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涡轮叶片中旋流冷却的肋片对流动换热的影响

Effects of finned structure on flow and heat transfer characteristics in vortex cooling of turbine blade
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摘要 为了探究肋片结构对旋流冷却进气腔和旋流腔内冷却气体流动和换热特性的影响,建立了六种不同的带肋旋流冷却模型,在相同的边界条件下对比分析了6种结构的流动换热特性和综合换热性能的差异。结果表明:在进气腔靶面加肋片能使进气腔靶面换热强度明显增强,而且肋片对进气腔整体流动的扰流影响较小;在旋流腔靶面加肋片增强了旋流腔靶面换热强度,并且提高了旋流腔内综合换热因子。在6种结构中,进气腔靶面上加45°斜肋并且旋流腔靶面加90°环肋的结构获得了最高的靶面总换热量和旋流腔内综合换热因子;与不加肋的旋流冷却结构相比,两个靶面的总换热量提高了51.8%,旋流腔内综合换热因子提高了3.44%。 In order to investigate the influence of the flow and heat transfer characteristics on vortex cooling with different finned structures in the intake cavity and vortex cooling chamber,six different models with finned structure were built.The flow characteristics,the heat transfer characteristics,and the comprehensive heat transfer performance of these six models were compared and analyzed under the same boundary conditions.The results showed that the heat transfer intensity of the target in the intake cavity increased obviously when finned structure was added to the intake cavity.When finned structure was added to the vortex chamber target surface,the heat transfer intensity and comprehensive heat transfer factor of the target in the vortex cooling chamber were enhanced a lot,too.Among these six models,the model with 45°oblique fins on the intake cavity and 90°fins on the vortex cooling chamber had the highest total heat transfer and comprehensive heat transfer factor,the total heat transfer of the two targets was 51.8%higher than that of the non-finned model,the comprehensive heat transfer factor was 3.44%higher than that of the non-finned model.
作者 严彪 朱华 刘雨松 李亮 YAN Biao;ZHU Hua;LIU Yusong;LI Liang(Institute of Turbomachinery,School of Energy and Power Engineering,Xi’an Jiaotong University,Xi’an 710049,China)
出处 《航空动力学报》 EI CAS CSCD 北大核心 2023年第11期2729-2737,共9页 Journal of Aerospace Power
基金 国家科技重大专项(2017-Ⅰ-0009-0010)。
关键词 涡轮叶片 旋流冷却 进气腔 旋流腔 气动性能 换热特性 turbine blade vortex cooling air intake cavity vortex cooling chamber flow properties heat transfer characteristics
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