物理学报2018,Vol.67Issue(3):225-233,9.DOI:10.7498/aps.67.20171805
耦合双泡声空化特性的理论研究
Theoretical study of coupling double-bubbles ultrasonic cavitation characteristics
摘要
Abstract
When the distances between bubbles are small enough, the pressure acting on the bubble is not the same as the external driving pressure, because of the radiation pressure wave of the neighboring bubbles. The force between two bubbles due to the bubble-radiated pressure waves by the neighboring bubbles is called the secondary Bjerknes force. Considering the bubble-radiated pressure waves and using the modified Keller-Miksis equation and van der Waals equation, the changes of the radius, the secondary Bjerknes force and the temperature of the double bubbles, which have different sizes, interspaces in between, and noble gases, in the process of ultrasonic cavitation are calculated. The calculations are based on the assumption that the locations of double bubbles stay unchanged in the oscillation process and their shapes always keep spherical. The double bubbles can also oscillate synchronously under the influence of the driving ultrasonic field. Because the sound propagation speed in water extremely fast, the time-delay effect on the secondary Bjerknes force is neglected. From the calculated results, the following conclusions can be drawn: when the sizes of double bubbles are different, the smaller bubble is more restrained and the temperature change is larger. When the sizes of double bubbles are the same, the Bjerknes force is negative, indicating that the coupled double bubbles are attracted to each other during the oscillation and the Bjerknes force has two radial oscillations in one driving period. As the interspace between double bubbles increases from 100 μm to 1 cm, the secondary Bjerknes force decreases from 10?4 N to 10?8 N, indicating that the interaction between double bubbles increases with the decreasing of the distance between the bubbles. The coupling double bubbles with different noble gases have only a small difference in maximum radius in the stage of expansion, but have different oscillation patterns clearly in the stage of rebound. This is because the bubble expansion process can be seen as an isothermal process, the effective polytropic exponentγ is approximately equal to 1. The collapse process can be regarded as an adiabatic process, so the effective polytropic exponentγ of noble gas with large molecules changes rapidly, and the influence of the oscillation of the bubbles becomes large. Our work provides a theoretical basis for establishing the acoustic cavitation model of different-number bubbles, and calculating the interaction force between different-number bubbles.关键词
次Bjerknes力/惰性气体/温度Key words
secondary Bjerknes force/noble gas/temperature引用本文复制引用
王德鑫,那仁满都拉..耦合双泡声空化特性的理论研究[J].物理学报,2018,67(3):225-233,9.基金项目
国家自然科学基金(批准号:11462019)资助的课题.Project supported by the National Natural Science Foundation of China(Grant No. 11462019). (批准号:11462019)
