Preparation and Performance of SiC Foam Ceramic/Fe Matrix Co-continuous Phase Composites

doi:10.11901/1005.3093.2014.267

Chinese Journal of Materials Research

2014, Vol. 28

Issue (11): 814-820 DOI: 10.11901/1005.3093.2014.267

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Preparation and Performance of SiC Foam Ceramic/Fe Matrix Co-continuous Phase Composites

Zhiheng REN,Peng JIN,Xiaoming CAO,Jinsong ZHANG(

)

Institute of Metal Research, Chinese Academy of Sciences, Shenyang 110016

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Zhiheng REN,Peng JIN,Xiaoming CAO,Jinsong ZHANG. Preparation and Performance of SiC Foam Ceramic/Fe Matrix Co-continuous Phase Composites. Chinese Journal of Materials Research, 2014, 28(11): 814-820.

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Abstract

SiC foam ceramic/Fe based co-continuous phase composites were prepared by squeeze casting method using oxidized SiC foam ceramic. Then the prepared composites were annealed. The influence of preparation process and SiC volume fraction on microstructures and mechanical properties of the composites were investigated. Results show that a SiO₂ barrier film of 1 mm in thickness on the surfaces of SiC foam can form after oxidizing at 1250°C for 48 h, which then can efficiently prevent the formation of a brittle intermetallic compound Fe₃Si at the interface of Fe matrix and SiC during the preparation of composites. As a result, the flexural strength of composites was increased by 100% and compressive strength by 18%. The thickness of SiO₂ film was increased after oxidizing at 1250°C for 72 h, and a thicker SiO₂ film may induce mismatch of thermal expansion coefficient between SiO₂, Fe and SiC, which thereby resulted in the increase of residual stress. Therefore, the mechanical properties of composites were decreased slightly. The residual stress could be relieved after annealing of composites at 600°C for 4 h, which improved the mechanical properties of composites. The function of bridging and deflecting crack of metal matrix is big for the composite with small SiC volume fraction, which is in turn beneficial to the enhancement of the flexural strength and flexural strain. For the composite with the higher SiC volume fraction, the size of SiC skeleton became bigger and the load-carrying capacity was strengthened, thereby its compressive strength was increased.

Key words: composites foam ceramic SiO₂ reaction inhibitor mechanical property

Received: 28 May 2014

Fund:

*Supported by National High Technology Research and Development Program of China No.2012AA03A508.

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	Zhiheng REN
	Peng JIN
	Xiaoming CAO
	Jinsong ZHANG

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https://www.cjmr.org/EN/10.11901/1005.3093.2014.267 OR https://www.cjmr.org/EN/Y2014/V28/I11/814

Fig.1 Morphologies of SiC foam ceramic, (a) macroscopy, (b) microscopy

Table 1 Composition of matrix in SiC/Fe composite (mass fraction, %)

Fig.2 XRD pattern of SiC foam ceramic

Fig.3 Morphology of SiC foam ceramic after 48 h oxidation treatment at 1250℃ (a) macroscopy, (b) microscopy

Fig.4 XRD pattern of SiC foam ceramic after oxidation treatment

Fig.5 Microstructures of composites with untreatment (a) and oxidation treatment (b)

Fig.6 XRD patterns of composites with different treatments

Fig.7 Microstructures of SiC foam ceramics after oxidation for 48 h (a) and 72 h (b)

Fig.8 Influence of oxidation on the mechanical properties of composites

Table 2 Comparison of mechanical properties between composites with different oxidation treatments of SiC foam ceramics

Fig.9 Influence of annealing on the mechanical properties of composites

Table 3 Comparison of mechanical properties between composites with different annealing treatments

Fig.10 Relationship between compressive stress-strain of composites and SiC volume fraction

Fig.11 Relationship between flexural stress-displacement of composites and SiC volume fraction

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