Simulations of Cryogenic Cavitation of Low Temperature Fluids with Thermodynamics Effects
Authors: A. Alhelfi, B. Sunden
Abstract:
Cavitation in cryogenic liquids is widely present in contemporary science. In the current study, we re-examine a previously validated acoustic cavitation model which was developed for a gas bubble in liquid water. Furthermore, simulations of cryogenic fluids including the thermal effect, the effect of acoustic pressure amplitude and the frequency of sound field on the bubble dynamics are presented. A gas bubble (Helium) in liquids Nitrogen, Oxygen and Hydrogen in an acoustic field at ambient pressure and low temperature is investigated numerically. The results reveal that the oscillation of the bubble in liquid Hydrogen fluctuates more than in liquids Oxygen and Nitrogen. The oscillation of the bubble in liquids Oxygen and Nitrogen is approximately similar.
Keywords: Cryogenic liquids, cavitation, rocket engineering, ultrasound.
Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1337945
Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 2669References:
[1] V. A. Akulichev, “Acoustic cavitation in low temperature liquids,” Ultrasonics, 1986, pp. 8–18.
[2] C. C. Tseng, and W. Shyy, “Turbulence modeling for isothermal and cryogenic cavitation,” in Proc. 47th AIAA Aerospace Sciences Meeting Including The New Horizons Forum and Aerospace Exposition, Orlando, Florida, 5 - 8 January 2009, Paper No. AIAA 2009-1215.
[3] A. Hosangadi, and V. Ahuja, “Numerical study of cavitation in cryogenic fluids,” Journal of Fluids Engineering, Vol. 127, pp. 267–281, 2005.
[4] N. Tani, S. Tsuda, N. Yamanishi, and Y. Yoshida, “Development and validation of new cryogenic cavitation model for rocket turbopump inducer,” in Proc. 7th International Symposium on Cavitation, Ann Arbor, Michigan, USA, 17-22 August, 2009, Paper No. 63.
[5] E. Goncalves, and R. F. Patella, “Constraints on equation of state for cavitating flows with thermodynamic effects,” Applied Mathematics and Computation, Vol. 2177, pp. 5095–5102, 2011.
[6] M. Giorgi, and A. Ficarella, “Simulation of cryogenic cavitation by Using both inertial and heat transfer Control bubble growth,” in Proc. 39th AIAA Fluid Dynamics Conference, San Antonio, Texas, 22 - 25 June 2009, Paper No. AIAA 2009-4039.
[7] A. Alhelfi, and B. Sunden, “Bubble power and ultrasound,” International Journal of Enhanced Research in Science Technology & Engineering, Vol. 2, No. 11, pp.130-134, 2013.
[8] P. Lebrun, “An introduction to cryogenics,”European Organization for Nuclear Research, Laboratory for Particle Physics, Departmental Report No. CERN/AT 2007-1.
[9] A. Alhelfi, “On bubble dynamics in acoustic cavitation,” Thesis for the Degree of Licentiate of Engineering, Energy Sciences Dept., Sweden.
[10] A. Alhelfi, B. Sunden, and J. Yuan, “ Modeling of spherical gas bubble oscillation in acoustic pressure field,” in Proc. 8th International Conference on Multiphase Flow, ICMF 2013, Korea, 26 – 31 May, 2013, Paper No. ICMF2013-224.
[11] J. B. Keller, and I. I. Kolodner, “Damping of underwater explosion bubble oscillations,” J. Applied Physics, Vol. 27, No.10, pp. 1152-1161, 1965.