A new design of unsymmetrical shunt circuit with negative capacitance for enhanced vibration control

Piezoelectric elements are widely used in structural vibration suppression. The applicable bipolar voltage of a piezoelectric element is unsymmetrical, but in most control systems, the voltage on the piezoelectric actuator is applied symmetrically, which greatly wastes the driving capability. In synchronized switching damping (SSD) approaches for structural vibration control, the damping effect depends on the effective voltage range on the piezoelectric actuator. A novel method of realizing unsymmetrical bipolar voltage with SSD method based on negative capacitance shunt circuit for vibration control is proposed for improvement of the control performance in this study. A resistance and a diode that added into constructed negative capacitance circuit are used to realize unsymmetrical bipolar voltage. The general expression of the switched voltage on the piezoelectric actuator is derived. The stability of negative capacitance shunt circuit is addressed. The added offset resistance in the negative capacitance circuit plays an important role in system stability. The simulation analysis results agree very well with the theoretical results, both of which reveal that the unsymmetrical voltage ratio depends on the resistance in the negative capacitance circuit. Finally, experiments are carried out to verify the designed circuit and the excellent damping performance. (c) 2021 Elsevier Ltd. All rights reserved.

Automated summary

Piezoelectric elements are commonly used in structural vibration suppression, but the symmetric application of voltage in control systems often leads to wastage of driving capability. This study introduces a novel method utilizing negative capacitance shunt circuit to achieve asymmetrical bipolar voltage for improved control performance. The addition of offset resistance in the negative capacitance circuit is crucial for system stability.