The Current Gap between Design Optimization and Experiments for Transonic Compressor Blades

IF 1.3 Q2 ENGINEERING, AEROSPACE International Journal of Turbomachinery, Propulsion and Power Pub Date : 2023-11-13 DOI:10.3390/ijtpp8040047

Edwin Joseph Munoz Lopez, Alexander Hergt, Till Ockenfels, Sebastian Grund, Volker Gümmer

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Abstract

The successful design of compressor blades through numerical optimization relies on accurate CFD-RANS solvers that are able to capture the general performance of a given design candidate. However, this is a difficult task to achieve in transonic flow conditions, where the flow is dominated by inherently unsteady shock effects. In order to assess the current gap between numerics and experiments, the DLR has tested the recently optimized Transonic Cascade TEAMAero at the transonic cascade wind tunnel. The tests were performed at a Mach number of 1.2 and with inflow angles between 145 and 147. The results indicate satisfactory agreement across the expected working range, over which the cascade losses were consistently predicted within a 3–6% error. However, some key differences are observed in the details of the wake and in the performance near the endpoints of the working range. This comparison helps validate the design process but also informs its constraints based on the limitations of CFD-RANS solvers.

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跨声速压气机叶片设计优化与实验之间的差距

通过数值优化设计压气机叶片的成功依赖于精确的cfd - ran解算器，该解算器能够捕获给定候选设计的一般性能。然而，在跨声速流动条件下，这是一项很难实现的任务，因为在跨声速流动条件下，流动由固有的非定常激波效应主导。为了评估目前数值与实验之间的差距，DLR在跨音速叶栅风洞中测试了最近优化的跨音速叶栅TEAMAero。试验在马赫数为1.2、入流角为145 ~ 147的条件下进行。结果表明，在预期的工作范围内，叶栅损失的预测结果一致，误差在3-6%以内。然而，在尾流的细节和工作范围端点附近的性能上观察到一些关键的差异。这种比较有助于验证设计过程，但也根据cfd - ran求解器的局限性告知其约束。

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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