- 中文核心期刊
- CSCD中国科学引文数据库来源期刊
- 中国科技核心期刊
- 中国机械工程学会材料分会会刊
| Citation: |
YU Tao, GUAN Yong, WANG Chuan, FAN Mingda, ZHEN Xingang. Preparation and Heat Treatment Process Optimization of Cr-Mo-B Series NM500 Wear Resistant Steel[J]. Materials and Mechanical Engineering, 2024, 48(12): 50-57. DOI: 10.11973/jxgccl230521
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Throgh adjusting alloy element content on the basis of the composition of Cr-Mo-B series NM450 steel, the 20 mm thick NM500 wear resistant steel plate was prepared by clean steel production technology and rolling process, and then was quenched and tempered. The microstructure and properties of the test steel at different quenching temperatures (880,900,920 ℃) and tempering temperatures (200,250,300,350,400 ℃) were studied, and the best heat treatment process was obtained. The results show that with the increase of quenching temperature, the undissolved ferrite in the test steel microstructure decreased, the austenite grain size first decreased and then slightly increased, the tensile strength, −20 ℃ impact absorbed energy and surface hardness all increased, and the percentage elongation after fracture decreased. In addition to the surface hardness after quenching at 880 ℃ did not meet the standard requirements, the mechanical properties of the test steel under other conditions met the standard requirements. After quenching at 920 ℃, with the increase of tempering temperature, the decomposition of martensite accelerated, the carbon content soluted in the matrix decreased, the number of carbides increased, the strength showed an overall decreasing trend, the percentage elongation after fracture first decreased, then increased and then decreased, and −20 ℃ impact absorbed energy and surface hardness both decreased. After bending test, only the 200 ℃ tempered sample did not fracture and there were no microcracks on the surface. The wear mass loss after tempering at 200 ℃ was significantly less than that after tempering at 400 ℃. After quenching at 920 ℃ and tempering at 200 ℃, the test steel had the best comprehensive mechanical properties with surface hardness of 496 HBW, tensile strength of 1 552 MPa, percentage elongation after fracture of 15.0%, −20 ℃ impact absorbed energy of 46 J, and qualified 180 ° cold bending property, and the properties all met the requirements of GB/T 24186—2022 standard.
| [1] |
宋苏峄,奚艳红. 耐磨钢在矿山机械中的应用[J]. 冶金与材料,2021,13(5):177-178.
SONG S Y ,XI Y H. Application of wear-resistant steel in mining machinery[J]. Metallurgy and Materials,2021,13(5):177-178.
|
| [2] |
李文斌,费静,曹忠孝,等. 我国低合金高强度耐磨钢的生产现状及发展方向[J]. 机械工程材料,2012,36(2):6-10.
LI W B ,FEI J ,CAO Z X ,et al. Production status and development direction of wear resistant steel with low alloy and high strength in China[J]. Materials for Mechanical Engineering,2012,36(2):6-10.
|
| [3] |
王国栋,刘振宇. 新一代节约型高性能结构钢的研究现状与进展[J]. 中国材料进展,2011,30(12):12-17.
WANG G D ,LIU Z Y. Current status and progress on the development of cost-saving and high performance structural steels[J]. Materials China,2011,30(12):12-17.
|
| [4] |
张唤唤,张祖江,吴世庆. 加硼对钢板力学性能的影响及解决措施探讨[J]. 宽厚板,2017,23(4):38-40.
ZHANG H H ,ZHANG Z J ,WU S Q. The effect of boron element content on mechanical properties of steel plate and solution discussion[J]. Wide and Heavy Plate,2017,23(4):38-40.
|
| [5] |
包爽,杨庚蔚,徐耀文,等. 中锰马氏体NM500钢奥氏体晶粒长大行为[J]. 钢铁,2022,57(8):152-159.
BAO S ,YANG G W ,XU Y W ,et al. Austenite grain growth behavior of medium manganese martensitic NM500 steel[J]. Iron & Steel,2022,57(8):152-159.
|
| [6] |
李红斌,姚连登,赵小婷. 新型高强高韧耐磨钢的显微组织与性能[J]. 机械工程材料,2010,34(7):46-48.
LI H B ,YAO L D ,ZHAO X T. Microstructure and properties of new wear resistance steel with high strength and high toughness[J]. Materials for Mechanical Engineering,2010,34(7):46-48.
|
| [7] |
陈英俊,熊文名,傅清霞,等. 低成本NM500耐磨钢板的研发[J]. 江西冶金,2015,35(4):1-3.
CHEN Y J ,XIONG W M ,FU Q X ,et al. Development of low-cost NM500 wear-resistant steel plates[J]. Jiangxi Metallurgy,2015,35(4):1-3.
|
| [8] |
彭欢,胡学文,王海波,等. 热轧超高强钢M1200HS的显微组织与磨粒磨损性能[J]. 机械工程材料,2022,46(1):68-72.
PENG H ,HU X W ,WANG H B ,et al. Microstructure and abrasive wear properties of hot rolled ultra-high strength steel M1200HS[J]. Materials for Mechanical Engineering,2022,46(1):68-72.
|
| [9] |
NAM W J ,LEE C S ,BAN D Y. Effects of alloy additions and tempering temperature on the sag resistance of Si–Cr spring steels[J]. Materials Science and Engineering:A,2000,289(1/2):8-17.
|
| [10] |
衣忠文,麻衡. Nb-Mo、V微合金元素对NM500超高强度耐磨钢板组织与性能的影响[J]. 金属热处理,2013,38(7):57-61.
YI Z W ,MA H. Influences of Nb-Mo,V microalloying on microstructure and properties of NM500 ultrahigh strength wear resistant steel plate[J]. Heat Treatment of Metals,2013,38(7):57-61.
|
| [11] |
宋欣,杨海峰,王川,等. C-Mn-Cr-B系低合金耐磨钢组织性能的研究[J]. 轧钢,2020,37(2):26-33.
SONG X ,YANG H F ,WANG C ,et al. Research on the microstructures and mechanical properties of the C-Mn-Cr-B low alloy wear resistance steel[J]. Steel Rolling,2020,37(2):26-33.
|
| [12] |
王凯凯,马龙腾,罗平,等. 回火温度对贝氏体耐磨钢组织和性能的影响[J]. 金属热处理,2023,48(3):84-90.
WANG K K ,MA L T ,LUO P ,et al. Effect of tempering temperature on microstructure and properties of bainitic wear-resistant steel[J]. Heat Treatment of Metals,2023,48(3):84-90.
|
| [13] |
牛海云,潘泳良,金头男,等. 含钴高钒高速钢回火组织演变和耐磨性[J]. 材料热处理学报,2023,44(8):123-132.
NIU H Y ,PAN Y L ,JIN T N ,et al. Tempered microstructure evolution and wear resistance of cobalt-containing high vanadium high speed steel[J]. Transactions of Materials and Heat Treatment,2023,44(8):123-132.
|
| [14] |
郑健,温长飞,黄龙,等. 低合金高强度耐磨钢板NM500的研发[J]. 金属热处理,2019,44(3):42-46.
ZHENG J ,WEN C F ,HUANG L ,et al. Development of high strength low alloy wear-resistant steel plate NM500[J]. Heat Treatment of Metals,2019,44(3):42-46.
|
| [15] |
朱震宇,吴志方,吴润. 回火温度对NM500耐磨钢组织和性能的影响[J]. 金属热处理,2022,47(10):154-159.
ZHU Z Y ,WU Z F ,WU R. Effect of tempering temperature on microstructure and properties of NM500 wear-resistant steel[J]. Heat Treatment of Metals,2022,47(10):154-159.
|
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