Abstract
In recent years, the new technologies and discoveries on manufacturing materials have encouraged researchers to investigate the appearance of material properties that are not naturally available. Materials featuring a specific stiffness, or structures that combine non-structural and structural functions are applied in the aerospace, electronics and medical industry fields. Particularly, structures designed for dynamic actuation with reduced vibration response are the focus of this work. The bi-material and multifunctional concepts are considered for the design of a controlled piezoelectric actuator with vibration suppression by means of the topology optimization method (TOM). The bi-material piezoelectric actuator (BPEA) has its metallic host layer designed by the TOM, which defines the structural function, and the electric function is given by two piezo-ceramic layers that act as a sensor and an actuator coupled with a constant gain active velocity feedback control (AVFC). The AVFC, provided by the piezoelectric layers, affects the structural damping of the system through the velocity state variables readings in time domain. The dynamic equation analyzed throughout the optimization procedure is fully elaborated and implemented. The dynamic response for the rectangular four-noded finite element analysis is obtained by the Newmark’s time-integration method, which is applied to the physical and the adjoint systems, given that the adjoint formulation is needed for the sensitivity analysis. A gradient-based optimization method is applied to minimize the displacement energy output measured at a predefined degree-of-freedom of the BPEA when a transient mechanical load is applied. Results are obtained for different control gain values to evaluate their influence on the final topology.
Highlights
In this work, the topology optimization (TO) extended to a bi-material metallic design of piezoactuators in timedomain analysis, seeks the structural vibration suppression needed in modern electronic devices applications that require lightweight, fast-response and fast stabilizing actuators [1]
The bi-material piezoelectric actuator (BPEA) structure designed in this work, features nonstructural functions such as the piezoelectric effect, for sensing and actuation of a controlled transducer, and optimized structural functions such as stiffness and damping of a bi-metallic host layer
For the design of the BPEA with an active velocity feedback control (AVFC) for vibration attenuation, the topology optimization method (TOM) is the most suited technique once it allows a continuous material properties variation within the microstructure according to the objective of the design
Summary
The topology optimization (TO) extended to a bi-material metallic design of piezoactuators in timedomain analysis, seeks the structural vibration suppression needed in modern electronic devices applications that require lightweight, fast-response and fast stabilizing actuators [1]. The number of time steps used in time integration for the dynamic finite element (FE) analysis and the time varying rate used for the dynamic input load are examples of parameters that have a significant influence on the final topological result [7] For this reason, when it comes to the design of piezoelectric actuators for time domain dynamic applications, researchers mostly deal with plate structures, given a fixed host layer structure, and optimize the piezoelectric material distribution for a transient objective function [8]. Linear quadratic regulator (LQR) and proportion integration differentiation (PID) control schemes have been studied for different excitation types applyed to flexible structures [18] Among those works, the predefined placement of sensors and actuators associated with a controller have resulted in vibration attenuations of the system.
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