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Engineering and Microstructural Studies of Western-Canadian Fly Ash Bricks

Published online by Cambridge University Press:  25 February 2011

Robert L. Day
Affiliation:
The Calgary Fly Ash Research Group, Dept. of Civil Engineering, University of Calgary, Alberta, Canada
Ramesh C. Joshi
Affiliation:
The Calgary Fly Ash Research Group, Dept. of Civil Engineering, University of Calgary, Alberta, Canada
Rudolf J. Slota
Affiliation:
The Calgary Fly Ash Research Group, Dept. of Civil Engineering, University of Calgary, Alberta, Canada
Brian W. Langan
Affiliation:
The Calgary Fly Ash Research Group, Dept. of Civil Engineering, University of Calgary, Alberta, Canada
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Abstract

An experimental programme was undertaken to determine whether Canadian fly ash, and in particular Western-Canadian fly ash, can be used to replace clay as the main ingredient in brick-masonry units.

These preliminary examinations show that Western-Canadian fly ash as the solid material, combined with an adequate binder, can be used to produce a superior ceramic material. Strengths are very much higher than that revuired for load-bearing masonry elements, densities are approximately 800 kg/m3 less than a normal clay brick and the material is durable to freezing and thawing. X-ray analysis and scanning electron microscopy clearly show chemical and physical changes which occur to the material due to firing. These chemical changes appear to be closely related to the subsequent strength which is developed.

Bricks manufactured from Alberta fly ash appear to be a viable alternative to standard clay brick. A substantially stronger and more economical brick may be possible; fly-ash bricks can be manufactured with lower firing temperatures of shorter duration. This, in itself, could lead to the realization of significant energy savings. Also, if large quantities of fly ash can be used in the brick industry, then significant gains will be made toward the elimination of this waste product from the environment and conservation of natural resources.

Type
Articles
Copyright
Copyright © Materials Research Society 1986

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References

1. Day, R.L., Langan, B.W., Joshi, R.C. and Ward, W.A., Increasing the Use of Fly Ash in Construction First Progress Report by the Calgary Fly Ash Research Group, University of Calgary, Dept. Civ., Eng., Rept. CE84–3, (1984).Google Scholar
2. Day, R.L., Joshi, R.C., Langan, B.W. and Ward, M.A., in Proc. 2nd Intnl. Conf. on Ash Technology and Marketing, London, England, Sept., 1984.Google Scholar
3. Snel, A., Fly Ash Production and Utilization in the Netherlands, EPRI CS2616-SR (1981).Google Scholar
4. Mohan, D., Intnl. Jour. for Housing Sci. and Its Appl., 3, 431436 (1979).Google Scholar
5. Slonaker, J.F., in Conf. on Ash Technology and Marketing (Sudbury House, Newgate St., London, 1978).Google Scholar
6. Slonaker, J.F., in 4th Intnl. Ash Utiliz. Symp., St. Louis, March, 1976).Google Scholar
7. Sieffert, P.L., in Proc. 2nd Ash Utiliz. Symp., Information Circular 8488, (Bureau of Mines, U.S. Dept. of Interior, 1970).Google Scholar
8. Reidelbach, J.A. Jr., in Proc. 2nd Ash Utilization Symposium, Information Circular 8488 (Bureau of Mines, U.S. Dept. of Interior, 1970).Google Scholar
9. Manz, O.E., Cem. Concr. Res., 14, 513520 (1984).Google Scholar