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Effect of sliding speed on elevated-temperature wear behavior of AISI H13 steel |
Yin Zhou1, Wei Jiang2 |
1 School of Shipping and Mechatronic Engineering, Taizhou University, Taizhou 225300, Jiangsu, China;
2 Light Alloy Research Institute, Central South University, Changsha 410083, Hunan, China |
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Abstract Elevated-temperature wear tests were performed on AISI H13 steel under 50 and 100 r/min at 400–600 °C. Through examining the morphology, structure and composition of worn surfaces as well as the microhardness at subsurfaces, the wear mechanisms in various sliding conditions were explored. H13 steel exhibited totally different elevated-temperature wear behavior at two sliding speeds while the high sliding speed would seriously deteriorate its wear resistance. During sliding at two sliding speeds, the wear rate of H13 steel decreased first and then rose with the increase in temperature and the wear rate reached the lowest value (lower than 1×10–6 mm3/mm) at 500 °C and 50 r/min. The wear rate at 600 °C was lower than that at 400 °C for 50 r/min, but the wear rate at 600 °C was higher than that at 400 °C for 100 r/min (except for 50 N). At 50 r/min, the wear rate decreased first and then increased with the increase in load. However, at 100 r/min, the wear rate monotonically increased with increasing load and reached 33×10–6 mm3/mm at 600 C and 150 N, where severe wear occurred. In the other sliding conditions, severe wear did not appear with wear rate lower than 5×10–6 mm3/ mm. Oxidative mild wear merely prevailed at 500 °C and 50 r/min and oxidative wear appeared in the other sliding conditions except for 600 °C and 150 N, where severe plastic extrusion wear prevailed. The effect of sliding speed on wear behavior was attributed to the changes of tribo-oxide layers. During elevated-temperature sliding, tribo-oxide particles were more readily retained to form protective tribo-oxide layers on worn surfaces at the lower sliding speed than at the higher sliding speed, so as to protect from wear.
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Cite this article: |
Yin Zhou,Wei Jiang. Effect of sliding speed on elevated-temperature wear behavior of AISI H13 steel[J]. Journal of Iron and Steel Research International, 2021, 28(9): 1180-1189.
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[1] |
Lan Wang, Jing-han Yang, Yang Li, Jie Song, Yun-xue Jin, Shu-qi Wang. Wear behavior of TC11 and AISI M2 in pin–disk tribo-system[J]. JOURNAL OF IRON AND STEEL RESEARCH,INTERNATIONAL, 2019, 26(5): 490-500. |
[2] |
De-hong Lu . Hai-zhou Li . Bo Ren. Effect of Si content on impact-abrasive wear resistance of Al2O3p/steel composites prepared by squeeze casting[J]. , 2018, 25(9): 984-994. |
[3] |
Zhen Cao,Shu-qi Wang*,Ke-zhi Huang,Bo Zhang,Guo-hong Wen,Qiu-yang Zhang,Lan Wang. Effect of artificial tribological layer on sliding wear behavior of H13 steel[J]. Chinese Journal of Iron and Steel, 2017, 24(9): 943-949. |
[4] |
Xiu-lin JI,Ju-yi WANG,Cui-cui JI,Jian-hua ZHAO. Abrasive Wear Resistance of Dual Phase Steels DP980 and DP600[J]. Chinese Journal of Iron and Steel, 2015, 22(4): 317-323. |
[5] |
Ting SUN,Ren-bo SONG,Xu WANG,Peng DENG,Chun-jing WU. Abrasive Wear Behavior and Mechanism of High Chromium Cast Iron[J]. Chinese Journal of Iron and Steel, 2015, 22(1): 84-90. |
[6] |
YANG Zi-run,LI Dong-sheng,WANG Lan,WANG Shu-qi,WEI Min-xian. Wear Behavior and Mechanism of Spheroidal Graphite Cast Iron[J]. Chinese Journal of Iron and Steel, 2013, 20(10): 81-86. |
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