Numerical Simulation of Transonic Compressors with Different Turbulence Models

IF 0.1 4区工程技术 Q4 ENGINEERING, AEROSPACE Aerospace America Pub Date : 2023-09-06 DOI:10.3390/aerospace10090784

Wen‐Jing Yan, Zhaozheng Sun, Junwei Zhou, Kun Zhang, Jiahui Wang, Xiao Tian, Junqian Tian

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Abstract

One of the most commonly used techniques in aerospace engineering is the RANS (Reynolds average Navier–Stokes) approach for calculating the transonic compressor flow field, where the accuracy of the computation is significantly affected by the turbulence model used. In this work, we use SA, SST, k-ɛ, and the PAFV turbulence model developed based on the side-biased mean fluctuations velocity and the mean strain rate tensor to numerically simulate the transonic compressor NASA Rotor 67 to evaluate the accuracy of turbulence modeling in numerical calculations of transonic compressors. The simulation results demonstrate that the four turbulence models are generally superior in the numerical computation of NASA Rotor 67, which essentially satisfies the requirements of the accuracy of engineering calculations; by comparing and analyzing the ability of the four turbulence models to predict the aerodynamic performance of transonic compressors and to capture the details of the flow inside the rotor. The errors of the Rotor 67 clogging flow rate calculated by the SA, SST, k-ɛ, and PAFV turbulence models with the experimental data are 0.9%, 0.8%, 0.7%, and 0.6%, respectively. The errors of the calculated peak efficiencies are 2.2%, 1.6%, 0.9%, and 4.9%. The SA and SST turbulence models were developed for the computational characteristics of the aerospace industry. Their computational stability is better and their outputs for Rotor 67 are comparable. The k-ɛ turbulence model calculates the pressure ratio and efficiency that are closest to the experimental data, but the computation of its details of the flow field near the wall surface is not ideal because the k-ɛ turbulence model cannot accurately capture the flow characteristics of the region of high shear stresses. The PAFV turbulence model has a better prediction of complex phenomena such as rotor internal shock wave location, shock–boundary layer interaction, etc., due to the use of a turbulent velocity scale in vector form, but the calculated rotor efficiency is small.

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不同湍流模式下跨声速压气机的数值模拟

航空航天工程中最常用的技术之一是用于计算跨声速压气机流场的RANS (Reynolds average Navier-Stokes)方法，其中计算的准确性受到所使用的湍流模型的显著影响。本文利用SA、SST、k- i和基于偏侧平均波动速度和平均应变率张量的PAFV湍流模型对NASA转子67进行了数值模拟，以评价跨声速压气机数值计算中湍流建模的准确性。仿真结果表明，4种湍流模型在NASA转子67的数值计算中总体较优，基本满足工程计算精度的要求;通过对比分析四种湍流模型预测跨声速压气机气动性能和捕捉转子内部流动细节的能力。基于实验数据的SA、SST、k- α和PAFV湍流模型计算旋翼67堵塞流量的误差分别为0.9%、0.8%、0.7%和0.6%。计算的峰值效率误差分别为2.2%、1.6%、0.9%和4.9%。SA和SST湍流模型是针对航空航天工业的计算特性而开发的。它们的计算稳定性较好，并且在转子67上的输出与之相当。k- ε湍流模型计算的压力比和效率最接近实验数据，但由于k- ε湍流模型不能准确捕捉高剪应力区域的流动特性，其对壁面附近流场细节的计算并不理想。由于采用矢量形式的湍流速度尺度，PAFV湍流模型能较好地预测转子内部激波位置、激波-边界层相互作用等复杂现象，但计算出的转子效率较小。

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Aerospace America 工程技术-工程：宇航

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4-8 weeks