Adjoint-Based Design Optimization of a Volute for a Radial Compressor

IF 1.3 Q2 ENGINEERING, AEROSPACE
Romain Hottois, Arnaud Châtel, Tom Verstraete
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引用次数: 1

Abstract

Numerical optimization methods are widely used for designing turbomachinery components due to the cost and time savings they can provide. In the available literature, the shape optimization of radial compressors mainly focuses on improving the impeller alone. However, it is well-established knowledge that the volute plays a key role in the overall performance of the compressor. The aim of the present paper is to perform an adjoint-based optimization of a volute that is designed for the SRV2-O compressor. The CAD model was first created by using the parametrization of 33 design parameters. Then, a butterfly topology was applied to mesh the computational domain with a multi-block structured grid, and an elliptic smoothing procedure was used to improve the quality of the fluid grid. A steady-state RANS CFD solver with a Spalart-Allmaras turbulence model was used to solve the Navier–Stokes equations, and then the flow sensitivities were computed with an adjoint solver. The objective function consists of minimizing the loss coefficient of the volute. The optimization is performed to obtain an improved design with a 14% loss reduction. A detailed flow and design analysis is carried out to highlight the loss reduction mechanisms, followed by the optimizer. Finally, the compressor map of the full stage is compared between the baseline and the optimized volute from the CFD simulations using a mixing plane interface. This research demonstrates the successful use of a gradient-based optimization technique to improve the volute of a radial compressor and opens the door towards simultaneously optimizing the wheel and the volute.
基于共轭法的径向压缩机蜗壳设计优化
数值优化方法由于可以节省成本和时间而广泛应用于涡轮机械部件的设计。在现有的文献中,径向压缩机的形状优化主要集中在单叶轮的改进上。然而,众所周知,蜗壳在压缩机的整体性能中起着关键作用。本文的目的是对SRV2-O压缩机设计的蜗壳进行伴随优化。首先对33个设计参数进行参数化,建立CAD模型。然后,采用蝶形拓扑对计算域进行多块结构网格的网格划分,并采用椭圆平滑处理提高流体网格的质量。采用Spalart-Allmaras湍流模型的稳态RANS CFD求解器对Navier-Stokes方程进行求解,然后利用伴随求解器计算流动灵敏度。目标函数包括最小化蜗壳的损耗系数。进行优化以获得改进的设计,损耗降低14%。进行了详细的流程和设计分析,以突出减少损失的机制,然后是优化器。最后,利用混合平面界面,比较了CFD模拟的基线和优化蜗壳的全级压气机分布图。该研究成功地应用了基于梯度的优化技术来改进径向压缩机的蜗壳,为同时优化叶轮和蜗壳打开了大门。
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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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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