Design and analysis of plate-type eddy-current damper with high energy-dissipation capability

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2021-05-01 DOI:10.12989/SSS.2021.27.5.769
Jiazeng Shan, Jie Liu, C. Loong, Weichao Wu
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引用次数: 2

Abstract

A plate-type eddy-current damper with high energy-dissipation capability is designed and analyzed. The damper is configured in a dimension of 270 mm × 500 mm × 80 mm by employing 16 pairs of rectangular magnets and a rectangular copper plate. The paired magnets are arranged as two rows of 4-by-4 arrays with polarities alternating along the moving direction, while the copper plate is embedded inside two rows of magnets. A finite-element model is developed to investigate eddy-current force. The damping coefficient of damper under a constant velocity of 0.2 m/s is 24.44 kN-s/m. The eddy-current force under harmonic motion can be fitted as a sum of a linear elastic force and a linear damping force. The stiffness coefficient is increased by 77 times and the damping coefficient is reduced relatively by 19%, for vibration frequency increased from 0.5 to 10.0 Hz. The sensitivity of stiffness and damping coefficients on the physical dimensions of magnet and copper plate are discussed. The phase lag is sensitive to copper-plate thickness but insensitive to clear gap between two rows of magnets. The damper is implemented on a based-isolated structure. It is shown that the damper could reduce the peak of base drift and absolute acceleration response spectra by 71.9% and 73.1%, respectively.
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高耗能板式涡流阻尼器的设计与分析
设计并分析了一种具有高耗能能力的板式涡流阻尼器。阻尼器采用16对矩形磁体和一块矩形铜板,尺寸为270 mm×500 mm×80 mm。成对的磁体排列为两排4乘4的阵列,极性沿移动方向交替,而铜板嵌入两排磁体内部。建立了涡流力的有限元模型。阻尼器在恒定速度0.2m/s下的阻尼系数为24.44kN-s/m。谐波运动下的涡流力可以拟合为线性弹性力和线性阻尼力的总和。当振动频率从0.5 Hz增加到10.0 Hz时,刚度系数增加了77倍,阻尼系数相对降低了19%。讨论了刚度和阻尼系数对磁体和铜板物理尺寸的敏感性。相位滞后对铜板厚度敏感,但对两排磁体之间的间隙不敏感。阻尼器是在基于隔震结构的基础上实现的。结果表明,阻尼器能使基底漂移峰值和绝对加速度响应谱分别降低71.9%和73.1%。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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