基于CFD和神经网络模型的涡轮叶片气动设计优化

IF 1.3 Q2 ENGINEERING, AEROSPACE
Chao Zhang, Matthew Janeway
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引用次数: 3

摘要

优化方法已广泛应用于燃气轮机叶片的气动设计。虽然将优化应用于高保真计算流体动力学(CFD)模拟已被证明能够提高工程设计性能,但一个挑战是克服由于计算成本高昂的CFD运行而导致的运行时间延长。降阶模型以及最近的机器学习方法越来越多地用于燃气轮机研究,以预测性能指标和运行特性、建模湍流和优化设计。机器学习方法的应用允许利用来自不同来源的现有知识和数据集,例如以前的实验、CFD、低保真度模拟、1D或系统级研究。本研究研究将利用这些数据的机器学习模型插入高保真CFD驱动的优化过程中,从而有效地减少了CFD模型所需的评估次数。人工神经网络(ANN)模型是根据3000多个涡轮叶片横截面二维(2D)CFD分析的数据进行训练的。然后,在嵌套优化过程中,将经过训练的ANN模型用作替代品,同时进行全三维Navier-Stokes CFD模拟。人工神经网络模型的评估成本低得多,可以进行数万次设计评估,以指导搜索在更昂贵、高保真度CFD运行中使用的最佳叶片轮廓,从而提高优化进度,同时减少所需的计算时间。据估计,与仅基于三维(3D)CFD模拟的优化过程相比,当前工作流程实现了计算时间的五倍减少。该方法在美国航空航天局/通用电气节能发动机(E3)高压涡轮叶片上进行了演示,发现Pareto前部设计的叶片效率和功率比基线有所提高。对优化数据的定量分析表明,本研究中的一些设计参数比其他参数更具影响力,如倾斜角和叶尖比例因子。检查优化设计还可以深入了解物理情况,表明优化设计在后缘附近的压降较低,但与基线设计相比,吸力侧表面的压降开始较早,有助于观察到效率和功率的提高。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Optimization of Turbine Blade Aerodynamic Designs Using CFD and Neural Network Models
Optimization methods have been widely applied to the aerodynamic design of gas turbine blades. While applying optimization to high-fidelity computational fluid dynamics (CFD) simulations has proven capable of improving engineering design performance, a challenge has been overcoming the prolonged run-time due to the computationally expensive CFD runs. Reduced-order models and, more recently, machine learning methods have been increasingly used in gas turbine studies to predict performance metrics and operational characteristics, model turbulence, and optimize designs. The application of machine learning methods allows for utilizing existing knowledge and datasets from different sources, such as previous experiments, CFD, low-fidelity simulations, 1D or system-level studies. The present study investigates inserting a machine learning model that utilizes such data into a high-fidelity CFD driven optimization process, and hence effectively reduces the number of required evaluations of the CFD model. Artificial Neural Network (ANN) models were trained on data from over three thousand two-dimensional (2D) CFD analyses of turbine blade cross-sections. The trained ANN models were then used as surrogates in a nested optimization process alongside a full three-dimensional Navier–Stokes CFD simulation. The much lower evaluation cost of the ANN model allows for tens of thousands of design evaluations to guide the search of the best blade profiles to be used in the more expensive, high-fidelity CFD runs, improving the progress of the optimization while reducing the required computation time. It is estimated that the current workflow achieves a five-fold reduction in computational time in comparison to an optimization process that is based on three-dimensional (3D) CFD simulations alone. The methodology is demonstrated on the NASA/General Electric Energy Efficient Engine (E3) high pressure turbine blade and found Pareto front designs with improved blade efficiency and power over the baseline. Quantitative analysis of the optimization data reveals that some design parameters in the present study are more influential than others, such as the lean angle and tip scaling factor. Examining the optimized designs also provides insight into the physics, showing that the optimized designs have a lower amount of pressure drop near the trailing edge, but have an earlier onset of pressure drop on the suction side surface when compared to the baseline design, contributing to the observed improvements in efficiency and power.
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来源期刊
CiteScore
2.30
自引率
21.40%
发文量
29
审稿时长
11 weeks
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