Volume 18, Issue 7 (2018)                   Modares Mechanical Engineering 2018, 18(7): 20-29 | Back to browse issues page

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Fasihi F, Noori S, Eidi Attarzadeh M. Investigation of radiative heat transfer effect on the SM1 flame structure with steady flamelet method. Modares Mechanical Engineering. 2018; 18 (7) :20-29
URL: http://journals.modares.ac.ir/article-15-13841-en.html
1- Aerospace engineering, Aerospace faculty, Amirkabir University of Technology, Tehran, Iran
2- Aerospace Engineering department, Aerospace Engineering faculty, Amirkabir University of Technology, Tehran, Iran
3- Aerospace Engineering, Aerospace Engineering Faculty, Amirkabir University of Technology, Tehran, Iran
Abstract:   (4028 Views)
Abstract Thermal radiation plays a key role in the heat transfer between the flame and its surroundings. It is essential to provide a reliable method for measurement of flame radiation in the combustion study. Also, it is challenging to measure the radiation flux from the flame in the chamber due to the effect of the walls. The radiation emitted from the walls and the reflection of the flame radiation from the walls interferes with the measurement of the flame radiation. High temperature or high reflection walls can increase the error in the measurement of flame radiation. In this paper, various parameters affecting the flame radiation have been investigated. These studies are based on the wall incident radiation and the wall radiation heat flux. To calculate the flame radiation, a theoretical method is presented which is compared with the CFD simulation results to confirm its correctness. To simulate the flame SM1 of the University of Sydney, a steady flamelet combustion model has been used with the k-ε modified turbulence model. Due to the low optical thickness of the model, the DO radiation model is used to simulate CFD. The CFD results are in good agreement with theoretical results, and the estimation of flame emission are accurately acceptable. The results show that the flame radiation differs from the wall radiation by more than 25%, when the wall radiation coefficient will be smaller than 0.8 or the wall temperature will be more than 330k.
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Article Type: Research Article |
Received: 2017/12/21 | Accepted: 2018/09/25 | Published: 2018/09/25

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