Semiactive Control of Nonlinear Parametric Vibration of Super‐Long Stay Cable in Cable‐Stayed Bridge Installed with Magnetorheological Fluid Damper

Du, Junping; Liu, Min; Zhou, Peng; Xiao, Huigang

doi:10.1155/2024/2161065

Cited by 3 publications

(1 citation statement)

References 69 publications

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“…As a type of semi-active damper, the MRD can regulate the damping characteristics by adjusting excitation current [1][2][3], possessing advantages such as fast response speed, a wide adjustable range of damping force, and low power consumption [4][5][6][7]. It has a promising prospect in the field of vibration control and has been widely applied in fields such as vehicle suspension [8][9][10][11], human exoskeletons [12][13][14], buildings [15][16][17] and bridges [18][19][20]. With the continuous expansion of MRD application fields, many new types of the MRD [21][22][23] meet the requirements of different application fields by increasing the damping output range and other means.…”

Section: Introductionmentioning

confidence: 99%

Multi-condition adaptive detail characterization model of magnetorheological dampers and experimental verification

Lei,

Li,

et al. 2024

Phys. Scr.

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The theoretical model for predicting the damping characteristics of magnetorheological dampers (MRDs) is significant for enhancing the design efficiency of the control algorithm. However, some existing theoretical models face limitations in characterizing MRD damping characteristics simultaneously in terms of nonlinear detail characterization and adaptability to variable working conditions. Therefore, this paper proposed the Composite Double-Boltzmann (CDB) model combining the Double-Boltzmann (DB) function widely used in the field of biology and chemistry for its strong nonlinear characterization capability. Utilizing this model to fit the sinusoidal vibration testing data of the MRD prototype under variable combination working conditions, obtaining quantitative relationships between the undetermined parameters in the CDB model and the excitation current, vibration frequency, and amplitude to enable the model to address both the nonlinear details characterization of MRDs and adaptability to variable working conditions. Subsequently, the validity of the quantitative relationships were verified by comparing the calculated parameter values using the quantitative relationships with the original accurate parameter values. In order to verify the validity of the CDB model, extensive unknown working condition vibration tests were conducted on the MRD prototype under variable excitation currents, vibration frequencies, amplitudes and random excitation working conditions, employing the CDB and Tanh models to predict the damping characteristics, to compare to demonstrate the CDB model’s capability of adapting to variable working conditions while accurately characterizing the nonlinear details of MRD damping characteristics.

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Section: Introductionmentioning

confidence: 99%

Multi-condition adaptive detail characterization model of magnetorheological dampers and experimental verification

Lei,

Li,

et al. 2024

Phys. Scr.

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Research on dynamic performance and mechanical model of a novel magnetorheological shear thickening damper with adaptive variable damping gap

Zhao,

Wang,

Yuan

et al. 2024

Smart Mater. Struct.

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Magnetorheological shear thickening fluid (MRSTF) is an intelligent composite material, which shows considerable potential in semi-active vibration control. However, the current research is mostly limited to the study of the rheological properties of materials, and there is still a lack of damper structures that can effectively utilize the dual-control characteristics of MRSTF. In this paper, a novel damper structure with adaptive adjustable damping gap length is proposed. Its unique design integrates an adaptive internal damping gap that changes with the movement of the piston and an external gap controlled by the magnetic field, providing a relatively wide range of current-controlled damping force and reliable adaptive adjustment capabilities. Based on the M-S shear stress constitutive model and structural characteristics, the mechanical model is derived from the force balance of the micro-element, and verified by performance test and curve fitting. The effectiveness of the new damper structure proposed in this paper is verified by dynamic performance test. The results show that the damper has a wide range of current controlled damping force at low speed and reliable adaptive adjustment capability at high speed. Finally, the accuracy and universality of the modified mechanical model of damper are verified by curve fitting method. All these studies can offer an effective guidance for further application of MRSTF in the field of semi-active vibration control.

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Experimental and Theoretical Investigations on an Asynchronized Parallel Double‐Stage Viscous Fluid Damper

Yang,

Wang,

Xie

et al. 2024

Structural Control and Health Monitoring

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The parameters of most conventional passive dampers are constant, which may not sufficiently satisfy the different energy dissipation capacity demands of the structure under different load conditions. The development of passive dampers with variable performances has become an emerging and vital trend in energy dissipation technologies and smart structures. This study proposes a novel passive viscous fluid damper with variable performance under different deformation levels called an asynchronized parallel double‐stage viscous fluid damper (APDVFD). It is expected to exhibit an asynchronized double‐stage working mechanism based on a variable annular gap. In the first stage, only the primary piston provides the damping force. When the deformation reaches a preset value, the primary and second pistons work in parallel, providing a damping force concurrently. Circular orifices are adopted for the piston head to provide a sufficient damping force. The double‐stage operating mechanism and fatigue performance of the APDVFD were validated and investigated through a full‐scale experiment with 46 load cases. Based on these, a theoretical model capable of predicting the hysteretic behavior of the APDVFD was developed and validated against test data.

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Semiactive Control of Nonlinear Parametric Vibration of Super‐Long Stay Cable in Cable‐Stayed Bridge Installed with Magnetorheological Fluid Damper

Cited by 3 publications

References 69 publications

Multi-condition adaptive detail characterization model of magnetorheological dampers and experimental verification

Multi-condition adaptive detail characterization model of magnetorheological dampers and experimental verification

Research on dynamic performance and mechanical model of a novel magnetorheological shear thickening damper with adaptive variable damping gap

Experimental and Theoretical Investigations on an Asynchronized Parallel Double‐Stage Viscous Fluid Damper

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