温度变化下粘弹性阻尼器与惯性器组合结构的动力特性

Q4 Engineering

Vibrations in Physical Systems Pub Date : 2020-01-01 DOI:10.21008/J.0860-6897.2020.2.22

Z. Pawlak, R. Lewandowski

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引用次数: 0

摘要

这项工作的目的是对结构系统中用于减少风或地震引起的过度振动的被动阻尼器进行动力分析。特殊的系统被认为包含惯性器，即利用转动惯量的装置，与粘弹性阻尼器相结合。所谓的粘弹性阻尼器分数阶模型是用少量的模型参数来描述粘弹性阻尼器在宽频率范围内的动态特性。为了描述材料在更宽频率范围内的行为，使用了时间-温度叠加原理。移动系数是根据著名的威廉-兰德尔-费里公式计算的。这样就可以根据在参考温度下获得的参数来确定在任何温度下的阻尼器参数。对导出的运动方程进行拉普拉斯变换，得到非线性特征问题，可采用延拓法求解。研究了温度对系统动态特性的影响。

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Dynamic Characteristics of the Structure with Viscoelastic Dampers Combined with Inerters and Subjected to Temperature Changes

The purpose of the work is dynamic analysis of passive dampers used in structural systems to reduce excessive vibrations caused by wind or earthquakes. Special systems are considered that contain inerter, i.e. device using rotational inertia, in combination with a viscoelastic damper. The so-called fractional models of viscoelastic dampers describe their dynamic behavior in a wide frequency range using a small number of model parameters. To describe material behavior over a wider frequency range, the time-temperature superposition principle is used. The shifting factor is calculated from the well-known William-Landel-Ferry formula. This allows for determination of damper parameters at any temperature based on the parameters obtained at the reference temperature. Laplace transformation of the derived equations of motion leads to the non-linear eigenproblem, which could be solved using the continuation method. The influence of temperature on the dynamic characteristics of the system is examined.

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来源期刊

Vibrations in Physical Systems Engineering-Mechanics of Materials

CiteScore

0.70

自引率

0.00%

发文量