Modelling of the Plasma–Sheath Boundary Region in Wall-Stabilized Arc Plasmas: Unipolar Discharge Properties.
Date
2017
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Abstract
A two-dimensional model of the non-equilibrium unipolar discharge occurring
in the plasma–sheath boundary region of a transferred-arc was developed. This model was
used to study the current transfer to the nozzle (1 mm diameter) of a 30 A arc cutting torch
operated with oxygen. The energy balance and chemistry processes in the discharge were
described by using a kinetic block of 45 elementary reactions and processes with the
participation of 13 species including electronically excited particles. The nonlocal transport of electrons was accounted for into the fluid model. The dependence of the ion
mobility with the electric field was also considered. Basic discharge properties were
described. It has been found that a large part (* 80%) of the total electric power
(1700 mW) delivered in the bulk of the sheath region is spent in heating the positive ions
and further dissipated through collisions with the neutral particles. The results also showed
that the electron energy loss in inelastic collisions represents only * 25% of the electron
power and that about 63% of the power spent on gas heating is produced by the ion–
molecule reaction, the electron–ion and ion–ion recombination reactions, and by the
electron attachment. The rest of the power converted into heat is contributed by dissociation by electron-impact, dissociative ionization and quenching of O(1
D). Some fast gas
heating channels which are expected to play a key role in the double-arcing phenomena in
oxygen gas were also identified.
Description
Keywords
Plasma–sheath., Wall-stabilized arc., Unipolar discharge.
Citation
Plasma Chem Plasma Process.
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