THERMAL SCIENCE

International Scientific Journal

MEASUREMENT OF PHASE INTERACTION IN DISPERSED GAS-PARTICLE TWO-PHASE FLOW BY PHASE-DOPPLER ANEMOMETRY

ABSTRACT
For simultaneous measurement of size and velocity distributions of continuous and dispersed phases in a two-phase flow a technique phase-Doppler anemometry was used. Spherical glass particles with a particle diameter range from 102 up to 212 µm were used. In this two-phase flow an experimental results are presented which indicate a significant influence of the solid particles on the flow characteristics. The height of influence of these effects depends on the local position in the jet. Near the nozzle exit high gas velocity gradients exist and therefore high turbulence production in the shear layer of the jet is observed. Here the turbulence intensity in the two-phase jet is decreased compared to the single-phase jet. In the developed zone the velocity gradient in the shear layer is lower and the turbulence intensity reduction is higher. .
KEYWORDS
PAPER SUBMITTED: 2007-11-28
PAPER REVISED: 2008-02-17
PAPER ACCEPTED: 2008-02-20
DOI REFERENCE: https://doi.org/10.2298/TSCI0802059M
CITATION EXPORT: view in browser or download as text file
THERMAL SCIENCE YEAR 2008, VOLUME 12, ISSUE Issue 2, PAGES [59 - 68]
REFERENCES
  1. Crowe, C. T., Sommerfield, M., Tsuji, Y., Multiphase Flows with Droplets and Particles, CRC Press, Boca Raton, Fla, USA, 1998
  2. Elgobashi, S., Particle-Laden Turbulent Flows: Direct Simulation and Closure Models, Applied Science res. 48 (1991), 3-4, pp. 301-314
  3. Simonin, O., Prediction of the Dispersed Phase Turbulence in Particle-Laden Jets, Proceedings, 4th International Symposium on Gas-Solid Flows, Portland, Ore., USA, 1991, pp. 23-26
  4. Berlemont, A., Desjonqueres, P., Gouesbet, G., Particle Lagrangian Simulation in Turbulent Flows, International Journal of Multiphase Flow, 16 (1990), 1, 19-34.
  5. Berlemont, A., Grancher, M. S., Gouesbet, G., Heat and Mass Transfercoupling Between Vaporizing Droplets and Trubulence Using A lagrangian Approach, International Journal of Heat Mass Transfer, 38 (1995), 16, pp. 3023-3034
  6. Desjonqueres, P., Modeling Lagrangien of the Behavior of Discrete Particles in Turbulent Flow, Ph. D. thesis, University of Rouen, France, 1987
  7. Sommerfeld, M., Lain, S., Turbulence Modulation In Dispersed Two-Phase Flow Laden With Solids from a Lagrangian Persepective, International Journal of Multiphase Flow, 24 (2003), 4, pp. 616-625
  8. Hetsroni, S., Sokolov, G., Distribution of Mass, Velocity, and Intensity of Turbulence in a Two-Phase Turbulent Jet, Journal Applied Mechanics, 38 (1971), 2, pp. 315-327
  9. Prévost, F., Behavior of Solid Particles Polydispersed in aTurbulent Air Blast, Ph. D. thesis, I. N. P., Toulouse, France, 1994
  10. Prévost, F., et al., Measurements of Fluid-Particle Correlated Motion in the Far Field of an Axisymmetric Jet, International Journal Multiphase Flow, 22 (1996), 4, pp. 685-701
  11. Lee, S. L., Durst, F., On the Motion of Particles in Turbulent Duct Flows, International Journal Multiphase Flow, 8 (1982), 2, pp. 125-146
  12. Modarress, D., Tan, H., Elghobashi, S., Two Component LDA Measurement in a Two-Phase Turbulent Jet, AIAA Journal, 22 (1984), 5, pp. 624-630
  13. Tsuji, Y., Morikawa, Y., Shiomi, H., LDV Measurements of an Air-Solid Two Phase Flow in a Vertical Pipe, Journal Fluid Mechanics, 139 (1984), pp. 417-434
  14. Hardalupas, Y., Taylor, A., Whitelaw, J., Velocity and Particle Flux Characteristics of Turbulent Particle-Laden Jets, Proc. R. Soc. London, 1989, A 426, pp. 31-78
  15. Longmire, E. K., Eaton, J. K., Structure of a Particle-Laden Round Jet, Journal Fluid Mechanics, 236 (1992), pp. 217-257
  16. Mergheni. M. A., et al., Aplication of Anemometry to Doppler Phase in a Turbulent Flow Diphasic Gas-Particles, 18eme Congres Francais de Mécanique, Grenoble, France, 2007
  17. Warda, H. A., et al., Influence of the Magnitude of the Two Initial Velocities on the Flow Field of a Coaxial Turbulent Jet, Flow Measurement and Instrumentation, 12 (2001), 1, pp. 29-35

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