METALS AND METAL MATRIX COMPOSITES |
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Improvement of the Microstructure and Properties of Iron-based Material Directly Synthesized from Vanadium-bearing Titanomagnetite Concentrate by Heat Treatment |
CHEN Sitan, FENG Keqin*, ZHANG Yanyan, CAI Yuchen
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School of Mechanical Engineering, Sichuan University, Chengdu 610065,China |
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Abstract An iron-based friction material was directly prepared from vanadium-bearing titanomagnetite concentrate by selective carbothermal in-situ reaction and vacuum sintering technology. This study focuses on the effects of quenching and tempering on the material. The results show that the material's microstructure and properties are improved by appropriate quenching and tempering. The microstructure of the material changes from pearlite to martensite by quenching at 900—1 000 ℃. With the increase of quenching temperature, the hardness and tribological properties are enhanced and reach the best by quenching at 950 ℃. Meanwhile, the tribological behavior is ameliorated from severe abrasive and adhesive wear to abrasive wear. Then, 950 ℃ quenched materials were tempered at 250 ℃, 500 ℃ and 650 ℃ respectively. The microstructure changes from martensite to lower-hardness troostite by tempering at 500 ℃, and lowest-hardness sorbate is generated by tempering at 650 ℃. Particularly, secondary hardening in tempering and dissolution of carbides occur by tempering at 500 ℃〗. Therefore, the hardness and tribological properties only get improved when tempering temperature is 500 ℃, and the tribological behavior changes to mild abrasive wear. Consequently, by quenching at 950 ℃ and then tempering at 500 ℃, the microstructure and properties of iron-based friction materials reach the maximum value. The hardness increases by 32%, wear rate decreases by 61% and the friction coefficient decreases by 18%.
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Published: 03 August 2021
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Fund:Panzhihua Municipal Science and Technology Project (2017CY-C-1). |
About author:: Sitan Chen under post-graduate of Sichuan University since Sep. 2019. He is now engaged in utilization of the vanadium and titanium resource. Keqin Feng professor of Sichuan University,Ph.D. supervisor. She has been long engaged in metal-ceramic composite materials, comprehensive utilization of vanadium and titanium resources, synthesis and preparation of field assisted materials, physical and chemical pro-perties of materials preparation and metallurgical. She has published more than 140 academic papers in core academic journals, including 53 SCI papers and 82 EI papers. |
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