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应用修正的k-ε模型研究超声速H2/Air燃烧
韩省思1, 叶桃红2, 朱旻明3, 陈义良4, 邵文清5
1.中国科学技术大学热科学和能源工程系 安徽合肥230027;2.中国科学技术大学热科学和能源工程系 安徽合肥230028;3.中国科学技术大学热科学和能源工程系 安徽合肥230029;4.中国科学技术大学热科学和能源工程系 安徽合肥230030;5.北京动力机械研究所 北京100074
摘要:
为了研究超声速燃烧中流体可压缩性的影响,对标准k-ε湍流模型进行可压缩性修正(包括结构可压缩性修正和膨胀可压缩性修正两部分)。分别应用标准k-ε模型、修正的k-ε模型和雷诺应力模型(RSM),考虑氢气/空气详细化学反应机理(GR I-M ech 2.11机理,10组分,28基元反应),数值模拟有壁面限制的超声速混合层冷态及热态流场。结果表明:壁面和燃烧对湍流影响都很大;修正模型对冷态以及燃烧场的预测结果优于其它两个;修正模型预测的混合层厚度更薄,燃烧区域更窄,与实验结果吻合地更好。
关键词:  可压缩湍流+  湍流模型  超音速混合层  燃烧  数值仿真
DOI:
分类号:V231.2
基金项目:国家自然科学基金(50506028)
Numerical simulation of supersonic H2/air combustion applingmodified k-ε turbulence model
HAN Xing-si1, YE Tao-hong2, ZHU Min-ming3, CHEN Yi-liang4, SHAO Wen-qing5
1.Dept.of Thermal Science and Energy Engineering,China Univ.of Science and Technology,Hefei 230027,China;2.Dept.of Thermal Science and Energy Engineering,China Univ.of Science and Technology,Hefei 230028,China;3.Dept.of Thermal Science and Energy Engineering,China Univ.of Science and Technology,Hefei 230029,China;4.Dept.of Thermal Science and Energy Engineering,China Univ.of Science and Technology,Hefei 230030,China;5.Beijing Power Machinery Research Inst.,Beijing 100074,China
Abstract:
To study compressibility effect in supersonic combustion,three additional terms(including structured compressibility and dilatational compressibility correction terms) were proposed to improve the standard k-ε turbulence model predictions.Combined comprehensive kinetics mechanics of H2/air(GRI-Mech 2.11,10 components,28 reactions),standard k-ε model,modified k-ε model and Reynolds Stress Model(RSM) were examined by simulations of wall bounded supersonic mixing layers under nonrective and reactive conditions.Comparisons of the results of the three models were made with experimental measurements.Both solid wall and combustion affect turbulence notably. Modified turbulence model gives better predictions than the other two models.Also the new model predicts compressed mixing layers and a narrow reaction zone,which are closer to measurements.
Key words:  Compressible turbulence+  Turbulence model  Supersonic mixing layers  Combustion  Numerical simulation