A numerical study of cavitation and bubble dynamics in liquid CO2 near the critical point

This study aims to provide insights into the cavitation and bubble dynamics in liquid CO2 near the critical point. It is inspired by a previous work that reports the absence of dysfunctional behavior during the operation of a test compressor in the two-phase region of CO2. First, several characteristic parameters in the literature have suggested that thermal effects have significant impact on the dynamics of a CO2 bubble. These effects lead to the change of vapor pressure inside the bubble, impeding the motion of the bubble interface. As a consequence, the CO2 bubble collapse should feature a slow contraction of the bubble interface and the absence of noticeable pressure rise. In addition, a dynamic model has been proposed to quantitatively study the bubble collapse in liquid CO2 near the critical point. Simulation results have confirmed the qualitative prediction given by characteristic parameters. They have also revealed that the thermal layer inside the bubble has an important contribution to the bubble dynamics, in addition to the one outside the bubble, by altering the rate of phase change at the interface. These predicted results appear to be in line with the aforementioned experimental observations.

Hong-Son Pham, Nicolas Alpy, S. Mensah, Mark Tothill, Jean-Henry Ferrasse, et al.. A numerical study of cavitation and bubble dynamics in liquid CO2 near the critical point. International Journal of Heat and Mass Transfer, 2016, 102, pp.174-185. ⟨10.1016/j.ijheatmasstransfer.2016.06.005⟩. ⟨hal-01461785⟩

Journal: International Journal of Heat and Mass Transfer

Date de publication: 01-01-2016

Auteurs:
  • Hong-Son Pham
  • Nicolas Alpy
  • S. Mensah
  • Mark Tothill
  • Jean-Henry Ferrasse
  • Olivier Boutin
  • Johann Quenaut
  • Gilles Rodriguez
  • Manuel Saez



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