TY - JOUR
T1 - Numerical simulation of single bubble dynamics under acoustic travelling waves
AU - Ma, Xiaojian
AU - Huang, Biao
AU - Li, Yikai
AU - Chang, Qing
AU - Qiu, Sicong
AU - Su, Zheng
AU - Fu, Xiaoying
AU - Wang, Guoyu
N1 - Publisher Copyright:
© 2017 Elsevier B.V.
PY - 2018/4
Y1 - 2018/4
N2 - The objective of this paper is to apply CLSVOF method to investigate the single bubble dynamics in acoustic travelling waves. The Naiver-Stokes equation considering the acoustic radiation force is proposed and validated to capture the bubble behaviors. And the CLSVOF method, which can capture the continuous geometric properties and satisfies mass conservation, is applied in present work. Firstly, the regime map, depending on the dimensionless acoustic pressure amplitude and acoustic wave number, is constructed to present different bubble behaviors. Then, the time evolution of the bubble oscillation is investigated and analyzed. Finally, the effect of the direction and the damping coefficient of acoustic wave propagation on the bubble behavior are also considered. The numerical results show that the bubble presents distinct oscillation types in acoustic travelling waves, namely, volume oscillation, shape oscillation, and splitting oscillation. For the splitting oscillation, the formation of jet, splitting of bubble, and the rebound of sub-bubbles may lead to substantial increase in pressure fluctuations on the boundary. For the shape oscillation, the nodes and antinodes of the acoustic pressure wave contribute to the formation of the “cross shape” of the bubble. It should be noted that the direction of the bubble translation and bubble jet are always towards the direction of wave propagation. In addition, the damping coefficient causes bubble in shape oscillation to be of asymmetry in shape and inequality in size, and delays the splitting process.
AB - The objective of this paper is to apply CLSVOF method to investigate the single bubble dynamics in acoustic travelling waves. The Naiver-Stokes equation considering the acoustic radiation force is proposed and validated to capture the bubble behaviors. And the CLSVOF method, which can capture the continuous geometric properties and satisfies mass conservation, is applied in present work. Firstly, the regime map, depending on the dimensionless acoustic pressure amplitude and acoustic wave number, is constructed to present different bubble behaviors. Then, the time evolution of the bubble oscillation is investigated and analyzed. Finally, the effect of the direction and the damping coefficient of acoustic wave propagation on the bubble behavior are also considered. The numerical results show that the bubble presents distinct oscillation types in acoustic travelling waves, namely, volume oscillation, shape oscillation, and splitting oscillation. For the splitting oscillation, the formation of jet, splitting of bubble, and the rebound of sub-bubbles may lead to substantial increase in pressure fluctuations on the boundary. For the shape oscillation, the nodes and antinodes of the acoustic pressure wave contribute to the formation of the “cross shape” of the bubble. It should be noted that the direction of the bubble translation and bubble jet are always towards the direction of wave propagation. In addition, the damping coefficient causes bubble in shape oscillation to be of asymmetry in shape and inequality in size, and delays the splitting process.
KW - Acoustic travelling wave
KW - Bubble dynamics
KW - CLSVOF
KW - Radiation force
UR - http://www.scopus.com/inward/record.url?scp=85038848875&partnerID=8YFLogxK
U2 - 10.1016/j.ultsonch.2017.12.021
DO - 10.1016/j.ultsonch.2017.12.021
M3 - Article
C2 - 29429710
AN - SCOPUS:85038848875
SN - 1350-4177
VL - 42
SP - 619
EP - 630
JO - Ultrasonics Sonochemistry
JF - Ultrasonics Sonochemistry
ER -