Aerodynamic Optimization of Axial Fans Using the Adjoint Method

Volume 1: Aircraft Engine; Fans and Blowers; Marine Pub Date : 2018-06-11 DOI:10.1115/GT2018-77027

K. Bamberger, T. Carolus

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引用次数: 2

Abstract

This paper discusses the aerodynamic optimization of low-pressure axial fans using adjoint Computational Fluid Dynamics (CFD). In the first part, a typical CFD-based fan optimization problem is introduced. The focus is on the CFD model and potential objective functions. The adjoint system of equations and the adjoint boundary conditions for this optimization problem are derived in the second part. Moreover, the software implementation in the open source CFD code OpenFOAM v3.0.x is described. The existing OpenFOAM solver “adjointShapeOptimizationFoam” serves as the basis and is customized to the optimization of fans. The code solves both the primal and the adjoint incompressible Reynolds-averaged Navier-Stokes (RANS) equations from which a sensitivity map of the objective function with respect to the grid topology can be derived. The main extension of the existing code deals with the consideration of a rotating frame of reference leading to additional source terms in both the primal and the adjoint RANS equations. Moreover, the implementation of new boundary conditions is performed to handle the distinct objective functions. In the third part, the customized adjoint solver is applied to improve an existing baseline fan. Two adjoint simulations of the baseline fan are performed aiming at maximization of pressure and efficiency, respectively. The resulting surface sensitivities on the blade are used to modify the blade shape accordingly. Eventually, the performance of the two optimized fans is predicted by RANS to quantify the improvements. The first fan features a pressure rise which is 3.6 % higher as compared to the baseline fan. The second fan features an efficiency improvement of 0.1 percentage points as compared to the baseline fan. Hence, the functionality of the adjoint method is proven. A more substantial improvement would require further optimization loops with repeated adjoint simulations that, however, are not part of this paper.

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基于伴随法的轴流风机气动优化

本文利用伴随计算流体力学(CFD)对低压轴流风机的气动优化进行了研究。第一部分介绍了一个典型的基于cfd的风机优化问题。重点是CFD模型和潜在的目标函数。第二部分推导了该优化问题的伴随方程组和伴随边界条件。并且，软件实现在开源CFD代码OpenFOAM v3.0上。描述X。现有的OpenFOAM求解器“adjointShapeOptimizationFoam”作为基础，为风扇优化定制。该代码同时求解原始和伴随不可压缩的reynolds -average Navier-Stokes (RANS)方程，由此可以导出目标函数相对于网格拓扑的灵敏度映射。现有代码的主要扩展处理了旋转参照系导致原始和伴随RANS方程中附加源项的考虑。此外，实现了新的边界条件来处理不同的目标函数。在第三部分中，应用自定义伴随求解器对现有基线风机进行改进。分别以压力最大化和效率最大化为目标，对基准风机进行了两次仿真。由此产生的叶片表面灵敏度用于相应地修改叶片形状。最后，通过RANS对两种优化后的风扇性能进行预测，量化改进的效果。第一个风扇的特点是压力上升，比基准风扇高3.6%。与基准风扇相比，第二个风扇的效率提高了0.1个百分点。由此证明了伴随法的功能性。一个更实质性的改进将需要进一步的优化循环与重复伴随模拟，然而，不是本文的一部分。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Volume 1: Aircraft Engine; Fans and Blowers; Marine

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