论文信息 - Bubble size distribution and energy dissipation in foam mixers

Bubble size distribution and energy dissipation in foam mixers

The bubble size distribution of a foam produced in a rotor-stator mixer has been determined as a function of several mixing parameters such as the rotor speed, residence time, gas/liquid ratio and the viscosity of the liquid used. A Newton-Reynolds expression for a foam mixer has been determined using energy consumption measurements. Two types of shear fields have been distinguished in the foam mixer, laminar and turbulent, the type of shear field depending on the properties of the foam mixer. After a certain mixing time the bubble size distribution characterised by the mean bubble size was found to reach a stationary value. The stationary bubble size distribution has been correlated with the mixing conditions by a critical Weber number. Both in the laminar and in the turbulent shear field bubble size distributions have been determined as a function of several mixing parameters.

A B J Kroezen | J Groot Wassink | J. Wassink | A. B. J. Kroezen

[1] G. Batchelor,et al. Pressure fluctuations in isotropic turbulence , 1951, Mathematical Proceedings of the Cambridge Philosophical Society.

[2] B. Gal-or. Coupled heat and multicomponent mass transfer in particulate systems with residence time and size distributions , 1968 .

[3] Lawrence L. Tavlarides,et al. A simulation model for homogeneous dispersions in stirred tanks , 1980 .

[4] Doraiswami Ramkrishna,et al. A coalescence redispersion model for drop-size distributions in an agitated vessel , 1976 .

[5] S. Saito,et al. SIMULATION MODEL FOR BREAKUP PROCESS IN AN AGITATED TANK , 1980 .

[6] Geoffrey Ingram Taylor,et al. The Viscosity of a Fluid Containing Small Drops of Another Fluid , 1932 .

[7] R. Lemlich,et al. The effect of initial bubble size distribution on the interbubble gas diffusion in foam , 1979 .

[8] A. B. Metzner. Agitation of non‐Newtonian fluids , 1957 .

[9] S. G. Mason,et al. Particle motions in sheared suspensions XII. Deformation and burst of fluid drops in shear and hyperbolic flow , 1961 .

[10] Geoffrey Ingram Taylor,et al. The formation of emulsions in definable fields of flow , 1934 .