Investigation of influencing factors of hot streaks migration in high pressure stage of a vaneless counter-rotating turbine 被引量：4

Investigation of influencing factors of hot streaks migration in high pressure stage of a vaneless counter-rotating turbine

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摘要 Three-dimensional,viscous,and unsteady CFD simulations have been performed in order to reveal the influencing factors of hot streaks migration in high pressure stage of a vaneless counter-rotating turbine. Based on the numerical results,the comparison between the case with inlet hot streaks and case without inlet hot streaks is carried out,which shows that the effect of inlet hot streaks on the load distributions of high pressure turbine airfoils is not notable and the airfoil load distributions are directly related to the inlet pressure distributions. The predicted results also indicate that the circumferential and radial movements of the hot streaks were not observed in the high pressure turbine stator. This means that the combined effects of secondary flow and buoyancy are very weak in the high pres-sure turbine stator. The numerical results also prove that the circumferential flow angle effect at the inlet of the high pressure turbine rotor,secondary flow effect and buoyancy effect are the mainly influencing factors to directly affect the migration characteristics of the hot streaks in the high pressure turbine rotor. Three-dimensional, viscous, and unsteady CFD simulations have been performed in order to reveal the influencing factors of hot streaks migration in high pressure stage of a vaneless counter-rotating turbine. Based on the numerical results, the comparison between the case with inlet hot streaks and case without inlet hot streaks is carried out, which shows that the effect of inlet hot streaks on the load distributions of high pressure turbine airfoils is not notable and the airfoil load distributions are directly related to the inlet pressure distributions. The predicted results also indicate that the circumferential and radial movements of the hot streaks were not observed in the high pressure turbine stator. This means that the combined effects of secondary flow and buoyancy are very weak in the high pressure turbine stator. The numerical results also prove that the circumferential flow angle effect at the inlet of the high pressure turbine rotor, secondary flow effect and buoyancy effect are the mainly influencing factors to directly affect the migration characteristics of the hot streaks in the high pressure turbine rotor.

作者 ZHAO QingJun WANG HuiShe TANG Fei ZHAO XiaoLu XU JianZhong

机构地区 Institute of Engineering Thermophysics Graduate University of Chinese Academy of Sciences

出处《Science China(Technological Sciences)》 SCIE EI CAS 2008年第2期127-144,共18页 中国科学（技术科学英文版）

关键词 COUNTER-ROTATING turbine HOT STREAK secondary flow BUOYANCY effect numerical simulation counter-rotating turbine hot streak secondary flow buoyancy effect numerical simulation

分类号 TP391.9 [自动化与计算机技术—计算机应用技术] TM21 [一般工业技术—材料科学与工程]

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