dc.description.abstract | The adsorption and transport of surface active
material such as surfactant and/or protein onto the surface of a
lamella in a foam fractionation column with reflux is investigated
using mathematical simulation. The dynamics of adsorption
of protein and/or surfactant from the bulk solution onto the
surface of the foam lamella is modelled using the Ward-Tordai
equation combined with relevant adsorption isotherms such as
the Henry, Langmuir or Frumkin isotherms. Once the surface
active material is attached to the surface of the lamella and the
surface of the Plateau border, the transport of that material
(in this study is represented by surfactant in the first instance)
is modelled based on the continuity equation. There are two
approaches to the transport of surfactant discussed in this study.
One is the transport of surfactant onto a foam lamella in the
absence of surface viscosity and in the presence of film drainage.
The second approach to the transport of surfactant onto a foam
lamella includes the surface viscosity, however the effect of film
drainage is neglected to simplify the problem thus the model
provides a benchmark for a more complicated system that would
involve film drainage.
Competition between protein and surfactant may occurs in
the absorption of mixed protein-surfactant. The protein arrives
onto the interface at a later time due to a slower diffusion
rate and it displaces the surfactant molecules already on the
surface since protein has a higher affinity for that surface than
surfactant. In the absence of surface viscosity, the Marangoni
effect dominates the film drainage results in accumulation of
surfactant on the surface of the foam lamella in the case of a
lamella with a rigid interface. In the case of a film with a mobile
interface, the film drainage dominates the Marangoni effect and
surfactant is washed away from the surface of the lamella. When
the drainage is very fast, such as that which is achieved by
a film with a mobile interface, the film could be predicted to
attain the thickness of a common black film, well within the
residence time in a foam fractionation column, at which point
the film stops draining and surfactant starts to accumulate on
the lamella surface. The desirable condition in operation of a
foam fractionation column however is when the Marangoni effect
dominates the film drainage and surfactant accumulates on the
surface of a foam lamella such as the one achieved by film with
a rigid interface. In the presence of surface viscosity and the
absence of film drainage, the surface viscous forces oppose the
Marangoni effect and reduce the amount of surfactant transport
onto the foam lamella. A larger surface viscosity results in less
surfactant transport onto the foam lamella. | en_US |