Time-dependent simulation of plasma and electrodes in high-intensity discharge lamps with different electrode shapes

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Published 19 March 2003 Published under licence by IOP Publishing Ltd
, , Citation P Flesch and M Neiger 2003 J. Phys. D: Appl. Phys. 36 849 DOI 10.1088/0022-3727/36/7/314

0022-3727/36/7/849

Abstract

The subject of this paper is the modelling of d.c. and a.c. high-intensity Hg-discharge lamps with differently shaped electrodes. Different arc attachments on the electrodes are studied and insight for the development of new electrodes is gained. The model includes the entire discharge plasma (plasma column, hot plasma spots in front of electrodes, near-electrode non-LTE-plasma) as well as anode and cathode. No subdivision of the discharge space into different regions is necessary (like space charge layer, ionization zone, plasma column). This is achieved by using a differential equation for a non-LTE electrical conductivity which is applicable for local thermal equilibrium (LTE-)regions as well as for non-LTE plasma regions close to the electrodes in a high pressure plasma. Modelling results for a 0.6 MPa mercury discharge considering six different electrode shapes (anode and cathode) are presented and compared with experimental results. The electrodes have different diameters and different electrode tips, such as hemispherical, flat, or conical tip with 60° or 90° apex angle. Furthermore, an electrode with a larger diameter in the mid section of the rod is investigated.

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10.1088/0022-3727/36/7/314