Parametric optimization of electromagnetic tuned inerter damper for structural vibration suppression

Luo, Yifan; Sun, Hongxin; Wang, Xiuyong; Chen, Anhua; Zuo, Lei

doi:10.1002/stc.2711

Cited by 17 publications

(7 citation statements)

References 35 publications

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“…As usually done in the relevant literature for design issues, the adequate space to accommodate the TMD stroke is critical to guarantee the proper functioning of the devices 27,31–35,39–44 . Furthermore, the knowledge of the stroke length value leads to an estimate of the cost of both the spring and the damper connecting the two masses.…”

Section: Resultsmentioning

confidence: 99%

A variant design of tuned mass damper with negative stiffness for vibration control of a damped primary system

Charef

Khalfallah

2022

Structural Contr & Hlth

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In this paper, the optimal design of a non-traditional tuned mass damper (NTTMD) with negative stiffness for a damped primary system is studied in detail. The dynamical differential equation is established and the analytical solution of the system is obtained. Closed-form expression for the optimum tuning parameter is analytically derived using the fixed-points approach based on the assumption that the damped primary structure is lightly or moderately damped. Then, the optimum damping ratio and the optimum negative stiffness ratio of NTTMD are found numerically by solving a set of nonlinear equations established by Chebyshev's equioscillation theorem. Extended numerical simulations are carried out to examine the efficiency of the optimally designed NTTMD as well as the sensitivity of the optimal parameters. Finally, the utmost control performance of the proposed NTTMD is compared with those of two existing typical TMDs, which were presented by Pennestri and Liu, respectively. The comparison results show that the proposed non-traditional TMD with negative stiffness can significantly improve the vibration control performance in terms of mitigating the normalized frequency responses of damped primary structures and confining the stroke length of NTTMDs.

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Section: Resultsmentioning

confidence: 99%

A variant design of tuned mass damper with negative stiffness for vibration control of a damped primary system

Charef

Khalfallah

2022

Structural Contr & Hlth

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“…Luo et al 56 proposed an EM resonant shunt TMDI (ERS-TMDI), and their numerical results demonstrated that the inerter improved the control effectiveness of the ERS-TMD. Luo et al 57 also conducted parametric optimization of an EM-TID for controlling structural vibration. Salvi and Giaralis 58 proposed an energy harvesting-enabled TMDI, which comprises a TMD system, a linear motor, and an inerter.…”

Section: Noveltymentioning

confidence: 99%

“…proposed an EM resonant shunt TMDI (ERS‐TMDI), and their numerical results demonstrated that the inerter improved the control effectiveness of the ERS‐TMD. Luo et al 57 . also conducted parametric optimization of an EM‐TID for controlling structural vibration.…”

Section: Introductionmentioning

confidence: 99%

Application of electromagnetic tuned mass damper with flywheels for controlling building structure vibration

Lin

2023

Earthq Engng Struct Dyn

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This study investigates a novel electromagnetic tuned mass damper with flywheels (EM‐FW‐TMD) system for reducing building structure vibration. The EM‐FW‐TMD system comprises a tuned mass damper (TMD) system with an electromagnetic (EM) damper and flywheels (FW). The EM damping coefficient and inertance of the EM‐FW‐TMD are adjustable. A prototype EM‐FW‐TMD device is fabricated and tested to validate its adjustability. Sliding‐ and pendulum‐type EM‐FW‐TMD systems with various inerter configurations are investigated. The equations of motion for single‐ and multiple‐degree‐of‐freedom structures in which the two EM‐FW‐TMD systems are installed are derived. A parameter optimization method that considers inertance is proposed for the EM‐FW‐TMD systems. The control performance of the two EM‐FW‐TMD systems is extensively compared. Furthermore, for frequency detuning, a parameter redesign method is proposed for adjusting the inertance and EM damping coefficient of both types of EM‐FW‐TMD systems; the results indicate that the detuning effect can be significantly mitigated by this retuning method.

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“…16,17 Apart from the mechanical approaches, the hydraulic mechanism 18,19 is also adopted, which can achieve the inertial effect by enlarging the piston area or by decreasing the channel cross-section area. Furthermore, by means of electromagnetic approach, 20,21 the circuit composed of capacitors, inductors, and resistors assembled in a proper arrangement can also be used to offer an equivalent inertial effect in the mechanical device. Given the large inertial coefficient, the work efficiency of the vibration absorber is greatly improved, which helps to enhance the capacity of vibration control system.…”

Section: Introductionmentioning

confidence: 99%

An integrated equivalent tuned‐mass‐inerter vibration absorber and its optimal design

Dai

Tang

Zhang

2022

Structural Contr & Hlth

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Inerters have been widely used in the vibration suppression of automobile and civil structures, due to its large capability in kinetic energy. When applying inerters at the free end of a structure, additional lumped mass has to be involved for obtaining the driving force, which may not be beneficial to the integrity of the device. In this paper, an integrated equivalent tuned mass damper with inerter (ETMDI), having the mass with respect to both translational motion and rotation in a single device, is proposed. First, the equation of motion for the proposed ETMDI system is derived from the Lagrange's equation. The extended fixed-point theory is next used to obtain the closed-form expression for the optimal parameters. Taking a single degree-of-freedom system and a wind turbine tower, numerical simulations are further performed considering base excitations. Compared to the classical TMD and the inerter-based vibration absorber (IDVA-C4), the efficiency and robustness of the proposed ETMDI have been confirmed, showing its potential in energy absorbing and vibration mitigation applications.

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Parametric optimization of electromagnetic tuned inerter damper for structural vibration suppression

Cited by 17 publications

References 35 publications

A variant design of tuned mass damper with negative stiffness for vibration control of a damped primary system

A variant design of tuned mass damper with negative stiffness for vibration control of a damped primary system

Application of electromagnetic tuned mass damper with flywheels for controlling building structure vibration

An integrated equivalent tuned‐mass‐inerter vibration absorber and its optimal design

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