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Polymer Impregnation of an Impervious Cementitious Composite Material

Published online by Cambridge University Press:  22 February 2011

Randall P. Bright ,
Sean Wise  and
Mark I. Mackenzie
Randall P. Bright
Affiliation:
CEMCOM Research Associates, Inc., 9901K George Palmer Highway, Lanham, Maryland
Sean Wise
Affiliation:
CEMCOM Research Associates, Inc., 9901K George Palmer Highway, Lanham, Maryland
Mark I. Mackenzie
Affiliation:
CEMCOM Research Associates, Inc., 9901K George Palmer Highway, Lanham, Maryland
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Abstract

Well compacted, silica fume-modified ordinary Portland cement pastes are well known for their low permeability. This quality can be maintained to temperatures slightly in excess of 200°C. Above this temperature, however, a continuous pore structure develops, making the material permeable and therefore unsuitable for high temperature applications (250–400°C) where vacuum integrity is necessary. To overcome this obstacle the permeability can be exploited for impregnating the concrete with an organic polymer. Organic polymers traditionally employed for impregnated concretes are not thermally stable enough to be used at high temperatures. Therefore, a high temperature-resistant organic resin has been studied for this application. The optimum conditions for impregnating this viscous resin into a high strength mortar have been investigated.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 42: Symposium L – Very High Strength Cement-Based Materials , 1984 , 287
Copyright
Copyright © Materials Research Society 1985

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References

[1] Wise, S., Satkowski, J.A., Scheetz, B., Rizer, J.M., Mackenzie, M.L., Double, D.D.; this symposium.Google Scholar
[2] Registered trademark DASH 47, U.S. Patent No. 4,482,385; CEMCOM Research Associates, Inc., (November 1984).Google Scholar
[3] Steinberg, M., Kukacka, L.E., Columbo, P., Kelch, J.K., Manowitz, B., Dikeou, J., Blackstorm, J., and Rubenstein, S., “Conrete Polymer Materials, First Topical Report,” BNL (T–509), P. 83 (1968).Google Scholar
[4] Swamy, R., J. Materials Science 124, 1521 (1979).10.1007/BF00569273Google Scholar
[5] Manson, J.A., Sperling, L.H., “Polymer Blends and Composites,” Plenum Press, (1976).10.1007/978-1-4615-1761-0CrossRefGoogle Scholar
[6] De Puy, G.W., Kukacka, L.E., Auskern, A., Cowna, W.C., Colombo, P., Lockman, W.T., Romano, A.J., Smoak, W.G., Steinberg, M., Causey, F.E., “Concrete-Polymer Materials, Fifth Topical Report,” BNL 50390 and USBR REC-ERC-73-12, December 1973.10.2172/4328261Google Scholar