Abstract EN:

Liquid-gas foams are a cellular system, where the bubbles forms cells surrounded by liquid. The liquid drains out of it by gravity and capillarity; this is the phenomenon of drainage. The subject of this work consisted in a study of the different physico-chemicals aspects of the aqueous foam. It is a matter to study the effect of the rheology of the foaming fluids (polymers, surfactants) on drainage and the stability of the foams, to determine the parameters governing the processes; all that according to the physical parameters (humidity of the foams, size of the bubbles, polydispersity, etc. . ) or physico-chemicals (surfactants, additives, liquid, gasses, etc. . ). This work allowed the development of a new approach in the problematic ones of the foam. The study was done by two experimental techniques: the measure of the conductivity and multiple light scattering. The measures of the viscoelastics surface parameters (elasticity, viscosity, dynamic tension) were equally carried by method of the pendant drop. The behaviour of mixtures of water and glycerol follows the theoretical predication, but for the solutions of polymers, we observe different phenomena. We have tested four polymers solutions: Polyethylene Oxide (PEO) how has important elongational viscosity. Drainage with this solution is faster than water-glycerol mixtures of the same bulk viscosity. To understand this behaviour we study drainage with Bogger fluids that present a constant shear thinning and variable elongational viscosity. Drainage of foam made with viscous solution is slowed down. This theoretical prediction is not flowed by the PEO, for this reason we studied the drainage by using the Carbopol, which is an industrial polymer known for this effect at small quantity. The Xanthan solutions how exhibit an important shear thinning effect, slowed down the drainage. These results clarify the effect observed with PEO, how is related to the elongational viscosity. All these results are an attempt to understand the effect of the rheology of volume on forced drainage. The effects are to vary, according to the nature of the foaming fluids.