Title :
Nature of convection-stabilized DC arcs in dual-flow nozzle geometry. I. The cold flow field and DC arc characteristics
Author :
Serbetci, Ilter ; Nagamatsu, H.T.
fDate :
2/1/1990 12:00:00 AM
Abstract :
An experimental investigation of the steady-state low current air arcs in a dual-flow nozzle system is presented. The cold flow field with no arc was determined for various nozzle geometries, i.e. two- and three-dimensional and orifice nozzles, and nozzle pressure ratios. Supersonic flow separation and oblique and detached shock waves were observed in the flow field. Using a finite-element computer program, the Mach number contours were determined in the flow field for various nozzle-gap spacings and pressure ratios. In addition, the DC arc voltage and current measurements were made for an electrode gap spacing of ≈5.5 cm and current levels of I≈25, 50, and 100 A for the three nozzle geometries. The arc voltage and arc power increased rapidly as the flow speed increased from zero to sonic velocity at the nozzle throat. The shock waves in the converging-diverging nozzles resulted in a decrease in the overall resistance by about 15%
Keywords :
arcs (electric); convection; flow separation; nozzles; plasma flow; supersonic flow; 100 A; 25 A; 5.5 cm; 50 A; DC arc voltage; Mach number contours; cold flow field; convection-stabilized DC arcs; converging-diverging nozzles; current measurements; detached shock waves; dual-flow nozzle geometry; electrode gap spacing; finite-element computer program; low current air arcs; nozzle geometries; nozzle throat; nozzle-gap spacings; oblique shock waves; orifice nozzles; sonic velocity; supersonic flow separation; three-dimensional nozzles; two-dimensional nozzles; Current measurement; Electrodes; Gases; Geometry; Helium; Mechanical engineering; Orifices; Shock waves; Steady-state; Voltage;
Journal_Title :
Plasma Science, IEEE Transactions on
