Effects of Heating of Turbine on Turbofan Engine Compressor Tip Clearance During Acceleration Process

doi:10.13675/j.cnki.tjjs.190116

Journal of Propulsion Technology ›› 2020, Vol. 41 ›› Issue (5): 1144-1151.DOI: 10.13675/j.cnki.tjjs.190116

• Structure, Strength and Reliablity • Previous Articles Next Articles

Effects of Heating of Turbine on Turbofan Engine Compressor Tip Clearance During Acceleration Process

1.Aviation Foundation College,Naval Aviation University,Yantai 264001,China;2.Naval Research Academy,Shanghai 200436,China;3.Naval Consumer Representative Office of Engine in Shenyang,Shenyang 110043,China

Published:2021-08-15

暖机对涡扇发动机加速过程中压气机叶尖间隙影响分析

钱仁军¹，李本威¹，宋汉强²，武晓龙³，张赟¹

1.海军航空大学航空基础学院，山东烟台 264001;2.海军装备研究院，上海 200436;3.海军驻沈阳地区第二军事代表室，辽宁沈阳 110043

基金资助:
国家自然科学基金（51505492）；泰山学者建设工程专项经费资助。

Abstract

Abstract: In order to study whether the heating program of a turbofan engine is reasonable, the effects of heating and unheating on compressor tip clearance change of the engine during acceleration are analyzed and the change rules under this two conditions are compared. The rotor model was established. On the basis of considering centrifugal and temperature load of the rotor, the load spectrum was drawn by using engine bench test data under heating and unheating conditions. The radial displacement of the engine rotor during acceleration was simulated by using thermal-solid coupling analysis method based on Workbench. According to the calculation model of the rotor radial clearance, the tip clearances under heating and unheating conditions were calculated by the simulation results. The results show that the tip clearance of compressor after fully heated is significantly smaller than that without heating. Compared with the original assembly clearance, the difference between two tip clearances is 19.86% in idle state and 8.04% in maximum afterburning state. During the acceleration process, the tip clearance decreases rapidly from the idle to the intermediate state and slowly during the afterburning process.

Key words: Heating of turbine;Cold push;Thermal-solid coupling;Acceleration process;Compressor;Tip clearance

摘要： 为了研究涡扇发动机暖机程序是否合理，分析了暖机与不暖机对发动机加速过程中压气机叶尖间隙变化造成的影响，并进行了两种情况下变化规律的对比分析。建立了转子模型，在综合考虑转子离心载荷与温度载荷基础上，运用该发动机暖机与不暖机情况下台架测试数据绘制载荷谱，并基于Workbench平台采用热—固耦合分析方法对加速过程中发动机转子径向位移进行仿真计算。根据转子径向间隙计算模型，利用仿真结果计算获得暖机与不暖机情况下的叶尖间隙。结果表明，充分暖机后的压气机叶尖间隙值明显小于不暖机情况下的间隙值，相对原始装配间隙，两者在慢车状态时相差19.86%，在最大加力状态相差8.04%，且加速过程中叶尖间隙变化规律均为随时间增加而不断减小，在慢车至中间状态过程中迅速减小，在加力过程中缓慢减小。

关键词: 暖机;冷推;热—固耦合;加速过程;压气机;叶尖间隙

QIAN Ren-jun¹, LI Ben-wei¹, SONG Han-qiang², WU Xiao-long³, ZHANG Yun¹. Effects of Heating of Turbine on Turbofan Engine Compressor Tip Clearance During Acceleration Process[J]. Journal of Propulsion Technology, 2020, 41(5): 1144-1151.

钱仁军，李本威，宋汉强，武晓龙，张赟. 暖机对涡扇发动机加速过程中压气机叶尖间隙影响分析[J]. 推进技术, 2020, 41(5): 1144-1151.

References

[1] PIAO Ying, QI Xing-ming. Active Control System of Turbine Tip Clearance [J]. Information Computing and Automation， 2015: 781-784.
[2] Lattime S B， Steinetz B M. Turbine Engine Clearance Control Systems:Current Practices and Future Directions [R]. NASA-TM-2002-211794.
[3] 马玉真. 旋转叶片叶尖间隙测量的关键技术研究[D]. 天津: 天津大学， 2006.
[4] Lattime S B， Steinetz B M， Robbie M. Test Rig for Evaluating Active Turbine Blade Tip Clearance Control Concepts[R]. NASA-TM-2003-212533.
[5] Steinetz B M， Lattime S B， Taylor S， et al. Preliminary Evaluation of an Active Clearance Control System Concept[R]. NASA-TM-2005-213856.
[6] Steinetz B M， Taylor S， Oswald J， et al. Seal Investigations of an Active Clearance Control System Concept [R]. NASA-TM-2006-214114.
[7] Taylor S， Steinetz B M， Oswald J. Further Characterization of an Active Clearance Control Concept[R]. AIAA 2007-5739.
[8] 刘巧英，于洋. 发动机斜流压气机叶尖间隙稳态数值分析[J]. 推进技术， 2013， 34(2): 168-172.
[9] Kypuros J A， Melcher K J. A Reduced Model for Prediction of Thermal and Rotational Effects on Turbine Tip Clearance [R]. NASA-TM-2003-212226.
[10] Kypuros J A， Colson R， Munoz A. Improved Dynamic Model of Turbine Subcomponents for Facilitation of Generalized Tip Clearance Control[R]. NASA-NAG 3-2857.
[11] Agarwal H， Akkaram S， Shetye S， et al. Reduced Order Clearance Models for Gas Turbine Applications[R]. AIAA 2008-2177.
[12] 岂兴明，朴英，祝剑虹，等. 某型航空发动机高压涡轮叶顶间隙三维数值分析[J]. 航空动力学报， 2008， 23(5): 904-909.
[13] 杨栋，李秋实，张健. 某三级低压风扇不同工况叶尖间隙的变化规律及气动影响[J]. 航空动力学报， 2015， 30(5): 1200-1209.
[14] 于洋，刘巧英，沈倍毅，等. 高压压气机径向间隙分析[J]. 推进技术， 2013， 34(3): 339-346.
[15] 张丽华. 航空发动机风扇叶尖径向间隙数值仿真分析[J]. 燃气涡轮试验与研究， 2014， 27(4):7-11.
[16] 费成巍，付黎，柏树生，等. 高压涡轮叶尖径向运行间隙非线性动态分析[J]. 航空发动机， 2013， 39(1): 38-43.
[17] 《中国航空材料手册》编辑委员会. 中国航空材料手册第2卷[M]. 北京:中国标准出版社， 2002.
[18] 中国金属学会高温材料分会. 中国高温合金手册上卷[M]. 北京:中国标准出版社， 2012.
[19] 张宇坤，李昂，张赟. 某多级压气机流场数值计算[J]. 舰船电子工程， 2018， 11(1): 73-177.
[20] 《航空发动机设计手册》总编委会. 航空发动机设计手册第8册[M]. 北京:航空工业出版社， 2000.
[21] 张龙，韩鹏卓，刘忠奎，等. 航空发动机转子叶尖间隙及同心度变化规律研究[J]. 燃气涡轮试验与研究， 2017， 30(1): 44-47.

Effects of Heating of Turbine on Turbofan Engine Compressor Tip Clearance During Acceleration Process

暖机对涡扇发动机加速过程中压气机叶尖间隙影响分析

PDF

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 0

Recommended Articles

Metrics

Comments