李军, 栗智宇, 李志刚, 张垲垣, 宋立明
收稿日期:
2020-04-20
修回日期:
2020-06-16
发布日期:
2020-07-27
通讯作者:
李军
E-mail:junli@mail.xjtu.edu.cn
基金资助:
LI Jun, LI Zhiyu, LI Zhigang, ZHANG Kaiyuan, SONG Liming
Received:
2020-04-20
Revised:
2020-06-16
Published:
2020-07-27
Supported by:
摘要: 现代燃烧室由于富油燃烧-快速焠熄-贫油燃烧技术和贫油预混燃烧技术导致其出口具有非均匀温度(热斑)分布、强旋流和高湍流度的流动特征,显著影响燃烧室下游高压涡轮级的气热性能。先进高压涡轮级气热性能分析和冷却设计越发依赖于燃烧室和涡轮相互作用下交界面的气热参数非均匀分布特征。论文阐述了燃烧室和涡轮相互作用机理。介绍了燃烧室和涡轮相互作用下高压涡轮级气热性能研究的代表性实验台和数值方法。分别综述了燃烧室和涡轮相互作用下热斑、热斑和旋流、旋流和湍流度对高压涡轮级气热性能的影响特性。给出了燃烧室和涡轮相互作用下高压涡轮级的气热性能分析及不确定性量化的研究现状。总结了燃烧室和涡轮相互作用下高压涡轮级气热性能的研究成果。展望了非均匀气热参数分布条件下高压涡轮级气热性能可靠性分析和鲁棒性设计需要更加深入研究的方向,为适应先进航空发动机的燃烧室和涡轮一体化设计需求提供参考。
中图分类号:
李军, 栗智宇, 李志刚, 张垲垣, 宋立明. 燃烧室和涡轮相互作用下高压涡轮级气热性能研究进展[J]. 航空学报, 2021, 42(3): 24111-024111.
LI Jun, LI Zhiyu, LI Zhigang, ZHANG Kaiyuan, SONG Liming. Aerothermal performance of high pressure turbine stage with combustor-turbine interactions: Review[J]. ACTA AERONAUTICAET ASTRONAUTICA SINICA, 2021, 42(3): 24111-024111.
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