Stress Calibration Methodology of Stator Blades Using Experimental SAFE Diagram

Volume 7C: Structures and Dynamics Pub Date : 2018-06-11 DOI:10.1115/GT2018-76709

J. Ligot, Sébastien Hoffait, Jean de Cazenove, F. Vallino, J. Golinval

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Abstract

This paper introduces an improvement of the stress calibration methodology of stator blades to consider a nodal diameter of interest of the structure. The proposed calibration procedure and the search for optimal excitation set-up are detailed. To this purpose, the following points are addressed. Experimental modal analyses are performed using both accelerometers and strain gages. Post-processing techniques are developed to determine the nodal diameters of the identified modes. SAFE (Singh’s Advanced Frequency Evaluation) diagrams are computed from the experimental data and compared with the diagrams obtained numerically by finite elements computations. Multiple excitations are used to appropriate the targeted modes. A comparative study of different shaker types, of the number of excitation points and of their location is performed. Calibration is achieved by comparing strain measurements taken on one gage installed on the engine and velocities measured using laser vibrometers. It allows reducing the impact of the instrumentation on the modal content. The calibration factors obtained by the novel proposed procedure are compared to the ones given by the currently used methodology.

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基于实验安全图的静叶应力标定方法

本文介绍了一种改进的静叶应力校准方法，以考虑结构的感兴趣节点直径。详细介绍了所提出的校准程序和寻找最佳励磁装置。为此目的，提出以下几点。实验用加速度计和应变计进行了模态分析。开发了后处理技术来确定已识别模态的节点直径。根据实验数据计算出了SAFE (Singh’s Advanced Frequency Evaluation)图，并与有限元数值计算得到的图进行了比较。采用多重激励来调整目标模态。对不同激振器类型、激振点数目和激振点位置进行了比较研究。校准是通过比较安装在发动机上的一个量具上的应变测量值和使用激光振动计测量的速度来实现的。它允许减少仪表对模态内容的影响。将新方法得到的校正因子与现有方法给出的校正因子进行了比较。

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 7C: Structures and Dynamics

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