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Simultaneous Measurement of Particle Size and Temperature in a Plasma Torch

Published online by Cambridge University Press:  25 February 2011

J. R. Fincke ,
C. L. Jeffery  and
S. B. Englert
J. R. Fincke
Affiliation:
Idaho National Engineering Laboratory EG&G Idaho, Inc.Idaho Falls, Idaho 83415
C. L. Jeffery
Affiliation:
Idaho National Engineering Laboratory EG&G Idaho, Inc.Idaho Falls, Idaho 83415
S. B. Englert
Affiliation:
Idaho National Engineering Laboratory EG&G Idaho, Inc.Idaho Falls, Idaho 83415
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Abstract

Two coincidence techniques for simultaneously obtaining particle size and temperature in a plasma torch are described. The absolute magnitude of scattered laser light is used to determine particle size and particle temperature is determined from a two-color pyrometer technique. Typical results on alumina particles injected into a 7 kW plasma torch are presented.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 98: Symposium K – Plasma Processing and Synthesis of Materials II , 1987 , 127
Copyright
Copyright © Materials Research Society 1987

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References

REFERENCES

1. Gurevich, M. A. and Shteinberg, V. B., “Flame Temperature of a Single Drop of Liquid Fuel,” Translation of the Journal of Technical Physics of the USSR, Vol.3, No. 2, pp. 368375, February 1958.Google Scholar
2. Kruszewska, B. and Lesinski, J., “Temperature Distributions of Solid Particles in a Plasma Stream,” Revue De Physique Appliquee, Vol.12, pp.12091211, September 1977.Google Scholar
3. Vardelle, A., Baronnet, J. M., Vardelle, M., and Fauchais, P., “Measurements of the Plasma and Condensed Particles Parameters in a DC Plasma Jet,” IEEE Transactions on Plasma Science, Vol. PS–8, No. 4, pp.417424, December 1980.Google Scholar
4. Mihsin, J., Vardelle, M., Lesinski, J., and Fauchais, P., “Measurements of Surface Temperatures of Particles Sprayed by D. C. Plasma Jets by Colour Pyrometry in Flight,” ISPC-7, Eindhoven, Paper number B-5-4, July 1985.Google Scholar
5. Jorgensen, F. R. A. and Zuiderwyk, M., “Two-Color Pyrometer Measurement of the Temperature of Individual Combusting Particles,” J. Physics E: Scientific Instrumentation, Vol.18, pp. 486491, 1985.Google Scholar
6. Vardelle, M., Vardelle, A., Fauchais, P., and Boulos, M. I., “Plasma-Particle Momentum and Heat Transfer: Modelling and Measurements,” AIChE Journal, Vol.29, No. 2, pp. 236243, March 1983.Google Scholar
7. Hirleman, E. D., “Laser-Based Single Particle Counters for In-Situ Particulate Diagnostics,” Optical Engineering, Vol.19, No. 6, pp. 854860, November/December 1980.Google Scholar
8. Durst, F., “REVIEW–Combined Measurements of Particle Velocities, Size Distributions, and Concentrations,” Transactions of the ASME, Journal of Fluids Engineering, Vol.104, pp. 284296, September 1982.Google Scholar
9. Holve, D. J., “In-Situ Optical Particle Sizing Technique,” Journal of Energy, Vol.4, No. 4, pp. 176183, July-August 1980.Google Scholar
10. Hodkinson, J. R., “Particle Sizing by Means of the Foward Scattered Lobe,” Applied Optics, Vol.5, No. 5, pp. 839844, May 1966.Google Scholar
11. Hess, C. F., “Nonintrusive Optical Single-Particle Counter for Measuring the Size and Velocity of Droplets in a Spray,” Applied Optics, Vol.23, No. 23, pp. 43754382, December 1984.Google Scholar
12. Grehan, G. and Grouesbet, G., “Simultaneous Measurements of Velocities and Sizes of Particles in Flows Using a Combined System Incorporating a Top-Hat Beam Technique,” Applied Optics, Vol.25, No. 19, pp. 35273538, October 1986.Google Scholar
13. Tichenor, D. D., Mitchell, R. E., Hencken, K. R., and Nilisa, S., “Simultaneous In-Situ Measurement of the Size, Temperature and Velocity of Particles in a Combustion Environment,” Sandia National Laboratories, Livermore California, SAND84-8628, January 1984.Google Scholar