Machine learning augmented multi-sensor data fusion to detect aero engine fan rotor blade flutter

IF 0.7 4区工程技术 Q4 ENGINEERING, AEROSPACE

International Journal of Turbo & Jet-Engines Pub Date : 2022-11-30 DOI:10.1515/tjj-2022-0066

A. Rao, T. Satish, V. Naidu, Soumendu Jana

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引用次数: 1

Abstract

Abstract Flutter-induced fatigue failure investigation of the fan blades of aero-engines necessitates extensive testing. During engine ground testing, strain gauges on rotor fan blades and casing vibration sensors were employed to investigate structural dynamic aspects. The correlation between strain sensor signals and fan casing vibration signals allowed the diagnosis of fluttering fan blades. For automated flutter detection during engine development testing, a machine learning-augmented information fusion methodology was developed. The method analyses casing vibration signals by extracting time-domain statistical features, intrinsic mode function characteristics through empirical mode decomposition, and recurrence quantification features. Feature vectors obtained from a relatively large set of engine tests were subjected to dimension reduction by applying machine learning techniques to rank them. Reduced feature vector space was labelled as “flutter” or “normal” based on the correlation of rotor strain gauge signals. In addition, the labelled feature vectors were employed to train classifier models using supervised learning-based algorithms such as Support Vector Machines, Linear Discriminant Analysis, K-means Clustering, and Artificial Neural Networks. Using only vibration signals from the casing, the trained and validated classifiers were able to detect flutter in fan baldes with a 99% probability during subsequent testing.

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机器学习增强多传感器数据融合检测航空发动机风扇转子叶片颤振

航空发动机风扇叶片的颤振疲劳失效研究需要进行广泛的试验。在发动机地面测试过程中，使用转子风扇叶片上的应变仪和壳体振动传感器来研究结构动力学方面。应变传感器信号和风机外壳振动信号之间的相关性使得能够诊断风机叶片的颤动。为了在发动机开发测试过程中实现颤振的自动检测，开发了一种机器学习增强信息融合方法。该方法通过提取时域统计特征、经验模态分解的固有模态函数特征和递推量化特征来分析套管振动信号。通过应用机器学习技术对从一组相对较大的发动机测试中获得的特征向量进行排序，对其进行降维。基于转子应变仪信号的相关性，将缩减的特征向量空间标记为“颤振”或“正常”。此外，使用基于监督学习的算法，如支持向量机、线性判别分析、K-means聚类和人工神经网络，将标记的特征向量用于训练分类器模型。仅使用来自外壳的振动信号，经过训练和验证的分类器能够在随后的测试中以99%的概率检测到风扇罩的颤振。

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

International Journal of Turbo & Jet-Engines 工程技术-工程：宇航

CiteScore

1.90

自引率

11.10%

发文量

审稿时长

6 months

期刊介绍： The Main aim and scope of this Journal is to help improve each separate components R&D and superimpose separated results to get integrated systems by striving to reach the overall advanced design and benefits by integrating: (a) Physics, Aero, and Stealth Thermodynamics in simulations by flying unmanned or manned prototypes supported by integrated Computer Simulations based on: (b) Component R&D of: (i) Turbo and Jet-Engines, (ii) Airframe, (iii) Helmet-Aiming-Systems and Ammunition based on: (c) Anticipated New Programs Missions based on (d) IMPROVED RELIABILITY, DURABILITY, ECONOMICS, TACTICS, STRATEGIES and EDUCATION in both the civil and military domains of Turbo and Jet Engines. The　International Journal of Turbo & Jet Engines　is devoted to cutting edge research in theory and design of propagation of jet aircraft. It serves as an international publication organ for new ideas, insights and results from industry and academic research on thermodynamics, combustion, behavior of related materials at high temperatures, turbine and engine design, thrust vectoring and flight control as well as energy and environmental issues.