electrodialysis cell a tutorial model. introduction electrodialysis –a separation process for...
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Electrodialysis CellA Tutorial Model
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Introduction
• Electrodialysis– A separation process for electrolytes based on the use of electric fields and ion selective
membranes
• Applications– Desalination of process streams, effluents, and drinking water– pH regulation in order to remove acids from, for examples fruit juices and wines (when you
cannot add caustic)– Metal winning (precious metals)
Electrodialysis cell. Image courtesy: Argonne National Laboratory
Bench-scale electrodialysis stack with ~10 to100 unit cells
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Model Definition, the Electrodialysis StackSchematic picture with 3 desalination units (in reality 10 - 20)
Cathode:NegativeElectrode
Anode:PositiveElectrode
Diluate
Diluate
Concentrate
Concentrate
ElectrodeStream
ElectrodeStream
ElectrodeStream
ElectrodeStream
OH -
SO4 2-
Na +
Cl -Cl -
Na + Na +Na +
Cl -
Na +Na + Na +
Cl -Cl - Cl -SO4 2- SO4
2-
Na +
H +
Cathode reaction: 2H2O +2e- -> H2 + 2OH-
Anode reaction: H2O -> 1/2O2 + 2H+ + 2e-
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Model Definition, the Model Geometry
Na +
Cl -
Na + Na +
Cl -Cl -
The repetitive unit cell with one desalination unit
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Model Definition, a First Approximation
• Parallel free channels with planar structure– In reality, cells are equipped with spacers for mechanical stability and increased mass transport in the
direction perpendicular to the main flow
• Variations in composition and potential along height and width are relatively large while they are small along the depth
– 2D simplification of the 3D geometry
Na +
Cl -
Na + Na +
Cl -Cl -
Na
+
Cl -
Na
+
Na
+
Cl -
Cl -
3D 2D
Approximation
Depth
ModelGeometry
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Model Definition, Equations
• Transport using the Nernst-Planck equations– Flux = diff. + conv. + migration– Conservation of species– Predefined flow field
• Charge separation controlled throughPoisson’s equation– Membrane charge is included in the charge
density– Other species can be included as supporting
electrolyte in the channels
Diluate channel
Cation selective membrane
Anion selective membrane
½ concentrate channel
½ concentrate channel
1 mm 0.5 mm
0.5 mm
0.25 mm
0.2 m
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Model Definition, Boundary Conditions
• Separate species balances for the channels and the membranes
– Donnan equilibrium and flux continuity for species at channel/membrane boundaries
– Given inlet fluxes and convective flux at outlets
– Periodic boundary conditions at the boundaries running along the middle of the concentrate channels
• Ionic potential set at the middle of the concentrate channels and continuity at the channel/membrane boundaries
• All other conditions are insulating conditions
Diluate channel
Cation selective membrane
Anion selective membrane
½ concentrate channel
½ concentrate channel
1 mm 0.5 mm
0.5 mm
0.25 mm
0.2 m
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Model Results
Diluate concentration, Na+ Concentrate concentration, Na+
Diffusion
Migration
Net x-flux ≈ 0 Net x-flux ≈ 0
Diffusion
Migration
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Model Results
Diluate concentration, Cl- Concentrate concentration, Cl-
Diffusion
Migration
Net x-flux ≈ 0 Net x-flux ≈ 0
Diffusion
Migration
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Model Results, Cross Section along the Middle of the Cell
Concentration profile, Na+ Concentration profile, Cl-
CationSelectiveMembrane
AnionSelectiveMembrane
CationSelectiveMembrane
AnionSelectiveMembrane
DonnanEquilibria
DonnanEquilibria
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The Influence of Spacer in the Flow Channels
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Model Definition
• Spacers are introduced in the middle of the flow channels– This means that the flow field
cannot be predefined as in the previous model, it has to be solved for.
• Boundary conditions for the spacer walls are insulating conditions except for the flow field where slip conditions are applied
Cation selective membrane
Anion selective membrane
0.2 m
0.5 mm
0.25 mm
1 mm 0.5 mm
Diluate channel
½ concentrate channel
Schematic SpacerGeometry
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Model Results, Flow Field
• The presence of spacers enhances the convective transport in the x-direction in the channels
Low flow rate High flow rate
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Model Results, Cross Section along the Middle of the Cell
Concentration profile, Na+ Concentration profile, Cl-
CationSelectiveMembrane
AnionSelectiveMembrane
CationSelectiveMembrane
AnionSelectiveMembrane
Without spacer
With spacer