Matrix structure evolution and thermo-mechanical properties of carbon fiber-reinforced Al{sub 2}O{sub 3}-SiC-C castable composites

Highlights: • Carbon fibers are formed in Al{sub 2}O{sub 3}-SiC-C castable composites under the action of nano Ni. • Starting growth temperature is 900 °C and growth mechanism agrees with V–S model. • The high temperature strength of composites can be increased by above 40%. • The thermal shock resi...

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Veröffentlicht in:	Materials research bulletin 2015-01, Vol.61
Hauptverfasser:	Li, Xiangcheng, Li, Yaxiong, Chen, Liufang, Zhu, Boquan
Format:	Artikel
Sprache:	eng
Schlagworte:	ALUMINIUM OXIDES CARBON CARBON FIBERS CATALYSTS COMPOSITE MATERIALS CORROSION ELECTRON MICROSCOPY IRON MATERIALS SCIENCE MATRIX MATERIALS MECHANICAL PROPERTIES MICROSTRUCTURE REINFORCED MATERIALS SILICON SILICON CARBIDES TEMPERATURE DEPENDENCE THERMAL SHOCK
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creator	Li, Xiangcheng Li, Yaxiong Chen, Liufang Zhu, Boquan
description	Highlights: • Carbon fibers are formed in Al{sub 2}O{sub 3}-SiC-C castable composites under the action of nano Ni. • Starting growth temperature is 900 °C and growth mechanism agrees with V–S model. • The high temperature strength of composites can be increased by above 40%. • The thermal shock resistance can be enhanced by above 20%. - Abstract: The spalling and corrosion during the thermal cycles are the main causes of the damages observed in Al{sub 2}O{sub 3}-SiC-C castable composites that are used in molten-iron system. Using the catalyst of nano Ni and ball pitch in the matrix, Al{sub 2}O{sub 3}-SiC-C castable composites were prepared with the anti-oxidant addition of silicon. The results indicate that the high temperature of the Al{sub 2}O{sub 3}-SiC-C castable composites can be increased by above 42%, and the thermal shock resistance can be enhanced by above 20% because the ball pitch is carbonized and releases C{sub x}H{sub y} vapor, which can be pyrolized to carbon atoms and subsequently deposited into carbon fibers under the catalyst action. The starting temperature of carbon fiber growth is approximately 900 °C, and their diameter and aspect ratio can increase with the rising temperature. The in-situ generation of carbon fibers in Al{sub 2}O{sub 3}-SiC-C castable composites can significantly improve the fibers’ thermo-mechanical properties.
doi_str_mv	10.1016/J.MATERRESBULL.2014.10.022
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Using the catalyst of nano Ni and ball pitch in the matrix, Al{sub 2}O{sub 3}-SiC-C castable composites were prepared with the anti-oxidant addition of silicon. The results indicate that the high temperature of the Al{sub 2}O{sub 3}-SiC-C castable composites can be increased by above 42%, and the thermal shock resistance can be enhanced by above 20% because the ball pitch is carbonized and releases C{sub x}H{sub y} vapor, which can be pyrolized to carbon atoms and subsequently deposited into carbon fibers under the catalyst action. The starting temperature of carbon fiber growth is approximately 900 °C, and their diameter and aspect ratio can increase with the rising temperature. 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Using the catalyst of nano Ni and ball pitch in the matrix, Al{sub 2}O{sub 3}-SiC-C castable composites were prepared with the anti-oxidant addition of silicon. The results indicate that the high temperature of the Al{sub 2}O{sub 3}-SiC-C castable composites can be increased by above 42%, and the thermal shock resistance can be enhanced by above 20% because the ball pitch is carbonized and releases C{sub x}H{sub y} vapor, which can be pyrolized to carbon atoms and subsequently deposited into carbon fibers under the catalyst action. The starting temperature of carbon fiber growth is approximately 900 °C, and their diameter and aspect ratio can increase with the rising temperature. 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subjects	ALUMINIUM OXIDES CARBON CARBON FIBERS CATALYSTS COMPOSITE MATERIALS CORROSION ELECTRON MICROSCOPY IRON MATERIALS SCIENCE MATRIX MATERIALS MECHANICAL PROPERTIES MICROSTRUCTURE REINFORCED MATERIALS SILICON SILICON CARBIDES TEMPERATURE DEPENDENCE THERMAL SHOCK
title	Matrix structure evolution and thermo-mechanical properties of carbon fiber-reinforced Al{sub 2}O{sub 3}-SiC-C castable composites
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