Model, tests and application design for viscoelastic dampers

Xu, Zhao‐Dong; Wang, Deng-Xiang; Shi, Chun-Fang

doi:10.1177/1077546310373617

Cited by 108 publications

(56 citation statements)

References 9 publications

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“…All of the hysteretic loops are obviously plump, which indicates that the VE dampers can efficiently dissipate energy. Compared with the VE dampers described in previous studies , the maximum damping force of this type of VE damper is greater, which means that the energy dissipation capacity is also larger. More significantly, the ultimate strain is remarkably greater.…”

Section: Performance Tests Of Viscoelastic Dampermentioning

confidence: 58%

“…In general, the damper behavior is nearly independent of frequency and is less insusceptible to velocity. This feature is very different from other types of VE dampers and will be significant in seismic application, because the damper behavior remains stable when the structural frequency is increased by the additional stiffness provided by the VE damper.…”

Section: Performance Tests Of Viscoelastic Dampermentioning

confidence: 88%

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Experimental study and numerical simulation on a new type of viscoelastic damper with strong nonlinear characteristics

Gong

Zhou

2016

Struct. Control Health Monit.

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In this study, a new type of viscoelastic (VE) damper with strong nonlinear characteristics, showing both softening and hardening, is investigated. Firstly, its performance tests are executed, and its mechanical properties summarized. Then, a shaking table test on a three-story viscoelastically damped structure is designed to investigate the dissipation characteristics and control effect of this type of VE damper. Six VE dampers were installed in pairs at each story and connected vertically to the upper and lower beams. The structure with additional VE dampers and that without additional VE dampers was subjected to three ground motions whose peak ground accelerations varied from 0.1 to 0.6 g. The experimental results indicate that the control effect on the displacements was remarkable, while the effect on accelerations and shear forces was limited, due to the damper's additional stiffness. With the increment of the damper deformation, the additional stiffness decreased, while the additional effective damping ratio increased at first and then declined. Finally, a simplified analytical method is proposed and applied to simulate the shaking table test using OpenSees. The simulating results validate the analytical method of this type of VE damper.

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Section: Performance Tests Of Viscoelastic Dampermentioning

confidence: 58%

Section: Performance Tests Of Viscoelastic Dampermentioning

confidence: 88%

Experimental study and numerical simulation on a new type of viscoelastic damper with strong nonlinear characteristics

Gong

Zhou

2016

Struct. Control Health Monit.

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“…Xu et al examined the performance of an eight‐story–reinforced concrete frame structure with installed VE dampers using numerical simulations. It was concluded that VE dampers have good energy dissipation capacity, which leads to a significant increase in structural stiffness and damping.…”

Section: Introductionmentioning

confidence: 99%

Shake table tests and numerical investigation of a resilient damping device for seismic response control of building structures

Bogdanovic¹,

Rakicevic²,

Farsangi

2019

Struct Control Health Monit

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In this study, shake table tests of a multistory steel frame structure designed according to Eurocodes 3 and 8 with and without the newly developed prestressed viscous damper (PVD) have been carried out at the Institute of Earthquake Engineering and Engineering Seismology in Macedonia. An array of strong ground motion records has been applied to the reduced-scale test structure to assess the efficiency and seismic performance of the equipped building with PVDs. It has been revealed that with the implementation of this system, the structural responses were suppressed in the range of 10% to 70%. Series of sensitivity analyses have been performed within the study to investigate the effect of the individual parameters and evaluate the effectiveness of the proposed system. Besides the experimental investigations, extensive numerical simulations of the structure without PVDs versus structure with three different damper placements were performed in ANSYS nonlinear platform, and part of the results that are presented in this paper confirms the remarkable structural performance improvement when using this system. The results also exhibit that the developed finite element models are properly verified through the experimental results and have the capabilities to further investigate the proposed system. It is likely that the proposed control strategy can be used for practical implementations into full-scale buildings to improve the urban seismic resilience. KEYWORDSdamper placement, numerical modeling, prestressed viscous damper, seismic resilience, shake table test, vibration control | INTRODUCTIONThe concept of structural resilience is a relatively new topic in the field of earthquake engineering. On the basis of the literature, a resilient system should have two main capabilities:• To maintain the structure functionality at an appropriate level during and after major seismic events.• To get recovered to its initial condition within a short period of time.

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“…And how to accurately calculate or simulate the mechanical properties of viscoelastic materials is a complex problem (Lewandowski and Chorazyczewski, 2010). A large number of scholars have studied viscoelastic materials and put forward a series of mechanical models, including Maxwell model, Kelvin model, standard solid model (Kim et al, 2003), ESS (equivalent standard solid) model (Xu, 2007;Xu et al, 2011), equivalent stiffness and equivalent damping model (Yoshida et al, 2002), fractional derivative model (Xu et al, 2015), Finite element model, complex stiffness model, Standard rheological model (Mould et al, 2011;Lee and Choi, 2018), fractional index model (Gonzalez et al, 2016;Chen et al, 2018), micro-oscillator model (Mctavish and Hughes, 1993), and so on. The ESS model is a new computational model based on temperature frequency equivalent principle and standard linear solid model, which can correctly describe the variation of viscoelastic damper with the change of temperature and frequency.…”

Section: Introductionmentioning

confidence: 99%

A Two-Step Transformation Approach for ESS Model of Viscoelastic Material to Time Domain

Huang

2019

Front. Mater.

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ESS (Equivalent Standard solid) model is proofed to be accurate for describing the physical properties of viscoelastic material under different temperatures and excitation frequencies. However, the ESS model faces difficulties for calculating time history responses. Therefore, a two-step transformation approach for ESS model to time domain is proposed, which can obtain precise time history response of structural finite element models of with dampers made of viscoelastic materials. In the first step of the approach, ESS model is extended from frequency domain to complex frequency domain. In the second step, a high-precision numerical inverse Laplace transform method is chosen to transform the model from complex frequency domain to time domain. Experimental and numerical tests are conducted to verify the effectiveness of the two-step transformation approach under simple harmonic external excitation. The comparisons indicate that the approach is accurate under different temperatures and excitation frequencies. Finally, the time domain dynamic responses of the viscoelastic dampers are obtained under earthquake excitations. Comparing to the equivalent linearization method for ESS model, the proposed two-step transformation approach has absolute advantage to obtain accurate results under random excitation, such as earthquake excitations.

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Model, tests and application design for viscoelastic dampers

Cited by 108 publications

References 9 publications

Experimental study and numerical simulation on a new type of viscoelastic damper with strong nonlinear characteristics

Experimental study and numerical simulation on a new type of viscoelastic damper with strong nonlinear characteristics

Shake table tests and numerical investigation of a resilient damping device for seismic response control of building structures

A Two-Step Transformation Approach for ESS Model of Viscoelastic Material to Time Domain

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