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Research needs in ARC Technology

Published online by Cambridge University Press:  15 February 2011

J. V. R. Heberlein
J. V. R. Heberlein*
Affiliation:
Westinghouse R&D Center1310 Beulah RoadPittsburgh, PA 15235
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Abstract

The state of the art and the research needs of selected applications of arc technology are described. The selected applications include plasma torch design, plasma synthesis of materials, plasma chemical synthesis and metallurgical processing. The research areas where results can have the broadest impact on the technology are electrode effects, plasma fluid dynamics and non-equilibrium effects.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 30: Symposium L – Plasma Processing and Synthesis of Materials I , 1983 , 101
Copyright
Copyright © Materials Research Society 1984

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References

REFERENCES

1. Down:, M. G. “Plasma Processing for Materials Production,” EPRI Report EM-2771, December 1982.Google Scholar
2. Maecker:, M. “Ein zylindrischer Bogen für hohe Leistungen,” Z. Naturforschung 11a, 457, 1956.Google Scholar
3. Liu, G. N., Chu, F. Y., Simpson:, C. J. “Design and Laboratory Utilization of a Thermal Plasma Generator,” Proc. 6th Intl. Symp. Plasma Chemistry Montreal, Canada July 1983, p. 156.Google Scholar
4. Winovich, W. and Carlson:, W. C. A. “The 60 MW Shuttle Interaction Heating Facility,” ISA Transactions 19/2, p. 75, 1980.Google Scholar
5. Fey, M. G. and Harvey:, F. J. “The Role of Plasma Heating Devices in the Electric Economy,” Metals Engineering Quarterly May 1976, p. 27.Google Scholar
6. Fey, M. G., Meyer, T. N., Reed, W. H., Philbrook:, W. O. “Thermal Plasma Systems for Industrial Processes,” Proc. Industrial Opportunities for Plasma Technology Toronto October 1982.Google Scholar
7. Wutzke:, S. A. Ph.D. Thesis, University of Minnesota, June 1967.Google Scholar
8. Scharf:, G. “Operational Experiences in the Plasma Steelplant at Freital,” Ist European Electric Steel Congress, Aachen, Germany, September 1983.Google Scholar
9. Curr, T. R., et al. “The Design and Operation of Transferred Arc Plasma Systems for Pyrometallurgical Applications,” Proc. 6th Intl. Symp. Plasma Chemistry Montreal July 1983, p. 175.Google Scholar
10. Fey, M. G. and McDonald:, J. “Electrode Erosion in Electric Arc Heaters,” A.I.Ch.E. Plasma Chemical Processing Symposium, August 1976.Google Scholar
11. Guile:, A. E. “Arc Electrode Phenomena,” IEE Rev. 118, p. 1131, 1971.Google Scholar
12. Guile, A. E. and Jüttner:, B. “Basic Erosion Processes of Oxidized and Clean Metal Cathodes by Electric Arcs,” IEEE Transactions Plasma Science, PS 8/3, p. 259, 1980.Google Scholar
13. Ronsheim, P., et al. “Thermal Plasma Synthesis of Transition Metal Nitrides and Alloys,” Plasma Chemistry and Plasma Processing.Google Scholar
14. Perugini:, G. “Arc Plasma Reactions for Special Ceramics,” Proc. 3rd Intl. Symp. Plasma Chem. Limoges, France 1977.Google Scholar
15. Kong, P. C., et al. : “Synthesis of S-WCIX in an Atmospheric- Pressure, Thermal Plasma, Plasma Chemistry and Plasma Processing, 3/1, p. 115, 1983.Google Scholar
16. Ronsheim, P., Pfender, E., Toth:, L. E. “Characteristics of Particle Growth in a Thermal Plasma Jet,” 5th Intl. Symp. Plasma Chemistry, Edinburgh, U.K., 1981, p. 844.Google Scholar
17. Fey, M. G., Meyer, T. N., Reed:, W. H. “An Electric Arc Heater Process to Produce Solar Grade Silicon,” Proc. 4th Intl. Symp. Plasma Chemistry Zurich, Switzerland August 1979, p. 708.Google Scholar
18. Heberlein, J. V. R., Lowry, J. F., Meyer, T. N., Ciliberti:, D. F. “The Reduction of Tetrachlorosilane by Sodium at High Temperatures in a Laboratory Scale Experiment,” Proc. 4th Intl. Symp. Plasma Chemistry Zurich, Switzerland August 1979, p. 716.Google Scholar
19. Down:, M. G. “Titanium Production by a Plasma Process,” Wright Aeronautical Materials Laboratory, Technical Report AFWAL-TR-82–4018, May 1982.Google Scholar
20. Bunting:, K. A. “Sodium and Titanium Tetrachloride Feed System for a Plasma Route to Titanium,” Proc. 6th Intl. Symp. Plasma Chemistry Montreal July 1983, p. 193.Google Scholar
21. Patrick, A. J. and Gannon:, R. E. “A 1 MW Prototype Arc Reactor for Processing Coal to Chemicals,” Proc. Symp. Industrial Opportunities for Plasma Technology Toronto, Canada October 1982.Google Scholar
22. Muller, R. and Peuckert:, C. “Recent Developments for the Production of Acetylene from Coal by the Huels Arc Process,” Proc. 6th Intl. Symp. Plasma Chemistry Montreal July 1983, p. 270.Google Scholar
23. Coudert, J. F., et al. “Applications of the Plasma Jet Generator to the Nitrogen Oxide Synthesis,” Proc. 3rd Intl. Symp. Plasma Chemistry Limoges, France 1977.Google Scholar
24. Baronnet, J. M., et al. “Nitrogen Oxides Synthesis in a DC Plasma Jet,” Proc. 4th Intl. Symp. Plasma Chemistry Zurich, Switzerland August 1979, p. 349.Google Scholar
25. Barton:, T. G. “Problem Waste Disposal by Plasma Heating,” Int. Recycling Congress, Berlin, Germany, 1979, Vol. I, p. 733.Google Scholar
26. Ponghis, N., Vidal, R., Poos:, A. “Operation of a Blast Furnace with Superhot Reducing Gas,“ Met. Reports CRM, Vol. 56, p. 9, 1980.Google Scholar
27. Harvey, A. J. and Meyer:, T. N. “A Model of Liquid Metal Droplet Vaporization in Arc Heated Gas Streams,” Metallurgical Transactions B, 9B, p. 615, 1978.Google Scholar
28. Vardelle, A., Vardelle, M., Fauchais:, P. “Influence of Velocity and Surface Temperature of Alumina Particles on the Properties of Plasma Sprayed Coatings,” Plasma Chemistry and Plasma Processing, 2/3, p. 255, 1982.Google Scholar
29. Chen, Xi and Pfender:, E. “Heat Transfer to a Single Particle Exposed to a Thermal Plasma,” Plasma Chemistry and Plasma Processing, 2/2, p. 185, 1982.Google Scholar
30. Apelian, D., et al. “Melting and Solidification in Plasma Spray Deposition - A Phenomenological Review,” Intl. Metal. Reviews.Google Scholar
31. Meyer, T. N., et al. “Metal Powder Vaporization Using a Plasma Torch,” Proc. 6th Intl. Symp. Plasma Chemistry Montreal, Canada July 1983, p. 369.Google Scholar
32. Santen:, S. “Plasma Smelting,” Proc. 6th Intl. Symp. Plasma Chemistry Montreal, Canada July 1983, p. 174.Google Scholar
33. , D. R. , MacRae, et al. “Ferrovanadium Production by Plasma Carbothermic Reduction of Vanadium Oxide,” Proc. 34th Electric Furnace Conf. St. Louis, MO Dec. 1976.Google Scholar
34. Barcza, N. A., et al. “The Production of Ferro-Chromium in a Transferred-Arc Plasma Furnace,“Proc. 39th Electric Furnace Conf. Houston December 1981.Google Scholar
35. Gauvin, W. H., Kubanek, G. R., Irons:, G. A. “The Plasma Production of Ferromolybdenum-Process Development and Economics,‘J. Metals, January 1981, p. 42.Google Scholar
36. Ponghis, N., Vidal, R., Poos:, A. “PIROGAS - a new process allowing diversification of energy sources for blast furnaces,” High Temperature Technology 1/5, p. 275, 1983.Google Scholar