Testing of Aluminium Carbide Formation in Hall-Heroult Electrolytic Cell

Stanislaw Pietrzyk; Piotr Palimaka

doi:10.4028/www.scientific.net/MSF.654-656.2438

Paper Titles

Post-Hydrogen Permeation Characterization of V-Based Crystalline Alloy Membranes
p.2422

High-Throughput Evaluation of Crystallization Temperature of Pd-Cu-Si System Using Integrated Thin Film Samples
p.2426

Structural Characterization of Electrodeposited Nickel-Iron Alloy Films
p.2430

Surface Damage in Riveted Aircraft Aluminium Lap Joints, in the Presence of Lubricants
p.2434

Testing of Aluminium Carbide Formation in Hall-Heroult Electrolytic Cell
p.2438

Thermodynamic Evaluation of the Fe-Pr Binary System
p.2442

Nanoindentation Characterization of Intermetallics Formed at the Lead-Free Solder/Cu Substrate Interface
p.2446

Formation and Mechanical Properties of Intermetallic Compounds in Sn-Cu High-Temperature Lead-Free Solder Joints
p.2450

Micro-Scratching of UHMW Polyethylene Surfaces
p.2455

HomeMaterials Science ForumMaterials Science Forum Vols. 654-656Testing of Aluminium Carbide Formation in...

Testing of Aluminium Carbide Formation in Hall-Heroult Electrolytic Cell

Abstract:

The trend in the aluminium smelting industry today is to operate cells with graphitized carbon cathode linings, increased current density and acidic bath chemistry. The resulting problem is an accelerated wear of graphitized cathode blocks, thought to be caused by formation and subsequent dissolution of Al4C3 at the cathode lining surface. The cycle of formation and subsequent dissolution Al4C3 is recognized as one of the most important mechanism causing pothole and surface wear, which results in limiting of the cell lifetime and loss efficiency. A special laboratory test method was developed to elucidate the mechanism of Al4C3 formation in electrolytic cell. The Al4C3 formation in the region between the carbon surface and aluminium as well as between the carbon surface and electrolytic bath has also been studied using X-ray diffraction, as well as optical and scanning electron microscopy. Solid Al4C3 layer was observed at the carbon surface. A possible mechanism which explains the presence of Al4C3 at the metal-bath interface is the transfer of dissolved carbide in the bath from metal-carbon interface.