Design of a novel 2D ultrasonic transducer for 2D high-frequency vibration–assisted micro-machining

Satpute, Vinod; Huo, Dehong; Hedley, John; Elgendy, Mohammed A.

doi:10.1007/s00170-023-11154-1

Cited by 3 publications

(1 citation statement)

References 26 publications

(31 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Therefore, it is an important component for assisting cutting. The structure [11,12] of the transducer consists of a tail mass and horn clamped by a hexagonal bolt and a piezoelectric ceramic stack for generating elliptical and longitudinal vibrations fixed in the middle. Therefore, the total energy [13,14] during operation includes the mechanical energy, loss, and electrical storage energy.…”

Section: Introductionmentioning

confidence: 99%

Structural Optimization Study on a Three-Degree-of-Freedom Piezoelectric Ultrasonic Transducer

Wu,

Zhang,

et al. 2024

Actuators

View full text Add to dashboard Cite

A three-degree-of-freedom (3-DOF) piezoelectric ultrasonic transducer is a critical component in elliptical and longitudinal ultrasonic vibration-assisted cutting processes, with its geometric structure directly influencing its performance. This paper proposes a structural optimization method based on a convolutional neural network (CNN) and non-dominated sorting genetic algorithm II (NSGA2). This method establishes a transducer lumped model to obtain the electromechanical coupling coefficients (X-ke and Z-ke) and thermal power (X-P) indicators, evaluating the bending and longitudinal vibration performance of the transducer. By creating a finite element model of the transducer with mechanical losses, a dataset of different transducer performance parameters, including the tail mass, piezoelectric stack, and dimensions of the horn, is obtained. Training a CNN model with this dataset yields objective functions for the relationship between different transducer geometric structures and performance parameters. The NSGA2 algorithm solves the X-ke and Z-ke objective functions, obtaining the Pareto set of the transducer geometric dimensions and determining the optimal transducer geometry in conjunction with X-P. This method achieves simultaneous improvements in X-ke and Z-ke of the transducer by 22.33% and 25.89% post-optimization and reduces X-P to 18.97 W. Furthermore, the finite element simulation experiments of the transducer validate the effectiveness of this method.

show abstract