考虑加工公差的叶片对压气机气动性能的影响
收稿日期: 2020-05-25
网络出版日期: 2020-10-10
基金资助
国家科技重大专项(2017-II-0004-0017);航空科学基金(2015ZB57006)
Impacts of Blades Considering Manufacturing Tolerances on Aerodynamic Performance of Compressor
Received date: 2020-05-25
Online published: 2020-10-10
为了量化轴流压气机叶片几何多种类加工公差对气动性能的综合影响,采用多种类几何加工公差的叶片三维模型构造方法,在设计点工况下,对压气机级样本进行三维计算流体力学数值模拟,并对样本叶片计算结果进行不确定性量化和敏感性分析.选择效率最高和最低的两个典型叶片几何误差案例,研究几何误差对出口流场的影响.结果表明:当压气机级处于设计工作状态时,全部位置度、扭转度和轮廓度公差范围内的叶片几何加工误差对样本叶片的质量流量、总压比、等熵效率、轴向推力和转矩等气动性能参数的平均影响可以忽略;转子叶片转矩的相对变化最大范围为-2.90%~2.30%.压气机级的质量流量和总压比对转子叶片各截面的扭转度公差敏感性最强,等熵效率则由转子叶片叶中截面扭转度、轴向位置度以及叶根截面的轴、周向位置度决定.几何误差的综合作用导致两案例转子叶片的等熵效率较原型的最大相对误差分别为+0.31%和-0.46%.转子叶片出口截面的径向相对总压损失和出口熵云图分布显示,典型几何误差对叶片通道内气流的流通和增压能力均有影响.
庄皓琬, 滕金芳, 朱铭敏, 羌晓青 . 考虑加工公差的叶片对压气机气动性能的影响[J]. 上海交通大学学报, 2020 , 54(9) : 935 -942 . DOI: 10.16183/j.cnki.jsjtu.2020.150
In order to quantify the comprehensive impact of multi-type geometric manufacturing tolerances of axial compressor blades on performances, a method of constructing three-dimensional blades with multi-type manufacturing tolerances was designed, and the three-dimensional computational fluid dynamics(CFD) numerical simulations of compressor stage samples at the design point were conducted. Then, the uncertainty quantification analysis and sensitivity analysis were conducted. Finally, the typical results of two blade samples with geometric errors, which have the highest efficiency and the lowest efficiency, respectively, were selected to explore the impacts of their geometric variations on the outlet flow field. The results show that when the compressor stage is working at the design point, the average impact of all real blade manufacturing position, twist, and profile errors within the tolerance on blade performances is negligible. The performances include mass flow rate, total pressure ratio, isentropic efficiency, axial thrust, and torque. However, the torque of rotor relatively changes with a range up to -2.90%-2.30%. The mass flow rate and the total pressure ratio of the compressor stage are most sensitive to the sectional twist of the rotor, while the isentropic efficiency is jointly determined by the twist and axial position of the middle section and the position of the bottom section. With the comprehensive influence of geometric errors, the relative errors of the maximum isentropic efficiency in the two cases are up to +0.31% and -0.46% compared with the original case. The geometric variations change the radial distribution of the relative total pressure loss and the entropy distribution at the rotor outlet obviously, and the flow capacity and the pressurizing ability of blade passage are consequently influenced.
| [1] | ZHENG S Y, TENG J F, WU Y, et al. Impact of nonuniform stagger angle distribution on high-pressure compressor rotor performance[C]//Proceedings of ASME Conference on ASME Turbo Expo 2018: Turbomachinery Technical Conference and Exposition. Houston, America: International Gas Turbine Institute, 2018: GT2018-76067. |
| [2] | GOODHAND M N, MILLER R J, LUNG H W. The impact of geometric variation on compressor two-dimensional incidence range[J]. Journal of Turbomachinery, 2015,137(2):021007. |
| [3] | REITZ G, SCHLANGE S, FRIEDRICHS J, Design of experiments and numerical simulation of deteriorated high pressure compressor airfoils[C]//Proceedings of ASME Conference on ASME Turbo Expo 2016: Turbomachinery Technical Conference and Exposition. Houston, America: International Gas Turbine Institute, 2016: GT2016-56024. |
| [4] | 高丽敏, 蔡宇桐, 曾瑞慧, 等. 叶片加工误差对压气机叶栅气动性能的影响[J]. 推进技术, 2017,38(3):525-531. |
| [4] | GAO Limin, CAI Yutong, ZENG Ruihui, et al. Effects of blade machining error on compressor cascade aerodynamic performance[J]. Journal of Propulsion Technology, 2017,38(3):525-531. |
| [5] | TENG X, CHU W L, ZHANG H G, , et al. The influence of geometry deformation on a multistage compressor[C]//Proceedings of ASME Conference on ASME Turbo Expo 2018: Turbomachinery Technical Conference and Exposition. Houston, America: International Gas Turbine Institute, 2018: GT2018-75935. |
| [6] | 高丽敏, 蔡宇桐, 徐浩亮, 等. 压气机叶片加工误差影响不确定分析[J]. 航空动力学报, 2017,32(9):2253-2259. |
| [6] | GAO Limin, CAI Yutong, XU Haoliang, et al. Uncertainty analysis of machining error influence of compressor blade[J]. Journal of Aerospace Power, 2017,32(9):2253-2259. |
| [7] | 郑似玉, 滕金芳, 羌晓青. 轮廓度加工超差对压气机气动性能影响的数值研究[J]. 科学技术与工程, 2016,16(29):317-320. |
| [7] | ZHENG Siyu, TENG Jinfang, QIANG Xiaoqing. Numerical investigation of profile variability on axial compressor flow field performance[J]. Science Technology and Engineering, 2016,16(29):317-320. |
| [8] | 郑似玉, 滕金芳, 羌晓青. 位置度超差对轴流压气机流场性能影响的数值研究[J]. 流体机械, 2016,44(11):20-24. |
| [8] | ZHENG Siyu, TENG Jinfang, QIANG Xiaoqing. Numerical investigation of positional variability on axial compressor flow field performance[J]. Fluid Machinery, 2016,44(11):20-24. |
| [9] | MONTOMOLI F, CARNEVALE M, D’AMMARO A, et al. Uncertainty quantification in computational fluid dynamics and aircraft engines[M]. Cham: Springer International Publishing, 2015: 33-57. |
| [10] | LANGE A, VOIGT M, VOGELER K, et al. Impact of manufacturing variability on multistage high-pressure compressor performance[J]. Journal of Engineering for Gas Turbines and Power, 2012,134(11):112601. |
| [11] | LEJON M, ANDERSSON N, ELLBRANT L, , et al. The impact of manufacturing variations on performance of a transonic axial compressor rotor[C]//Proceedings of ASME Conference on ASME Turbo Expo 2018: Turbomachinery Technical Conference and Exposition. Houston, America: International Gas Turbine Institute, 2018: GT2018-76340. |
| [12] | SCHNELL R, LENGYEL K T, NICKE E. On the impact of geometric variability on fan aerodynamic performance, unsteady blade row interaction, and its mechanical characteristics[J]. Journal of Turboma-chinery, 2014,136(9):091005. |
| [13] | GHISU T, PARKS G T, JARRETT J P, et al. Adaptive polynomial chaos for gas turbine compression systems performance analysis[J]. AIAA Journal, 2010,48(6):1156-1170. |
| [14] | 蔡宇桐, 高丽敏, 马驰, 等. 基于NIPC的压气机叶片加工误差不确定性分析[J]. 工程热物理学报, 2017,38(3):490-497. |
| [14] | CAI Yutong, GAO Limin, MA Chi, et al. Uncertainty quantification on compressor blade considering manufacturing error based on NIPC method[J]. Journal of Engineering Thermophysics, 2017,38(3):490-497. |
| [15] | LI Z H, LIU Y M, AGARWAL R K, Robust optimization design of single-stage transonic axial compressor considering the manufacturing uncertainties[C]//Proceedings of ASME Conference on ASME Turbo Expo 2018: Turbomachinery Technical Conference and Exposition. Houston, America: International Gas Turbine Institute, 2018: GT2018-75415. |
| [16] | SCHMIDT R, VOIGT M, VOGELER K, , et al. Comparison of two methods for sensitivity analysis of compressor blades[C]//Proceedings of ASME Conference on ASME Turbo Expo 2016: Turbomachinery Technical Conference and Exposition. Houston, America: International Gas Turbine Institute, 2016: GT2016-57378. |
| [17] | LUO J Q, LIU F. Performance impact of manufacturing tolerances for a turbine blade using second order sensitivities[C]//Proceedings of ASME Conference on ASME Turbo Expo 2018: Turbomachinery Technical Conference and Exposition. Houston, America: International Gas Turbine Institute, 2018: GT2018-75999. |
| [18] | 郑似玉, 滕金芳, 羌晓青. 叶片加工超差对高压压气机性能影响和敏感性分析[J]. 机械工程学报, 2018,54(2):216-224. |
| [18] | ZHENG Siyu, TENG Jinfang, QIANG Xiaoqing. Sensitivity analysis of manufacturing variability on high-pressure compressor performance[J]. Journal of Mechanical Engineering, 2018,54(2):216-224. |
| [19] | DOW E A, WANG Q Q. The implications of tolerance optimization on compressor blade design[J]. Journal of Turbomachinery, 2015,137(10):101008. |
| [20] | 中国航空工业总公司. 叶片叶型的标注、公差与叶身表面粗糙度: HB 5647—1998[S]. 北京: 中国航空工业总公司, 1999. |
| [20] | Aviation Industry Corporation of China. Tolerance and blade surface roughness: HB 5647—1998[S]. Beijing: AVIC, 1999. |
/
| 〈 |
|
〉 |
