Using ANSYS and CFX to Model Aluminum Reduction Cell since 1984 and Beyond
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References:
1) M. Dupuis, "Computation of Aluminum reduction Cell Energy Balance Using ANSYS® Finite
Element Models", TMS Light Metals, (1998), 409-417.
2) M. Dupuis, "Aluminum Electrolysis Process Simulation", Analysis Solutions, (Spring 1998), 26-
31.
3) M. Dupuis and C. Fradet, "Using ANSYS® Based Aluminum Reduction Cell Energy Balance
Models to Assist Efforts to Increase Lauralco's Smelter productivity", Proceeding of the ANSYS®
8
th
International Conference, volume 2, 2.233-2.240, (1998).
4) M. Dupuis and al., "Cathode Shell Stress Modelling", TMS Light Metals, (1991), 427-430.
5) M. Dupuis and I. Tabsh, "Thermo-Electric Analysis of Aluminum Reduction Cells", CIM Light
Metals, (1992), 55-62.
6) D. J. Parrish, "The ANSYS Program in Materials", ANSYS News, (Forth Issue 1993), 10-25.
More specifically see section "ANSYS in the Aluminum Industry", 13-16.
7) M. Dupuis, "Computation of Accurate Horizontal Current Density on Metal Pad using a Full
Quarter Cell Thermo-electric Model", CIM Light Metals, (2001), 3-11.
8) M. Dupuis and I. Tabsh, "Thermo-Electro-Magnetic Modeling of a Hall-Héroult Cell", ",
Proceeding of the ANSYS
®
Magnetic Symposium,
9.3-9.13, (1994).
9) G. V. Asadi, M. Dupuis and I. Tabsh "Shell Design Technique Considering the Sodium Swelling
Phenomenon of Carbon Cathode Blocks" CIM Light Metals, (1993), 125-130.
10) M. Segatz and D. Vogelsang, "Effect of Steel Parts on Magnetic Fields in Aluminum Reduction
Cells", TMS Light Metals, (1991), 393-398.
11) M. Dupuis and al, "Thermal Study of the Coke Preheating for Hall-Héroult Cell", CIM Light
Metals, (1993), 93-100.
12) M. Dupuis and I. Tabsh, "Evaluation of Thermal Stresses due to Coke Preheat of a Hall-Héroult
Cell", Proceeding of the ANSYS
®
6
th
International Conference, vol. 1, 3.15-3.23, (1994).
13) M. Dupuis, "Usage of a Full 3D Transient Thermo-electric F.E. Model to Study the Thermal
Gradient Generated in the Lining during a Coke Preheat", TMS Light Metals, (2001), 757-761.
14) M. Dupuis, "Modeling Power Modulation", TMS Light Metals, (2002), 489-493.
15) M. Dupuis and R. Lacroix, "Development of a 2D+ Dynamic Model of an Aluminum Reduction
Cell", CIM Light Metals, (1999), 41-55.
16) M. Dupuis, "Thermo-Electric Design of a 400 kA Cell using Mathematical Models: A Tutorial",
TMS Light Metals, (2000), 297-302.
17) M. Dupuis, "Development of a 3D Transient Thermo-electric Cathode Panel Erosion Model of an
Aluminum Reduction Cell", CIM Light Metals, (2000), 169-178.
18) D. Richard and al., "Thermo-electro-mechanical Modelling of the Contact between Steel and
Carbon Cylinders using the Finite Element Method", TMS Light Metals, (2000), 523-528.
19) D. Richard, "Conception des tourillons d'anode en usage dans une cuve de Hall-Héroult à l'aide
de la méthode des éléments finis", Master Thesis Chemical Engineering Laval University, (2000).
20) I. Eick and D. Vogelsang, "Dimensioning of Cooling Fins for High-Amperage Reduction Cells",
TMS Light Metals, (1999), 339-345.
21) M. Dupuis, "3D Modeling of the Ventilation Pattern in an Aluminium Smelter Potroom Building
using CFX-4", Proceedings of the CFDSC Conference, (2001), 161-166.
22) C. Vanvoren and al., "AP 50: The Pechiney 500 kA cell", TMS Light Metals, (2001), 221-226.