Experimental Measurement of Sectional Stiffness Properties of Composite Rotor Blades

Proceedings of the Vertical Flight Society 76th Annual Forum Pub Date : 2020-10-05 DOI:10.4050/f-0076-2020-16367

Tyler Sinotte, O. Bauchau

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引用次数: 1

Abstract

This paper describes an experimental-numerical technique for evaluating the full 6 × 6 stiffness matrices for beams based on measured strains using digital image correlation (DIC). The general formulation makes the method well suited for isotropic beams with simple cross-sectional configurations or beams made of anisotropic materials with complex geometries, as typically exhibited in composite rotor blades. A 2-D finite element code, SectionBuilder, is used to generate a finite element mesh of the cross-section and evaluate the warping field, which is then combined with the experimental strain data to calculate the stiffness matrix. A detailed error analysis is performed to allow for the propagation of the experimental errors into the stiffness calculation and provide an uncertainty quantification for use in comprehensive analysis codes. Experimental results are presented for an isotropic beam and two composite rotor blades. Overall, the stiffness properties from the experimental measurements and numerical models showed good agreement and the experimental measurements were able to capture all the expected non-zero stiffness components.

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复合材料动叶截面刚度特性的实验测量

本文介绍了一种利用数字图像相关技术(DIC)基于实测应变计算梁的全6 × 6刚度矩阵的实验-数值方法。一般公式使得该方法非常适合于具有简单截面结构的各向同性梁或具有复杂几何形状的各向异性材料制成的梁，如典型的复合转子叶片。利用二维有限元软件SectionBuilder生成截面有限元网格，计算翘曲场，并结合实验应变数据计算刚度矩阵。进行了详细的误差分析，以允许实验误差传播到刚度计算中，并为综合分析代码提供不确定性量化。给出了一个各向同性光束和两个复合材料转子叶片的实验结果。总体而言，从实验测量和数值模型得到的刚度特性显示出良好的一致性，并且实验测量能够捕获所有预期的非零刚度分量。

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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Proceedings of the Vertical Flight Society 76th Annual Forum

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