Jen Zen Ho , Mohsen Talei , Davy Brouzet , Wai Tong Chung , Pushan Sharma , Matthias Ihme
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引用次数: 0
Abstract
The Flame Surface Density (FSD) model is an affordable combustion model that has been widely used in simulating turbulent premixed flames. In Large Eddy Simulations (LES) with FSD, the combined effect of reaction and diffusion is governed by the Filtered Flame Front Displacement (FFFD) term. While the existing modelling approaches for this term are computationally cost-effective, their predictions still show inconsistencies in certain cases. This study aims to address these inconsistencies by generating Machine Learning (ML) models for the FFFD and FSD terms using the DNS data of a turbulent premixed jet flame. With this approach, the relevance of certain input parameters as well as certain modelling assumptions used for the FFFD term are assessed. Overall, it is found that the resolved curvature term is the most important input parameter to consider and that the resolved progress variable should also be considered in the models. It is shown that the ML models perform significantly better than legacy, algebraic formulations using a priori testing. To further assess the performance of ML, one of the ML models is employed in a a posteriori LES and compared against simulations with the algebraic model. The ML simulation is stable and yields encouraging improvements on key physical parameters regarding the flame length and the FFFD distribution.
Novelty and Significance Statement: This research is of importance because it answers fundamental and practical questions related to the use of combustion modelling approaches, specifically the Flame Surface Density (FSD) and the Filtered Flame Front Displacement (FFFD) models, by means of Machine Learning (ML) algorithms. From a fundamental aspect, we show that two features which are typically not considered as inputs in combustion models, i.e., the progress variable and the resolved curvature, are key to consider for improved predictions of the model, more so than features which are typically used in FSD modelling, i.e., and . From a practical standpoint, we demonstrate a framework to use the developed ML combustion model a posteriori in a LES, without any stability issues. Overall, these findings are key to guide further traditional and ML improvement efforts on combustion models.
火焰表面密度(FSD)模型是一种经济实惠的燃烧模型,被广泛用于模拟湍流预混火焰。在使用 FSD 的大涡流模拟(LES)中,反应和扩散的综合效应受过滤火焰前沿位移(FFFD)项控制。虽然现有的建模方法在计算上具有成本效益,但其预测结果在某些情况下仍存在不一致之处。本研究旨在利用湍流预混合喷射火焰的 DNS 数据,为 FFFD 和 FSD 项生成机器学习 (ML) 模型,从而解决这些不一致问题。通过这种方法,对 FFFD 项所使用的某些输入参数和某些建模假设的相关性进行了评估。总之,研究发现,解析曲率项是需要考虑的最重要的输入参数,而且在模型中还应考虑解析进度变量。先验测试表明,ML 模型的性能明显优于传统的代数公式。为了进一步评估 ML 的性能,在后验 LES 中使用了其中一个 ML 模型,并与代数模型的模拟结果进行了比较。ML 模拟效果稳定,并在火焰长度和 FFFD 分布等关键物理参数方面取得了令人鼓舞的改进:这项研究具有重要意义,因为它通过机器学习(ML)算法,回答了与使用燃烧建模方法(特别是火焰表面密度(FSD)和过滤火焰前沿位移(FFFD)模型)相关的基本问题和实际问题。从根本上讲,我们证明了两个通常不被视为燃烧模型输入的特征,即进度变量和解析曲率,是改进模型预测的关键,比通常用于 FSD 建模的特征,即 uΔ′、Δ 和 |∇c¯|更重要。从实用的角度来看,我们展示了在 LES 中使用所开发的 ML 燃烧后验模型的框架,而不存在任何稳定性问题。总之,这些发现是指导进一步改进燃烧模型的传统和 ML 方法的关键。
期刊介绍:
The Proceedings of the Combustion Institute contains forefront contributions in fundamentals and applications of combustion science. For more than 50 years, the Combustion Institute has served as the peak international society for dissemination of scientific and technical research in the combustion field. In addition to author submissions, the Proceedings of the Combustion Institute includes the Institute''s prestigious invited strategic and topical reviews that represent indispensable resources for emergent research in the field. All papers are subjected to rigorous peer review.
Research papers and invited topical reviews; Reaction Kinetics; Soot, PAH, and other large molecules; Diagnostics; Laminar Flames; Turbulent Flames; Heterogeneous Combustion; Spray and Droplet Combustion; Detonations, Explosions & Supersonic Combustion; Fire Research; Stationary Combustion Systems; IC Engine and Gas Turbine Combustion; New Technology Concepts
The electronic version of Proceedings of the Combustion Institute contains supplemental material such as reaction mechanisms, illustrating movies, and other data.
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