Numerical Analysis of the Influence of Low Frequency Vibration on Bubble Growth

Published: May 02, 2017

Author(s)

Dong Han, Mark A. Kedzierski

Abstract

Numerical simulation of bubble growth during pool boiling under the influence of low frequency vibration was done to understand the influence of common vibrations such as those induced by wind, highway transportation, and nearby mechanical devices on the performance of thermal systems that rely on boiling. The simulations were done for saturated R123 boiling at 277.6 K with a 15 K wall superheat. The numerical volume-of-fluid method (fixed grid) was used to define the liquid-vapor interface. The basic bubble growth characteristics including the bubble departure diameter and the bubble departure time were determined as a function of the bubble contact angle (20 – 80), the vibration displacement (10 m – 50 m), the vibration frequency (5 Hz – 25 Hz), and the initial vibration direction (positive or negative). The bubble parameters were shown to be strongly dependent on the bubble contact angle at the surface. For example, both the bubble departure diameter and the bubble departure time increased with the contact angle. At the same vibration frequency and the initial vibration direction, the bubble departure diameter and the bubble departure time both decreased with increasing vibration displacement. In addition, the vibration frequency had a greater effect on the bubble growth characteristics than did the vibration displacement. The vibration frequency effect was strongly influenced by the initial vibration direction. The pressure contour, the volume fraction of vapor phase, the temperature profile, and the velocity vector were investigated to understand these dynamic bubble behaviors. The limitation of the computational fluid dynamics approach was also described.
Citation: International Journal of Transport Phenomena
Pub Type: Journals

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Keywords

vibration, pool boiling, bubble departure diameter, bubble departure time, VOF, CFD
Created May 02, 2017, Updated May 02, 2017