Article ID | Journal | Published Year | Pages | File Type |
---|---|---|---|---|
9952590 | Wear | 2018 | 17 Pages |
Abstract
Here we systematically investigated the mechanical properties, microstructure and three-body impact abrasive wear behavior of martensitic steel and traditional Hadfield steel (i.e. Mn13Cr2). Compared with Mn13Cr2, the martensitic steel showed better wear resistance with 1335â¯MPa higher tensile strength, 1007â¯MPa higher yield strength, 305 HV higher initial hardness, 34.5-79.0% less wear loss. Furthermore, a dimensionality wear analysis method was proposed to explain the wear behavior from one to four dimensions. One dimensional wear (i.e. phase transition wear) proposed that twining, high density dislocations, retained austenite phase transformations were the strengthening mechanism of martensitic steel while entangled dislocations and stacking faults were the work hardening mechanism of Mn13Cr2. Two dimensional wear (i.e. surface wear) suggested that strain fatigue, cracks, furrow, press-in abrasive and extruded accumulation were the main wear mechanisms of martensitic steel. While those of Mn13Cr2 were press-in abrasive, furrow, strain fatigue, cutting, extruded accumulation and delaminated crater. Three dimensional wear (i.e. macro wear) viewed that the martensitic steel wore in a thin film two dimensional plane surface on the macroscopic scale. However, Mn13Cr2 wore in a three dimensional concave surface with indispensable height and showed one more dimensional wear than martensitic steel.
Related Topics
Physical Sciences and Engineering
Chemical Engineering
Colloid and Surface Chemistry
Authors
Zhongzheng Pei, Renbo Song, Qinan Ba, Yifan Feng,