Use this feature to model packed bed reactors with catalytic pellets. For details, see the section
Theory for the Reactive Pellet Bed. By default, subnodes for Reactions and are added.
Here you can specify the bed porosity, which is the void fraction in the packed bed structure. Select From densities to calculate the porosity from the bed density and the individual pellet density. Select
User defined to specify the porosity directly.
In order to add surface species, click the Add button and enter the species name in the
Surface species table. Added surface species are be available inside all pellet types defined in the
Pellet Shape and Size section, but not in the bulk fluid.
Enter a Pellet porosity εpe (dimensionless) to specify the porosity of the pellet internals.
Select Diffusion model —
Millington and Quirk model (the default),
Bruggeman model,
Tortuosity model, or
User defined to describe the effective correction of the diffusion coefficient in the pellet. In the case of the
Tortuosity model, a value for the tortuosity
τpe within the pellet is required.
Enter also the Diffusion coefficient Dpe,c (SI unit: m
2/s). If a
User defined diffusion model is selected, an
Effective diffusion coefficient Dpeff,c (SI unit: m
2/s) is entered. The default value is 1·10
-9 m
2/s in both cases.
The Film resistance (mass flux) option computes the inward surface flux,
Ni,inward=hDi(ci-cpe,i).
hDi is the mass transfer coefficient (SI unit: m/s) and is calculated with the default
Automatic setting from a dimensionless
Sherwood number expression or with
User defined mass transfer coefficients.
The Active specific surface area (SI unit: m
-1) is required to couple the mass transfer between the pellets and the bed fluid. Select either the
Automatic setting that calculates the specific surface area from the shape information given above. User defined is also available for explicit surface area specification.
The Sherwood number expression can be computed from three available expressions:
Frössling,
Rosner, and
Garner and Keey. The Frössling equation is the default and probably the most commonly used for packed spheres. All of these are based on the dimensionless Reynolds,
Re, and Schmidt,
Sc, numbers, which are computed from
Density and
Dynamic viscosity. Select these to be taken either
From material or choose the
User defined alternative.
To display this section, click the Show button (
) and select
Advanced Physics Options. See the details about the different constraint settings in the section
Constraint Reaction Terms in the
COMSOL Multiphysics Reference Manual.
Theory for the Reactive Pellet Bed in the Theory section of this manual.