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涡轮叶片吸力面上收敛缝形孔气膜冷却对叶栅气动损失的影响 被引量:9

Numerical Investigation on Aerodynamic Loss of Turbine Cascade with Converging Slot Hole Film Cooling at Suction Surface
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摘要 运用RNG湍流模型对具有气膜冷却的涡轮叶栅通道内部的三维流场进行了数值模拟,分析在叶栅通道主流入口雷诺数Re=4×105~6×105和二次流吹风比M=0.5~3.0范围内,沿吸力面3个典型弦向位置处(分别对应叶栅通道喉部上游、喉部和喉部下游)开设收敛缝形孔对叶栅通道损失系数的影响。计算结果表明:冷气喷射仅对孔附近区域的压力系数产生影响;位于喉部上游位置收敛缝形孔的能量损失及总压损失系数最低,大部分工况中位于喉部下游位置收敛缝形孔的损失系数最高;与圆形孔相比,位于喉部上游位置收敛缝形孔既具有好的冷却效率又具有低的损失系数。 The three-dimensional turbulent flow in a turbine cascade with blade film cooling is numerically investigated using a RNG turbulence model under different Reynolds numbers ranging from 4×105 to 6×105 and blowing ratios ranging from 0.5 to 3.0.The influence of the converging slot hole location at the blade suction surface (corresponding to the upstream of the throat,the cascade throat and the downstream of the throat) on the aerodynamic loss of the turbine cascade is investigated.Results show that the injection from the converging slot holes has effect only on the pressure coefficient distribution near the film cooling holes.The kinetic loss and total pressure loss induced by the injection from the film holes located at the upstream of the throat are lower than those induced by the other two locations,while the aerodynamic loss coefficients corresponding to the downstream of the throat location are the largest in most cases.Compared with cylindrical holes,the converging slot holes at the upstream of the throat exhibit both higher cooling effectiveness and lower aerodynamic loss coefficient.
作者 姚玉 张靖周 何飞 郭文
机构地区 南京航空航天大学能源与动力学院 洪都航空工业集团 中国燃气涡轮研究院
出处 《航空学报》 EI CAS CSCD 北大核心 2010年第7期1312-1317,共6页 Acta Aeronautica et Astronautica Sinica
基金 航空基础科学基金(03C52019)
关键词 收敛缝形孔 气动损失 气膜冷却 涡轮叶栅 吸力面 converging slot hole aerodynamic loss film cooling turbine cascade suction surface
分类号 V231.1 [航空宇航科学与技术—航空宇航推进理论与工程]
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参考文献15

  • 1Denton J D.Loss mechanisms in turbomachinery[R].ASME 93-GT-435,1993.
  • 2Ito S,Eckert E R G,Goldstein R J.Aerodynamic loss in a gas turbine stage with film cooling[J].Journal of Engineering for Power,1980,102:964-970.
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  • 4Kubo R,Otomo F,Fukuyama Y,et al.Aerodynamic loss increase due to individual film cooling injections from gas turbine nozzle surface[R].ASME 98-GT-497,1998.
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二级参考文献22

  • 1姚玉,张靖周,郭文.内部对流换热对导叶冷却效果的影响[J].工程热物理学报,2008,29(7):1181-1184. 被引量:3
  • 2何立明,蒋永健,康强,朱艳.利用上游斜坡改善气膜冷却效率的数值研究[J].推进技术,2009,30(1):9-13. 被引量:9
  • 3李永康,张靖周,姚玉.利用三角形突片改善气膜冷却效率的数值研究[J].航空动力学报,2006,21(1):83-87. 被引量:21
  • 4Gritsch M, Schulz A, Wittig S. Adiabatic wall effectiveness measurements of film-cooling holes with expanded exits[J]. Journal of Turbomachinery, 1998, 120(3): 549 -556.
  • 5Nasir H, Acharya S, Ekkad S. Improved film cooling from cylindrical angled holes with triangular tabs: effect of tab orientations [J]. International Journal of Heat and Fluid Flow, 2003, 24(5): 657-668.
  • 6Na S, Shih T I P. Increasing adiabatic film-cooling effectiveness by using an upstream ramp[J]. Journal of Heat Transfer, 2007, 129(4): 464- 471.
  • 7Shih T I P, Lin Y L, Chyu M K, et al. Computations of film cooling from holes with struts[R]. ASME 99 GT- 282, 1999.
  • 8Heidmann J D, Ekkad S. A novel antivortex turbine filmcooling hole concept [J]. Journal of Turbomachinery, 2008, 130(3): 201-209.
  • 9Sargison J E, Guo S M, Oldfield M L G, et al. A converging slot-hole film-cooling geometry--part 2: transonic nozzle guide vane heat transfer and loss[J]. Journal of Turbomachinery, 2002, 124(3): 461 471.
  • 10Ito S, Goldstein R J, Eckert E R G. Film cooling of a gas turbine blade[J]. Journal of Engineering for Power, 1978, 100(3): 476-481.

共引文献24

同被引文献89

引证文献9

二级引证文献105

航空学报
2010年 第7期

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