Research on the Wear Resistance of High-Chromium White Cast Iron and Multi-Component White Cast Iron

Chien Lung Yen; Fu Je Chen; Yung Ning Pan

doi:10.4028/www.scientific.net/AMR.859.64

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HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 859Research on the Wear Resistance of High-Chromium...

Research on the Wear Resistance of High-Chromium White Cast Iron and Multi-Component White Cast Iron

Abstract:

The pin-on-disk wear test and solid particle erosion test were used to investigate the wear resistance property of both high chromium white cast iron and multi-component white cast iron with optimal alloy compositions and heat treatment conditions. Experimental results indicate that a linear relationship between the wear lose and the testing time exists for high chromium white cast irons. Apparent scratch grooves and sheared pits appeared on the specimen surface. Subsurface observations found pit depths of some 4.5~8.0 mm. Crack propagation routes were clearly visible along the martensitic grain boundaries for alloys in the as-quenched state. Tempering treatment increases the toughness of the alloy, resulting in an increase in the resistance to crack formation. On the other hand, the multi-component white cast irons exhibited a non-linear relationship between the wear lose and the testing time. Relatively shallow scratches were found on the specimen surface, and pit depths of about 4.0 mm were observed through subsurface observations. Tempering at 570°C caused a reduction in hardness of the alloy, and therefore, the fracture mode tends to be ductile. As a result, deformation only occurred in crater regions with no clear evidence of spreading.