Aeroelastic Stability of Combined Plunge-Pitch Mode Shapes in a Linear Compressor Cascade

IF 1.3 Q2 ENGINEERING, AEROSPACE

International Journal of Turbomachinery, Propulsion and Power Pub Date : 2022-02-14 DOI:10.3390/ijtpp7010007

George Hill, Julian Gambel, Sabine Schneider, D. Peitsch, Sina Stapelfeldt

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引用次数: 2

Abstract

Modern aeroengine designs strive for peak specific fuel and thermal efficiency. To achieve these goals, engines have more highly loaded compressor stages, thinner aerofoils, and blended titanium integrated disks (blisks) to reduce weight. These configurations promote the occurrence of aeroelastic phenomena such as flutter. Two important parameters known to influence flutter stability are the reduced frequency and the ratio of plunge and pitch components in a combined flap mode shape. These are used as design criteria in the engine development process. However, the limit of these criteria is not fully understood. The following research aims to bridge the gap between semi-analytical models and modern compressors by systematically investigating the flutter stability of a linear compressor cascade. This paper introduces the plunge-to-pitch incidence ratio, which is defined as a function of reduced frequency and pitch axis setback for a first flap (1F) mode shape. Using numerical simulations, in addition to experimental validation, aerodynamic damping is computed for many modes to build stability maps. The results confirm the importance of these two parameters in compressor aeroelastic stability as well as demonstrate the significance of the plunge-to-pitch incidence ratio for predicting the flutter limit.

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线性压缩机叶栅中组合柱塞-节距模态形状的气动弹性稳定性

现代航空发动机的设计力求达到最高的燃料比效率和热效率。为了实现这些目标，发动机具有更高负载的压缩机级、更薄的机翼和混合钛集成盘（整体叶盘）以减轻重量。这些构型促进了诸如颤振之类的气动弹性现象的发生。已知影响颤振稳定性的两个重要参数是组合襟翼模态形状中的降低频率以及倾斜度和俯仰分量的比率。这些被用作发动机开发过程中的设计标准。然而，这些标准的局限性还没有得到充分理解。以下研究旨在通过系统研究线性压缩机叶栅的颤振稳定性，弥合半解析模型与现代压缩机之间的差距。本文介绍了第一襟翼（1F）模态形状的纵倾-俯仰入射比，该入射比被定义为降低频率和俯仰轴回缩的函数。使用数值模拟，除了实验验证外，还计算了许多模式的气动阻尼，以建立稳定性图。结果证实了这两个参数在压缩机气动弹性稳定性中的重要性，并证明了倾斜度入射比对预测颤振极限的重要性。

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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