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| TiC Precipitation Behavior and Its Effect on Abrasion Resistance of High Titanium Wear-Resistant Steel |
SUN Xinjun( ),LIU Luojin,LIANG Xiaokai,XU Shuai,YONG Qilong |
| Department of Structrual Steels, Central Iron & Steel Research Institute, Beijing 100081, China |
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Cite this article:
SUN Xinjun,LIU Luojin,LIANG Xiaokai,XU Shuai,YONG Qilong. TiC Precipitation Behavior and Its Effect on Abrasion Resistance of High Titanium Wear-Resistant Steel. Acta Metall Sin, 2020, 56(4): 661-672.
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Abstract In general, the wear resistance of traditional low alloy wear-resistant steels can be improved by increasing the hardness of steel matrix, but this significantly deteriorates the processing properties of steel, such as weldability, formability and machinability. Therefore, how to improve the wear resistance of steels without increasing the hardness has become an important issue for the study of wear-resistant steels in recent years. In this work, it is prosposed to introduce ultra-hard TiC particles into the matrix of steel by means of high-Ti microalloying and in situ reaction of TiC in billets (ingots), so as to achieve a significant increase in the wear resistance without increasing the hardness. Seven tested steels with different Ti and C contents were firstly fabricated by smelting, hot rolling and heat treatment, then the morphology, size distribution and fraction of precipitates were characterized by means of OM, SEM, EPMA, TEM, physical-chemical phase analysis, etc. Finally, the wear resistance and its mechanisms of the tested steels were investigated. The results show that TiC particles in the tested steels exhibit an unique trimodal distribution characteristic of "micron-submicron-nanometer". The micron-sized TiC particles were originated from the eutectic reaction of L→γ+TiC occuring at the end of solidification; the eutectic TiC was broken up into small fragments and homogenized gradually during the subsequent hot rolling. The submicron-sized particles were mainly precipitated from austenite at relatively high temperature after solidification, and the nano-sized particles were mainly precipitated from deformed austenite at relatively low temperature during hot rolling. The size of precipitates becomes finer at lower precipitation temperature. The relative precipitation-temperature-time (PTT) diagrams of both submicron-sized and nano-sized TiC were calculated, and it is shown that the most rapid precipitation temperature of the submicron-sized TiC is about 208 ℃ higher than that of the nano-sized TiC. The relative wear resistance of the tested steels is found to increase linearly with increasing TiC fraction, and the improvement of wear resistance is mainly due to the obstruction of micron-sized particles on wear furrow.
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Received: 04 November 2019
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| Fund: National Key Research and Development Program of China(2017YFB0305100) |
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