Mechanical Wear of SnO2-C Morph-Genetic Composite Materials

Xin Hai He; Ming Qian Shen; Le Hua Qi; Jun Bo Wang; Min Ge Yang; Wei Chang

doi:10.4028/www.scientific.net/AMR.152-153.1227

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Experimental Investigation of Microsegregation in Low Frequency Electromagnetic Casting of Al-4.5%Cu Binary Alloy
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Hydrothermal Synthesis and Characterization of Single-Crystal Lead Titanate Nanoflakes
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Mechanical Wear of SnO₂-C Morph-Genetic Composite Materials
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The Fracture Research of Hexagonal Duralumin Nut
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HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 152-153Mechanical Wear of SnO2-C Morph-Genetic Composite...

Mechanical Wear of SnO₂-C Morph-Genetic Composite Materials

Abstract:

Five series SnO2/C Morph-genetic composite materials were prepared using ramie fiber as biological templates, Sn(OH)4 sol as impregnant, and phenolic resin as supplementary adhesive. The influences of calcination temperature, holding time, and phenolic resin treatment on the mechanical wear property of the SnO2/C morph-genetic materials were studied. The results showed that when the calcination temperature reached 630 and holding time increased, SnO2 was reduced by C and CO to needle-like flakes and pellet mixed SnO/SnO2 tissue, and their pinning and supportive effects significantly increased wear resistance of the samples. Glass Carbon derived from phenolic resin decomposition and ramie carbon were difficult to distinguish, but glass carbon had obvious supportive and strengthening effects on ramie carbon walls. With the formation of homogeneous carbon membrane in the process of friction, the alternative distribution of soft carbon and hard carbon could effectively improve wear resistance of the matrix ramie carbon.