Non-linear modelling of elastic hysteretic damping in the time domain

IF 1.1 4区工程技术 Q3 MATERIALS SCIENCE, CHARACTERIZATION & TESTING

Archives of Mechanics Pub Date : 2020-10-08 DOI:10.24423/AOM.3536

C. Spitas, M. Dwaikat, V. Spitas

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引用次数: 9

Abstract

Elastic hysteretic damping is defined as the dissipation of energy at a rate that is weakly dependent on frequency of vibration. In this article, we propose that the elastic hysteretic damping can be achieved by a simple modification to the viscous damping model. The proposed modification is based on computing an instantaneous correction factor that recursively depends on the state variables of the system. This correction factor is related to the rate by which the velocity changes with respect to the displacement. The new model compares quite favourably with the other existing solutions in the time-domain and differences between the solutions become evident for higher damping ratios. It is found that the new model predicts consistently the weak variation in the loss factor as a function of frequency. In addition to its simple mathematical formulation, the proposed model is superior to the existing solutions in that it does not require knowledge of the past history of motion neither the knowledge of the excitation frequency and is extensible to any type of loading. Various aspects pertaining to the linearity of the proposed approach are finally discussed.

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弹性滞回阻尼的时域非线性建模

弹性滞回阻尼的定义是能量的耗散速率与振动频率的关系很弱。在本文中，我们提出弹性滞回阻尼可以通过对粘性阻尼模型的简单修改来实现。所提出的修正是基于计算一个递归依赖于系统状态变量的瞬时修正因子。这个修正系数与速度相对于位移的变化率有关。新模型在时域上与其他现有的解相比非常有利，并且在较高的阻尼比下，解之间的差异变得明显。结果表明，新模型能较好地预测损耗因子随频率的微弱变化。除了其简单的数学公式外，所提出的模型优于现有的解决方案，因为它不需要了解过去的运动历史，也不需要了解激励频率，并且可以扩展到任何类型的加载。最后讨论了与所提出的方法的线性有关的各个方面。

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

Archives of Mechanics 工程技术-材料科学：表征与测试

CiteScore

1.40

自引率

12.50%

发文量

审稿时长

>12 weeks

期刊介绍： Archives of Mechanics provides a forum for original research on mechanics of solids, fluids and discrete systems, including the development of mathematical methods for solving mechanical problems. The journal encompasses all aspects of the field, with the emphasis placed on: -mechanics of materials: elasticity, plasticity, time-dependent phenomena, phase transformation, damage, fracture; physical and experimental foundations, micromechanics, thermodynamics, instabilities; -methods and problems in continuum mechanics: general theory and novel applications, thermomechanics, structural analysis, porous media, contact problems; -dynamics of material systems; -fluid flows and interactions with solids. Papers published in the Archives should contain original contributions dealing with theoretical, experimental, or numerical aspects of mechanical problems listed above. The journal publishes also current announcements and information about important scientific events of possible interest to its readers, like conferences, congresses, symposia, work-shops, courses, etc. Occasionally, special issues of the journal may be devoted to publication of all or selected papers presented at international conferences or other scientific meetings. However, all papers intended for such an issue are subjected to the usual reviewing and acceptance procedure.