Effects of Temperature Variation of Flamelet Library on Supersonic Flamelet Modeling

doi:10.13675/j.cnki.tjjs.190618

Journal of Propulsion Technology ›› 2020, Vol. 41 ›› Issue (12): 2808-2814.DOI: 10.13675/j.cnki.tjjs.190618

• Combustion, Heat and Mass Transfer • Previous Articles Next Articles

Effects of Temperature Variation of Flamelet Library on Supersonic Flamelet Modeling

1.Northwest Engineering Corporation Limited，Power China，Xi’an 710065，China;2.School of Aerospace，Tsinghua University，Beijing 100084，China

Published:2021-08-15

建库温度在超声速火焰面模型中的影响

牛东圣^1,2，侯凌云²

1.中国电建集团西北勘测设计研究院有限公司，陕西西安 710065;2.清华大学航天航空学院，北京 100084

作者简介:牛东圣，博士，研究领域为超声速燃烧数值模拟。E-mail：niudongsheng@hotmail.com
基金资助:
国家自然科学基金（91641114）。

Abstract

Abstract: In the flametlet modeling， the accuracy of flamelet library has a significant impact on the prediction precision of the turbulent combustion flow field. In order to study the effects of temperature variation of flamelet library on supersonic flamelet modeling， the oxidizer temperature was added as a control parameter during the flamelet library generation， and a lookup method to determine the oxidizer temperature from the local temperature for any node in the flow field was proposed. Taken the DLR supersonic combustor as test case and kerosene as fuel， the flamelet library was generated under five different temperature levels， and the effects of temperature on both the one-dimensional flamelet and two-dimensional turbulent reactive flow field were investigated. Results show that the temperature variation has fairly remarkable effects on the temperature and species distributions in one-dimensional flamelet database. Taking the temperature variation into account can help to improve the prediction results of supersonic turbulent reactive flow field.

Key words: Supersonic combustion;Numerical simulation;Flamelet model;Flamelet library;Oxidizer temperature

摘要： 在火焰面模型中，数据库计算结果的准确程度对之后湍流燃烧流场的预测精度有重要影响。为了研究建库温度在超声速火焰面模型中的影响作用，在建立火焰面数据库时增加了建库氧化剂温度这一维度，并提出了一种由流场各点平均温度确定其对应的建库氧化剂温度的查表方法。针对DLR结构的超声速燃烧室，以煤油作为燃料，在五个温度级别条件下建立火焰面数据库，考察了建库温度对一维火焰面数据库以及二维燃烧流场计算结果的影响。研究结果表明，建库温度对一维火焰面的温度和组分分布有较为明显的影响，增加建库温度这一查表维度有助于改善超声速湍流燃烧流场的预测精度。

关键词: 超声速燃烧;数值模拟;火焰面模型;火焰面数据库;氧化剂温度

NIU Dong-sheng^1,2, HOU Ling-yun². Effects of Temperature Variation of Flamelet Library on Supersonic Flamelet Modeling[J]. Journal of Propulsion Technology, 2020, 41(12): 2808-2814.

牛东圣，侯凌云. 建库温度在超声速火焰面模型中的影响[J]. 推进技术, 2020, 41(12): 2808-2814.

References

[1] Gao Z X， Jiang C W， Lee C H. Representative Interactive Flamelet Model and Flamelet/Progress Variable Model for Supersonic Combustion Flows［J］. Proceedings of the Combustion Institute， 2017， 36（2）： 2937-2946.
[2] Zhao G Y， Sun M B， Wang H B， et al. Investigation of Combustion Characteristics in a Scramjet Combustor Using a Modified Flamelet Model［J］. Acta Astronautica， 2018， 148： 32-40.
[3] Aravind S， Kumar R. Supersonic Combustion of Hydrogen Using an Improved Strut Injection Scheme［J］. International Journal of Hydrogen Energy， 2019， 44（12）： 6257-6270.
[4] 纪鹏飞，罗雨，陈兵，等. 煤油燃料超声速燃烧室火焰面模型应用探究［J］. 推进技术， 2017， 38（6）： 1201-1208.
[5] 赵国焱，孙明波，吴锦水. 基于不同PDF的超声速扩散燃烧火焰面模型对比［J］. 推进技术， 2015， 36（2）： 232-237.
[6] Peters N. Turbulent Combustion［M］. Cambridge： Cambridge University Press， 2000.
[7] Zhao G Y， Sun M B， Wu J S， et al. A Flamelet Model for Supersonic Non-Premixed Combustion with Pressure Variation［J］. Modern Physics Letters B， 2015， 29（21）.
[8] Ladeinde F， Lou Z P， Li W H. The Effects of Pressure Treatment on the Flamelet Modeling of Supersonic Combustion［J］. Combustion and Flame， 2019， 204： 414-429.
[9] 范周琴. 超声速湍流燃烧火焰面模型判别及应用研究［D］. 长沙：国防科学技术大学， 2011.
[10] 孙明波，范周琴，梁剑寒，等. 部分预混超声速燃烧火焰面模式研究综述［J］. 力学进展， 2010， 40（6）： 634-641.
[11] Oevermann M. Numerical Investigation of Turbulent Hydrogen Combustion in a Scramjet Using Flamelet Modeling［J］. Aerospace Science and Technology， 2000， 4： 463-480.
[12] Menter F R. Two-Equation Eddy-Viscosity Turbulence Models for Engineering Applications［J］. AIAA Journal， 1994， 32（8）： 1598-1605.
[13] Jones W P， Whitelaw J H. Calculation Methods for Reacting Turbulent Flows： A Review［J］. Combustion and Flame， 1982， 48： 1-26.
[14] 张涵信. 计算流体力学-差分方法的原理和应用［M］. 北京：国防工业出版社， 2003.
[15] Hou L Y， Niu D S， Ren Z Y. Partially Premixed Flamelet Modeling in a Hydrogen-Fueled Supersonic Combustor［J］. International Journal of Hydrogen Energy， 2014， 39（17）： 9497-9504.
[16] 牛东圣，侯凌云. 乙烯超声速燃烧部分预混火焰面模型数值研究［J］. 推进技术， 2015， 36（9）： 1376-1381.
[17] Waidmann W， Alff F， Bohm M， et al. Supersonic Combustion of Hydrogen/Air in a Scramjet Combustion Chamber［J］. Space Technology， 1995， 15（6）： 421-429.
[18] Guerra R， Waidmann W， Laible C. An Experimental Investigation of the Combustion of a Hydrogen Jet Injected Parallel in a Supersonic Air Stream［R］. AIAA 91-5102.
[19] Pitsch H. FlameMaster： a C++ Computer Program for 0D Combustion and 1D Laminar Flame Calculations［D］. Aachen： RWTH Aachen University， 1998.

Effects of Temperature Variation of Flamelet Library on Supersonic Flamelet Modeling

建库温度在超声速火焰面模型中的影响

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