Title :
Coupling of Anode and Cathode Torches Perpendicularly Arranged in a Discharge Chamber
Author :
Yan, Jiu D. ; Tang, Kah M. ; Fang, Michael T C
Author_Institution :
Dept. of Electr. Eng. & Electron., Univ. of Liverpool, Liverpool, UK
Abstract :
An atmospheric arc-plasma system employing two gas-shielded torches aligned obtusely has a high-temperature coupling zone that is sufficiently faraway from the tips of both electrodes to achieve minimum contamination by electrode erosion and is thus used for the production of micro- and nanopowders. Such an arc plasma exhibits a strong 3-D structure within the coupling zone, and results in this paper obtained from a steady-state arc model show that, for the first time, the two torches are coupled through a tissue-like conducting layer for an electric-current return. The thickness of the layer is less than 6 mm in comparison with the typical dimension of 20 mm of the torches in the coupling zone. The Lorentz force resulting from a “Y” shaped current path and strong ohmic heating, dominate the coupling process.
Keywords :
anodes; arcs (electric); cathodes; plasma collision processes; plasma fluctuations; plasma torches; plasma transport processes; 3D structure; Lorentz force; Y-shaped current path; anode torch; arc plasma; atmospheric arc-plasma system; cathode torch; discharge chamber; electric-current return; electrode erosion; gas-shielded torches; high-temperature coupling zone; micropowder; nanopowder; ohmic heating; steady-state arc model; tissue-like conducting layer; Anodes; Argon; Cathodes; Couplings; Lorentz covariance; Plasmas; Solid modeling; Arc plasma devices; atmospheric thermal plasma; computational investigation;
Journal_Title :
Plasma Science, IEEE Transactions on
DOI :
10.1109/TPS.2011.2152861
