DocumentCode
2213931
Title
Consequences of geometry and material properties on breakdown in high pressure lamps
Author
Moss, R.S. ; McCain, S.T. ; Eden, J. Gary ; Kushner, Mark J.
Author_Institution
Dept. of Mech. & Ind. Eng., Illinois Univ., Urbana, IL, USA
fYear
2002
fDate
26-30 May 2002
Firstpage
316
Abstract
Summary form only given. Optimizing breakdown and startup in high pressure lighting sources, such as metal-halide lamps, is of interest for both increasing electrode lifetime, by reducing voltage, and enabling re-ignition of a warm lamp. In this paper, we report on computational and experimental investigations of breakdown processes in real and idealized lamps with the goal of developing scaling laws for lamp design. The computational platform is a 2-dimensional plasma transport model using an unstructured mesh to resolve fine physical features of the lamp. Electric field emission, secondary electron emission and photoionization by radiation transport are included in addition to transport equations for all charged and neutral species. The experiments consist of an idealized coaxial lamp having an adjustable gap and cylindrical quartz tube. Diagnostics include I-V characteristics and optical emission. Scaling laws for breakdown processes, derived from the model, will be discussed for cold and warm Ar/Hg lamps having initial pressures of 10s-100s Torr and gaps of many cm. Emphasis will be placed on optimization of the lamp geometry and materials. To validate the model comparisons will be made between the model and experiments for simpler coaxial geometries for breakdown in Ar, while varying gap, pressure and geometry.
Keywords
discharge lamps; electric breakdown; electron field emission; optimisation; photoionisation; plasma diagnostics; plasma pressure; secondary electron emission; 2-dimensional plasma transport model; Ar-Hg; I-V characteristics; adjustable gap; breakdown optimisation; breakdown processes; charged species; coaxial geometries; cold lamps; cylindrical quartz tube; diagnostics; discharge gap; electric field emission; electrode lifetime; geometry effects; high pressure lamps; high pressure lighting sources; initial pressures; lamp design; lamp geometry; material properties; neutral species; optical emission; optimization; photoionization; plasma pressure; radiation transport; re-ignition; scaling laws; secondary electron emission; startup; transport equations; unstructured mesh; warm Ar/Hg lamps; warm lamp; Argon; Breakdown voltage; Coaxial components; Electric breakdown; Electrodes; Geometry; Lamps; Material properties; Physics computing; Solid modeling;
fLanguage
English
Publisher
ieee
Conference_Titel
Plasma Science, 2002. ICOPS 2002. IEEE Conference Record - Abstracts. The 29th IEEE International Conference on
Conference_Location
Banff, Alberta, Canada
Print_ISBN
0-7803-7407-X
Type
conf
DOI
10.1109/PLASMA.2002.1030643
Filename
1030643
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