$New types of light-weight refractory and heat-insulation materials for long-term use at extremely high temperatures$

New types of light-weight refractory and heat-insulation materials for long-term use at extremely high temperatures

The particulars of a technology for new types of refractory and heat-insulation materials with high porosity, which are obtained by duplicating the cellular structure of the polymer base (polyurethane foam) and using pore-forming technology based on “cold” swelling of inorganic compositions, are exa...

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Veröffentlicht in:	Glass and ceramics 2011-07, Vol.68 (3-4), p.116-122
Hauptverfasser:	Vladimirov, V. S., Lukin, E. S., Popova, N. A., Ilyukhin, M. A., Moizis, S. E., Moizis, E. S., Artamonov, M. A.
Format:	Artikel
Sprache:	eng
Schlagworte:	Aluminum oxide Calcium carbonate Ceramics Characterization and Evaluation of Materials Chemistry and Materials Science Composites Corundum Electric properties Glass Hydroxides Insulating materials industry Materials Science Natural Materials Phosphates Polyurethane foam Porosity Refractories Reproduction Spinel Swelling Thermal conductivity Weight reduction Zirconium dioxide
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container_title	Glass and ceramics
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creator	Vladimirov, V. S. Lukin, E. S. Popova, N. A. Ilyukhin, M. A. Moizis, S. E. Moizis, E. S. Artamonov, M. A.
description	The particulars of a technology for new types of refractory and heat-insulation materials with high porosity, which are obtained by duplicating the cellular structure of the polymer base (polyurethane foam) and using pore-forming technology based on “cold” swelling of inorganic compositions, are examined. The use of electrocorundum, periclase, spinel, and zirconium dioxide as a base permits using such materials from 1750 to 2200°C. In a number of cases the heat-insulation materials which have been developed can successfully replace corundum fiber materials.
doi_str_mv	10.1007/s10717-011-9335-7
format	Article
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subjects	Aluminum oxide Calcium carbonate Ceramics Characterization and Evaluation of Materials Chemistry and Materials Science Composites Corundum Electric properties Glass Hydroxides Insulating materials industry Materials Science Natural Materials Phosphates Polyurethane foam Porosity Refractories Reproduction Spinel Swelling Thermal conductivity Weight reduction Zirconium dioxide
title	New types of light-weight refractory and heat-insulation materials for long-term use at extremely high temperatures
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