Numerical Investigation of Active Tip-clearance Control through Tip Cooling Injection in an Axial Turbine Cascade 被引量：6

Numerical Investigation of Active Tip-clearance Control through Tip Cooling Injection in an Axial Turbine Cascade

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摘要 This paper presents a numerical investigation of an active tip-clearance control method based on cooling injectionfrom the blade tip surface. It aims to study the influences of air injection on controlling tip clearance flow, withemphasis on the effects of the injection location on secondary flow and the potential thermal benefits from thecooling jet. The results show that injection location plays an important role in the redistribution of secondary flowwithin the cascade passage. Injection located much closer to the pressure-side comer performs better in reducingtip clearance massflow and its associated losses. However, it also intensifies tip passage vortex, due to less restraintderiving from the reduced tip clearance vortex. Lower plenum total pressure is required to inject equivalentamount of cooling air, but the heat transfer condition on the blade tip surface is a bit worse than that with injectionfrom the reattachment region. Thus the optimum location of air injection should be at the tip separation vortex region. This paper presents a numerical investigation of an active tip-clearance control method based on cooling injection from the blade tip surface. It aims to study the influences of air injection on controlling tip clearance flow, with emphasis on the effects of the injection location on secondary flow and the potential thermal benefits from the cooling jet. The results show that injection location plays an important role in the redistribution of secondary flow within the cascade passage. Injection located much closer to the pressure-side comer performs better in reducing tip clearance massflow and its associated losses. However, it also intensifies tip passage vortex, due to less restraint deriving from the reduced tip clearance vortex. Lower plenum total pressure is required to inject equivalent amount of cooling air, but the heat transfer condition on the blade tip surface is a bit worse than that with injection from the reattachment region. Thus the optimum location of air injection should be at the tip separation vortex region.

作者 Maosheng Niu Shusheng Zang

机构地区 Institute of Turbomachinery

出处《Journal of Thermal Science》 SCIE EI CAS CSCD 2009年第4期306-312,共7页 热科学学报(英文版)

关键词涡轮叶栅喷射控制数值研究冷却方法轴流清除间隙控制冷却空气 active tip-clearance control tip cooling injection injection location tip clearance vortex passagevortex secondary flow

分类号 V235.11 [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1

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Journal of Thermal Science

2009年第4期

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