The Effects of Power Level on the Microwave Heating of Selected Chemicals and Minerals

S. L. McGill; J. W. Walkiewicz; G. A. Smyres

doi:10.1557/PROC-124-247

Abstract

The effect of power level on the microwave heating characteristics of a variety of reagent-grade chemicals and minerals has been determined in a Bureau of Mines study. Heating rates of the powdered samples are presented for incident power ranging from 500 to 2,000 W at 2.45 GHz. The apparatus consisted of a WR 975 waveguide-applicator mounted to WR 284 waveguide sections and connected to a 3-kW power source. Tests were conducted in an alumina crucible enclosed in a fused-quartz beaker that was fitted with a Teflon lid to allow for a controlled inert atmosphere and thermocouple insertion. In general, heating rates increased as input power increased. Exceptions to this were some very high-lossy (microwave receptive) and very low-lossy materials that showed negligible changes with increased power. Microwave data collected should provide insight as to possible chemical and mineral processing applications as well as to assist in predictions of processing parameters.

References

REFERENCES

1. Metaxas, A. C. and Meredith, R. J.. Industrial Microwave Heating. IEE Power Engineering Series 4, (Peter Peregriuns Ltd., London, U.K., 1983) pp. 296–321.Google Scholar

2. Walkiewicz, J. W., Kazonich, G., and McGill, S. L.. Miner. and Metall. Proc., 5 (1), 39–42 (Feb. 1988).Google Scholar

3. White, J. R.. Why Materials Heat. Theory and Applications of Microwave Power in Industry: A Short Course. International Microwave Power Institute, 1971.Google Scholar

4. Walkiewicz, J. W., McGill, S. L., and Moyer, L. A.. Paper No. M4.7, Symp. Proc. on Microwave Processing of Materials, Mater. Res. Soc. 1988 Spring Meeting, Reno, NV, April 5–8, 1988.Google Scholar

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Walkiewicz, J.W. Raddatz, A.E. and McGill, S.L. 1989. Microwave-assisted grinding. p. 1528.

Walkiewicz, J.W. Clark, A.E. and McGill, S.L. 1991. Microwave-assisted grinding. IEEE Transactions on Industry Applications, Vol. 27, Issue. 2, p. 239.

Kenkre, V. M. Kus, M. and Katz, J. D. 1992. Model for Anomalous Power Dependence of Microwave Heating in Ceramic Materials. physica status solidi (b), Vol. 172, Issue. 1, p. 337.

Kenkre, V. M. Kus, M. and Katz, J. D. 1992. Explanation of the barrier-depression effect in ceramics undergoing microwave heating. Physical Review B, Vol. 46, Issue. 21, p. 13825.

Whittaker, A.G. and Mingos, D.M.P. 1994. The Application of Microwave Heating to Chemical Syntheses. Journal of Microwave Power and Electromagnetic Energy, Vol. 29, Issue. 4, p. 195.

Endicott, M. R. Kenkre, V. M. and Kuś, M. 1994. Theory of a Confinement Effect of Dipole Rotations Resulting in Saturation in Microwave Heating of Ceramics. physica status solidi (b), Vol. 184, Issue. 1, p. 99.

Lee, Ki-Yong Case, Eldon D. and Asmussen, Jes 1997. The steady-state temperature as a function of casket geometry for microwave-heated refractory caskets. Materials Research Innovations, Vol. 1, Issue. 2, p. 101.

Aguilar, J. A. and Gomez, I. 1997. Microwaves Applied to Carbothermic Reduction of Iron Ore Pellets. Journal of Microwave Power and Electromagnetic Energy, Vol. 32, Issue. 2, p. 67.

Li, Haoxuan Agrawal, Dinesh K. Cheng, Jiping and Silsbee, Michael R. 1999. Formation and hydration of C3S prepared by microwave and conventional sintering. Cement and Concrete Research, Vol. 29, Issue. 10, p. 1611.

Haque, Kazi E. 1999. Microwave energy for mineral treatment processes—a brief review. International Journal of Mineral Processing, Vol. 57, Issue. 1, p. 1.

Marland, S Han, B Merchant, A and Rowson, N 2000. The effect of microwave radiation on coal grindability. Fuel, Vol. 79, Issue. 11, p. 1283.

Orumwense, A. O. and Negeri, T. 2003. Impact of microwave irradiation on the processing of a sulfide ore. Mining, Metallurgy & Exploration, Vol. 21, Issue. 1, p. 44.

Orumwense, O. A. Negeri, T. and Lastra, R. 2004. Effect of microwave pretreatment on the liberation characteristics of a massive sulfide ore. Mining, Metallurgy & Exploration, Vol. 21, Issue. 2, p. 77.

Batar, T. 2004. Theory and Applications of Microwave Energy in Communition. Key Engineering Materials, Vol. 264-268, Issue. , p. 1399.

Al-Harahsheh, M. and Kingman, S.W. 2004. Microwave-assisted leaching—a review. Hydrometallurgy, Vol. 73, Issue. 3-4, p. 189.

Reguera, E. Díaz-Aguila, C. and Yee-Madeira, H. 2005. On the changes and reactions in metal oxides under microwave irradiation. Journal of Materials Science, Vol. 40, Issue. 19, p. 5331.

Temple, Dustin G. Goff, Matthew T. Martin, Jeffrey D. Agresti, David and Boles, Walter W. 2006. Microwave Induced Carbothermic Reduction of Iron Oxides in Lunar Soil Simulant. p. 1.

Al-Harahsheh, M. Kingman, S. and Bradshaw, S. 2006. The reality of non-thermal effects in microwave assisted leaching systems?. Hydrometallurgy, Vol. 84, Issue. 1-2, p. 1.

Nanthakumar, B. Pickles, C.A. and Kelebek, S. 2007. Microwave pretreatment of a double refractory gold ore. Minerals Engineering, Vol. 20, Issue. 11, p. 1109.

Can, N. M. and Bayraktar, I. 2007. Effect of microwave treatment on the flotation and magnetic separation properties of pyrite, chalcopyrite, galena and sphalerite. Mining, Metallurgy & Exploration, Vol. 24, Issue. 3, p. 185.

Download full list

Article contents

The Effects of Power Level on the Microwave Heating of Selected Chemicals and Minerals

Abstract

Access options

References

REFERENCES

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

The Effects of Power Level on the Microwave Heating of Selected Chemicals and Minerals

Abstract

Access options

References

REFERENCES

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests