Dianchao Wang scite author profile

Summary A particle tuned mass damper system is an integration of tuned mass damper and particle damper. The damping performance of such device is investigated by an aero‐elastic wind tunnel test on a benchmark high‐rise building. The robustness of the system is studied by comparing the damping performance to that of a traditional tuned mass damper, and the results show that the damper has excellent and steady wind‐induced vibration control effects. Meanwhile, the parameters (filling ratio, mass ratio, and mass ratio of the container to particles), which have great influence on the vibration reduction performance of the system, are also analyzed, and it is found that the particles filling ratio plays the most important role in deciding the damping effects of the dampers. There exists an optimum filling ratio and mass ratios in which the damper can reach the best damping state. Proper parameter selections can greatly improve the damping performance.

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Strategies to accelerate CO2 sequestration of cement-based materials and their application prospects

Wang

Xiao

2022

Construction and Building Materials

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Increasing efficiency of carbon dioxide sequestration through high temperature carbonation of cement-based materials

Wang

Noguchi

Nozaki

2019

Journal of Cleaner Production

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Comparison Study of Vibration Control Effects between Suspended Tuned Mass Damper and Particle Damper

Wang

2014

Shock and Vibration

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The vibration control performance and its influencing factors of a tuned mass damper and a particle damper are examined by a single degree of freedom structure with such devices. The vibration control effects between these two dampers are also investigated. Increasing the mass ratio of the damper can improve the damping effects; under the condition of tuning frequency, the damping effects are remarkable. However, the more the deviation from the tuned frequency, the less controlling effects can be obtained. The damping effect of a particle damper is generally better than that of a tuned mass damper. For this test model, the particle damper can improve primary structure’s equivalent damping ratio 19 times to the original one’s, while the tuned mass damper can be 13 times. The reason lies in the fact that the particle damper can dissipate input energy by tuning mass, collision, impact, and friction between particles and the container and the momentum exchange effects between the secondary damper mass and the primary structure.

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Sustainable 3D printed mortar with CO2 pretreated recycled fine aggregates

Sun¹,

Zeng²,

Wang³

et al. 2022

Cement and Concrete Composites

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Investigation on the fast carbon dioxide sequestration speed of cement-based materials at 300 °C–700 °C

Wang

Noguchi

Nozaki

et al. 2021

Construction and Building Materials

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Energy analysis of particle tuned mass damper systems with applications to MDOF structures under wind-induced excitation

Zhang

Wang

2021

Journal of Wind Engineering and Industrial Aerodynamics

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Dianchao Wang

An experimental study of vibration control of wind-excited high-rise buildings using particle tuned mass dampers

Experimental parametric study on wind-induced vibration control of particle tuned mass damper on a benchmark high-rise building

Strategies to accelerate CO2 sequestration of cement-based materials and their application prospects

Increasing efficiency of carbon dioxide sequestration through high temperature carbonation of cement-based materials

Comparison Study of Vibration Control Effects between Suspended Tuned Mass Damper and Particle Damper

Sustainable 3D printed mortar with CO2 pretreated recycled fine aggregates

Investigation on the fast carbon dioxide sequestration speed of cement-based materials at 300 °C–700 °C

Energy analysis of particle tuned mass damper systems with applications to MDOF structures under wind-induced excitation

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