Surfaces, Vol. 8, Pages 19: Analysis of Fatigue Life After Application of Compressive Microstresses on the Surface of Components Manufactured by Metal Injection Molding

Surfaces, Vol. 8, Pages 19: Analysis of Fatigue Life After Application of Compressive Microstresses on the Surface of Components Manufactured by Metal Injection Molding

Surfaces doi: 10.3390/surfaces8010019

Authors: Jorge Luis Braz Medeiros Luciano Volcanoglo Biehl Ismael Cristofer Baierle

The metal injection molding (MIM) manufacturing process has made relevant advances for applications in components with complex geometries, small dimensions, and high production volumes. New technologies such as hot isostatic pressing (HIP), uniform polymer extraction, and sintering with reduced temperature variations improve metallurgical and mechanical properties. However, there are still knowledge gaps in understanding these technologies and the behavior of catalytic low-alloy steels obtained by the MIM process and cyclic applications. This study aims to analyze the behavior of Catamold 100Cr6 steel subjected to quenching and tempering heat treatment in different microhardness ranges and the effect of compressive stresses on the samples obtained by polishing using ceramic microchips. The samples were characterized using optical microscopy, scanning electron microscopy, an EDS microprobe, and X-ray diffraction and subjected to elastic return cycling and an experimental device developed to apply a 19° bending angle. The findings show a significant increase in fatigue life due to the compressive stresses (up to—430 MPa) generated by the reduction in retained austenite and surface plastic microdeformation, indicating the effectiveness of 100Cr6 Catamold steel in cyclic applications.