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Abstract
Ultrasonic dental scalers are indispensable instruments for efficient dental cleaning through the generation of cavitation. To gain valuable insights and enhance the cavitation cleaning effects, a numerical investigation is conducted using the finite element method via ABAQUS. Numerical results are compared with the experimental cavitation image for a scaler undergoes vibrations near a wall. We then analyse how the amplitude, frequency, and cross-sectional shape of the scaler affect cavitation generation. Numerical results indicate that cavitation is more pronounced for a scaler oscillating near a nearly rigid boundary than a soft boundary. It increases with the vibration amplitude because of higher ultrasonic energy transferring to the liquid and generating stronger pressure waves. The resonant frequency of the scaler coincides with the maximum cavitation and scaler tip amplitude. Reducing the dimension of the cross-section of the scaler in its oscillation direction increases both the scaler tip amplitude and the cavitation generated. This finding offers a potential design approach for enhancing the scaler cavitation and its cleaning effects. These insights provide practical guidance for optimising dental scaler settings, which can improve oral hygiene and prevent complications related to dental implants.
Original language | English |
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Article number | 106625 |
Number of pages | 9 |
Journal | Ultrasonics Sonochemistry |
Volume | 100 |
Early online date | 30 Sept 2023 |
DOIs | |
Publication status | Published - Nov 2023 |
Bibliographical note
Acknowledgement:This work was funded partially by the Engineering and Physical Sciences Research Council (EPSRC) grant number EP/P015743/1. The computations described in this paper were performed using the University of Birmingham's BlueBEAR HPC service, which provides a High Performance Computing service to the University's research community. See http://www.birmingham.ac.uk/bear for more details.
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- 1 Finished
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Maximising cavitation to clean dental implants
Engineering & Physical Science Research Council
1/07/17 → 31/05/21
Project: Research