Damping in CFRP Structures: Modelling and Comparison of Technological Solutions Using Elastomer

VIII Conference on Mechanical Response of Composites Pub Date : 1900-01-01 DOI:10.23967/composites.2021.003

Y. Archi, N. Lahellec, S. Lejeunes, A. Jouan, B. Tranquart

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Abstract

In aeronautics, the latest generations of turbojets have inlet fan blades made of 3D-woven carbon fibre composite. Damping of rotating structures, such as blades, is of major industrial concern for controlling vibratory instabilities, like in-flight flutter for example, which can lead to the degradation of these blades. In order to overcome this difficulty and because CFRP materials are known to have limited damping properties, it seems necessary to implement innovative solutions to improve such a structure’s damping. Here, we study three damping technologies, based on the introduction of a dissipative material (elastomer) in the structure: The first technology consists in the bonding of an elastomeric layer at the scale of the blade structure which is also known as the viscoelastic patch (see [1]). Here the solution studied is a particular case of this technology where the elastomer layer lies within the laminate. The second technology consists in the introduction of the elastomer at the microstructure scale by adding some elastomeric fibers in the carbon fabric (see for example [2]). In the last one, still at the microstructure scale, all the carbon fibers are coated with a thin layer of elastomer ([3]). In the present study, some multiscale simulations are done to demonstrate the ability of these techniques to damp the first eigenfrequency of a cantilever beam, also known as Oberst beam tests ([4]). The constitutive materials (epoxy matrix and elastomer) are modelled in the framework of linear viscoelasticity, the plies behaviour are obtained by numerical homogenization and the laminate response is obtained by finite element method analysis (≪ Steady-State Dynamics ≫ procedure, ABAQUS V6.14). The results show that for a quasi-isotropic laminate stacking sequence, [−45,90,45,0]s, the ”coated” and ”co-fabric” technologies succeed in damping the first eigenmode but the damping ratio obtained with both techniques are lower than those obtained with the patch method (all the results are obtained with the same amount of added elastomer).

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碳纤维增强塑料结构中的阻尼:使用弹性体的建模和技术解决方案的比较

在航空领域，最新一代的涡轮喷气机的进气道风扇叶片由3d编织碳纤维复合材料制成。旋转结构(如叶片)的阻尼是控制振动不稳定性的主要工业问题，例如飞行中的颤振，这可能导致这些叶片的退化。为了克服这一困难，并且由于已知CFRP材料具有有限的阻尼性能，似乎有必要实施创新的解决方案来改善这种结构的阻尼。在这里，我们研究了三种阻尼技术，基于在结构中引入耗散材料(弹性体):第一种技术包括在叶片结构的尺度上粘接弹性体层，也称为粘弹性补丁(见[1])。这里研究的解决方案是该技术的一个特殊案例，其中弹性体层位于层压板内。第二种技术是通过在碳织物中添加一些弹性体纤维，在微观结构上引入弹性体(参见示例[2])。在最后一种方法中，仍然是在微观结构尺度上，所有的碳纤维都涂上了一层薄薄的弹性体([3])。在目前的研究中，进行了一些多尺度模拟来证明这些技术阻尼悬臂梁的第一特征频率的能力，也称为奥伯斯特梁试验([4])。本构材料(环氧树脂基体和弹性体)在线性粘弹性框架内建模，层状行为通过数值均匀化获得，层状响应通过有限元方法分析获得(《稳态动力学》程序，ABAQUS V6.14)。结果表明，对于准各向同性层叠序列[−45,90,45,0]s，“涂层”和“共织物”技术成功地阻尼了第一特征模，但两种技术获得的阻尼比都低于贴片法(所有结果都是在添加相同数量弹性体的情况下获得的)。

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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VIII Conference on Mechanical Response of Composites

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