预混合\({\text{NH}}_{3}\) / \({\text{H}}_{2}\)燃烧CFD湍流模型对旋流稳定燃烧器排放和火焰特性的影响

IF 2 3区工程技术 Q3 MECHANICS

Flow, Turbulence and Combustion Pub Date : 2025-02-08 DOI:10.1007/s10494-025-00638-7

Luca Mazzotta, Rachele Lamioni, Giuliano Agati, Adriano Evangelisti, Franco Rispoli, Agustin Valera-Medina, Domenico Borello

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引用次数: 0

摘要

氨燃烧作为一种可行的替代传统化石燃料的方法正受到人们的关注，因为它对环境的影响小，而且可以作为氢和能源的载体。本研究采用计算流体动力学（CFD）模拟，比较了不同湍流模型在旋流稳定燃烧器内的氨/氢预混燃烧。主要目的是确定最佳湍流模型，以准确预测氨/氢燃料混合物的流动动力学、燃烧行为和排放概况。评估的湍流模型有大涡模拟（LES）、Realizable k- \(\epsilon\)、重整化组（RNG） k- \(\epsilon\)、k- \(\omega\) SST和雷诺应力模型（RSM）。在LES方面，进一步比较了两个子网格模型（Smagorinsky-Lilly和WALE）。火焰生成歧管（FGM）方法采用了详细的化学方案，考虑了所有\(\hbox {NO}_x\)反应。为了改进\(\hbox {NO}_x\)排放的预测，加入了NO和\(\hbox {NO}_2\)的附加标量输运方程。这种方法的目的是在计算效率和详细化学模型所期望的准确性之间取得平衡。验证是用卡迪夫大学燃气轮机研究中心的涡流燃烧器完成的。结果表明，所有湍流模型都能准确地捕捉到火焰在排气温度和轴向速度方面的特征，在再循环区域差异较小，其中只有RSM模型能像LES模拟那样预测速度趋势，而其他RANS模型的差异至少为7 m/s。在火焰区，LES达到的温度比其他模型高100 K。LES模拟可以预测发射值，误差小于10 \(\%\)。此外，从RANS模拟中得出的与排放有关的误差不可忽略，将\(\hbox {NO}_x\)排放量低估了约35 \(\%\)。然而，与其他RANS模型相比，RSM模型产生的结果更接近高保真LES模型，特别是在火焰厚度和排放方面。得出结论，为了得到合理的结果，必须进行非定常分析。

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On the Impact of CFD Turbulence Models for Premixed \({\text{NH}}_{3}\)/\({\text{H}}_{2}\) Combustion on Emissions and Flame Characteristics in a Swirl-Stabilized Burner

Ammonia combustion is gaining interest as a feasible alternative to traditional fossil fuels because of to the low environmental impact and as hydrogen and energy carrier. This study used Computational Fluid Dynamics (CFD) simulations to compare various turbulence models for premixed ammonia/hydrogen combustion in a swirl-stabilized burner. The primary aim was to identify the best turbulence model for accurately predicting the flow dynamics, combustion behaviour, and emissions profiles of ammonia/hydrogen fuel blends. The turbulence models evaluated were Large Eddy Simulation (LES), Realizable k-\(\epsilon\), Renormalization Group (RNG) k-\(\epsilon\), k-\(\omega\) SST, and Reynolds Stress Model (RSM). On the LES side, a further comparison of two subgrid models (Smagorinsky-Lilly and WALE) was investigated. The Flamelet Generated Manifold (FGM) method was utilized with a detailed chemistry scheme taking into consideration all \(\hbox {NO}_x\) reactions. To improve the prediction of \(\hbox {NO}_x\) emissions, additional scalar transport equations for NO and \(\hbox {NO}_2\) were included. This methodology aimed to be a balance between computational efficiency and the accuracy expected of detailed chemistry models. Validation was done with a swirl burner from Cardiff University’s Gas Turbine Research Centre. Results showed that all turbulence models accurately captured flame characteristics in terms of exhaust temperature and axial velocity with minor differences in the recirculation zones, where only the RSM model can predict the velocity trend as the LES simulation while other RANS models differ by at least 7 m/s. The temperature reached by the LES resulted 100 K higher than the other models in the flame zone. LES simulation can predict the emission value with an error of less than 10\(\%\). Moreover, the error related to emissions derived from the RANS simulations was not negligible, underestimating \(\hbox {NO}_x\) emissions by about 35\(\%\). However, RSM model produced results that were closer to those derived from the high-fidelity LES when compared to the others RANS models, particularly in terms of flame thickness and emissions. It was concluded that it is mandatory to perform an unsteady analysis to reach reasonable results.

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来源期刊

Flow, Turbulence and Combustion 工程技术-力学

CiteScore

5.70

自引率

8.30%

发文量

审稿时长

2 months

期刊介绍： Flow, Turbulence and Combustion provides a global forum for the publication of original and innovative research results that contribute to the solution of fundamental and applied problems encountered in single-phase, multi-phase and reacting flows, in both idealized and real systems. The scope of coverage encompasses topics in fluid dynamics, scalar transport, multi-physics interactions and flow control. From time to time the journal publishes Special or Theme Issues featuring invited articles. Contributions may report research that falls within the broad spectrum of analytical, computational and experimental methods. This includes research conducted in academia, industry and a variety of environmental and geophysical sectors. Turbulence, transition and associated phenomena are expected to play a significant role in the majority of studies reported, although non-turbulent flows, typical of those in micro-devices, would be regarded as falling within the scope covered. The emphasis is on originality, timeliness, quality and thematic fit, as exemplified by the title of the journal and the qualifications described above. Relevance to real-world problems and industrial applications are regarded as strengths.