Compression strength and wear resistance of ceramic foams–polymer composites

Ceramic foam–polymer composites have been made by infiltration without pressure. Cellular ceramics (SiC and SiO2·ZrO2) of various cell size, (10, 20 and 30 ppi), were selected and combined with an epoxy vinyl-ester resin to produce composite materials. The interconnected pores (open cells) in the ce...

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Published inMaterials letters Vol. 60; no. 13-14; pp. 1687 - 1692
Main Authors Gómez de Salazar, J.M., Barrena, M.I., Morales, G., Matesanz, L., Merino, N.
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.06.2006
Subjects
Ceramics
Composite materials
Mechanical properties
Microstructure
Wear
Mechanical properties
Composite materials
Ceramics
Microstructure
Wear
Online AccessGet full text
ISSN0167-577X
1873-4979
DOI10.1016/j.matlet.2005.11.092

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Abstract Ceramic foam–polymer composites have been made by infiltration without pressure. Cellular ceramics (SiC and SiO2·ZrO2) of various cell size, (10, 20 and 30 ppi), were selected and combined with an epoxy vinyl-ester resin to produce composite materials. The interconnected pores (open cells) in the ceramic allowed a polymer flow throughout. This allowed a “continuous” distribution of the polymer throughout the structure and hence a good transmission of stresses between phases which resulted in higher mechanical properties. The results of compressive and wear test up on the materials obtained show the influence of cell size and wetness on the interface formed between the constituents. The failure modes exhibited in these materials were also analysed. It was observed that the polymer suffered plastic deformation while the ceramic phase was largely subject to shearing forces resulting in isolated fracturing.
AbstractList Ceramic foam-polymer composites were made by infiltration without pressure. Cellular ceramics (SiC and SiO2.ZrO2) of various cell size, (10, 20 and 30 ppi), were selected and combined with an epoxy vinyl-ester resin to produce composite materials. The interconnected pores in the ceramic allowed a polymer flow throughout. This allowed a "continuous" distribution of the polymer throughout the structure and hence a good transmission of stresses between phases which resulted in higher mechanical properties. The results of compressive and wear tests on the materials obtained show the influence of cell size and wetness on the interface formed between the constituents. The failure modes exhibited in these materials were also analysed. It was seen that the polymer suffered plastic deformation while the ceramic phase was largely subject to shearing forces resulting in isolated fracturing. 27 refs.
Ceramic foam–polymer composites have been made by infiltration without pressure. Cellular ceramics (SiC and SiO2·ZrO2) of various cell size, (10, 20 and 30 ppi), were selected and combined with an epoxy vinyl-ester resin to produce composite materials. The interconnected pores (open cells) in the ceramic allowed a polymer flow throughout. This allowed a “continuous” distribution of the polymer throughout the structure and hence a good transmission of stresses between phases which resulted in higher mechanical properties. The results of compressive and wear test up on the materials obtained show the influence of cell size and wetness on the interface formed between the constituents. The failure modes exhibited in these materials were also analysed. It was observed that the polymer suffered plastic deformation while the ceramic phase was largely subject to shearing forces resulting in isolated fracturing.
Ceramic foam-polymer composites have been made by infiltration without pressure. Cellular ceramics (SiC and SiO2*ZrO2) of various cell size, (10, 20 and 30 ppi), were selected and combined with an epoxy vinyl-ester resin to produce composite materials. The interconnected pores (open cells) in the ceramic allowed a polymer flow throughout. This allowed a "continuous" distribution of the polymer throughout the structure and hence a good transmission of stresses between phases which resulted in higher mechanical properties. The results of compressive and wear test up on the materials obtained show the influence of cell size and wetness on the interface formed between the constituents. The failure modes exhibited in these materials were also analysed. It was observed that the polymer suffered plastic deformation while the ceramic phase was largely subject to shearing forces resulting in isolated fracturing.
Author Gómez de Salazar, J.M.
Morales, G.
Matesanz, L.
Merino, N.
Barrena, M.I.
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Issue 13-14
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Ceramics
Microstructure
Wear
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Snippet Ceramic foam–polymer composites have been made by infiltration without pressure. Cellular ceramics (SiC and SiO2·ZrO2) of various cell size, (10, 20 and 30...
Ceramic foam-polymer composites were made by infiltration without pressure. Cellular ceramics (SiC and SiO2.ZrO2) of various cell size, (10, 20 and 30 ppi),...
Ceramic foam-polymer composites have been made by infiltration without pressure. Cellular ceramics (SiC and SiO2*ZrO2) of various cell size, (10, 20 and 30...
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SubjectTerms Ceramics
Composite materials
Mechanical properties
Microstructure
Wear
Title Compression strength and wear resistance of ceramic foams–polymer composites
URI https://dx.doi.org/10.1016/j.matlet.2005.11.092
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