Controlled acoustic levitation — physical model and real-time digital implementation

To resolve the issues of the conventional dust removing method, such as electrostatic suspension and direct wiping with special lens paper, which can cause damage to precision instruments and their dependence on specific dust particle properties, we present a novel acousticlevitation device design which incorporates an initial design of a multi-axis levitation device by Marzo. A. with our enhancement model based on the variation of transducers numbers and their spacing to achieve the dust removing efficiency and feasibility in real dust removal process. In this work, modeling simulation in COMSOL Multiphysics and light absorbance experiment are performed to evaluate the distribution of acoustic fields, trajectory of dust particles, and dust removing efficiency. With the manufactured device based on our design, the varying factors are characterized that may influence the removing efficiency when output voltage generated onto motor driven board is altered. Experiment shows 27.5 V is the most efficient voltage output with highest dust removal proportion in actual removing operations. The study demonstrates our design can achieve higher dust removing efficiency comparing to conventional methods. Whereas our design serves the purpose to solve a practical industrial problem, this paper also shows how it can be taken into the classroom as an demonstration experiment, providing an animated way to visualize the nodes and antinodes by the levitation position of particles, which help the students to not only understand the physical properties of standing waves, but also the connection from a classroom lab to an industrial solution.

show abstract

“…The levitation height is controlled by several physical parameters but mostly by the squeeze number, (Gabai et al 2017;Bucher et al 2016):…”

Section: Simulation Of Acoustic Fieldsmentioning

confidence: 99%

Design and Test of a Multi-Axis Acoustic-Levitation Device for Non-Contact Dust Removal from Precision Instruments

Niu

Che

et al. 2020

REAL

View full text Add to dashboard Cite

show abstract

Ultrasonic Levitation with Software-Defined FPGAs and Electronically Phased Arrays

Beasley

Gatusch

Connolly-Taylor

et al. 2019

2019 NASA/ESA Conference on Adaptive Hardware and Systems (AHS)

View full text Add to dashboard Cite

Precise Resonance Frequency Tracking Based on a DSP-Implemented Virtual Vector Voltmeter

Dörsam,

Suppelt,

Bossert

et al. 2024

2024 IEEE Ultrasonics, Ferroelectrics, and Frequency Control Joint Symposium (UFFC-JS)

View full text Add to dashboard Cite

Controlled acoustic levitation — physical model and real-time digital implementation

Cited by 3 publications

References 21 publications

Design and Test of a Multi-Axis Acoustic-Levitation Device for Non-Contact Dust Removal from Precision Instruments

Design and Test of a Multi-Axis Acoustic-Levitation Device for Non-Contact Dust Removal from Precision Instruments

Ultrasonic Levitation with Software-Defined FPGAs and Electronically Phased Arrays

Precise Resonance Frequency Tracking Based on a DSP-Implemented Virtual Vector Voltmeter

Contact Info

Product

Resources

About