用过滤制表化学法模拟湍流喷射火焰的大涡

IF 1.5 Q3 ENGINEERING, CHEMICAL
Adrien Chatelier, B. Fiorina, V. Moureau, N. Bertier
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引用次数: 10

摘要

本文介绍了用液体正庚烷和空气供气的无约束CORIA鲁昂喷雾燃烧器的大涡模拟。紊流燃烧模型是基于过滤表化学模型的LES (F-TACLES)形式,旨在捕捉紊流分层火焰的传播速度。最初致力于气体燃烧,过滤小火焰模型首次在湍流喷雾火焰配置中受到挑战。使用两个网格。最好的网格,其中火焰厚度和起皱都解决了,旨在挑战化学制表程序。相反,粗网格不允许火焰厚度的完全分辨率,并表现出亚网格尺度火焰起皱的显着未解决的贡献。两种LES解决方案都与实验数据进行了广泛的比较。在非反应条件和反应条件下,两种模拟都能很好地捕捉到流动和喷雾的空气动力学特性。更有趣的是,LES准确地预测了细网格和粗网格条件下的火焰起飞高度。验证了该建模方法能够在两相流环境和具有实际应用代表性的网格条件下捕获过滤后的湍流火焰传播速度。观察到的液滴温度的差异似乎与蒸发模式的假设有关。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Large Eddy Simulation of a Turbulent Spray Jet Flame Using Filtered Tabulated Chemistry
This work presents Large Eddy Simulations of the unconfined CORIA Rouen Spray Burner, fed with liquid n-heptane and air. Turbulent combustion modeling is based on the Filtered TAbulated Chemistry model for LES (F-TACLES) formalism, designed to capture the propagation speed of turbulent stratified flames. Initially dedicated to gaseous combustion, the filtered flamelet model is challenged for the first time in a turbulent spray flame configuration. Two meshes are employed. The finest grid, where both flame thickness and wrinkling are resolved, aims to challenge the chemistry tabulation procedure. At the opposite the coarse mesh does not allow full resolution of the flame thickness and exhibits significant unresolved contributions of subgrid scale flame wrinkling. Both LES solutions are extensively compared against experimental data. For both nonreacting and reacting conditions, the flow and spray aerodynamical properties are well captured by the two simulations. More interesting, the LES predicts accurately the flame lift-off height for both fine and coarse grid conditions. It confirms that the modeling methodology is able to capture the filtered turbulent flame propagation speed in a two-phase flow environment and within grid conditions representative of practical applications. Differences, observed for the droplet temperature, seem related to the evaporation model assumptions.
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来源期刊
Journal of Combustion
Journal of Combustion ENGINEERING, CHEMICAL-
CiteScore
2.00
自引率
28.60%
发文量
8
审稿时长
20 weeks
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