲜反应物在混合过程中形成的点状扩散和/或完全混合的内核会被大量稀释和预热,从而逃过经典的回馈式易燃火焰稳定机制,而点燃和熄灭事件则会通过 "无滞后性 "行为在独特的条件下合并。迄今为止,以甲烷为参考燃料的研究已在很大程度上证明了上述 "滞燃 "条件是非常保守的,并按照卡瓦列雷和德琼农的定义定义了 MILD 燃烧过程的一个子域。此外,点火和熄灭现象的同时发生也会保留滞后现象。反过来,这一条件又极大地扩展了 MILD 燃烧过程的稳定域,从滞后现象的上部分支开始到真正的熄灭,具有特征性的不稳定位置可被视为进一步/最后的机会,通过在热产品/新鲜反应物混合过程(喷射配置/燃烧器设计)中在燃烧室中形成局部热动能条件,或通过强制点火事件来促进稳定的运行条件。通过在模型反应器中进行数值研究,深入讨论了在 MILD 条件下与多个能源部门的去碳化政策相关的可再生/替代燃料的滞后行为,以揭示共同和/或不同的特征,并概述了定义稳定 MILD 燃烧域的实用规则。结果表明,由于 MILD 燃烧是化学动力学驱动的过程,因此必须结合燃料性质讨论稳定性问题,尽管可以得出共同的行为。在极度稀释的条件下,熄灭/点火现象会重合,这已经可以归结为 MILD 燃烧条件,从而定义了该过程的一个小的子域。这种情况可以通过 "滞后 "或 "非滞后 "行为达到。
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