何臻毅,程永奇,陈宇航,麦兴广,林灿鑫,鲁一田

• 1:广东工业大学材料与能源学院

摘要(Abstract)：

采用光学显微镜、扫描电镜、X射线衍射仪、洛氏硬度计和HT-1000高温摩擦磨损试验机等研究了不同淬火温度对冷轧辊用MC3钢组织、硬度和摩擦性能的影响。结果表明:淬火后,冷轧辊用MC3钢基体组织由铁素体向隐针状马氏体转变,同时碳化物溶解并伴随有残留奥氏体的生成,当淬火温度超过920℃时,马氏体组织严重粗化,残留奥氏体体积分数急剧增加。随着淬火温度的升高,MC3钢的硬度和耐磨性都呈先升高后下降的趋势,当淬火温度为920℃时,硬度达到最大值63.8 HRC,平均摩擦系数为0.61,体积磨损量为0.164 mm~3,耐磨性最佳。

关键词(KeyWords)： MC3钢;淬火温度;冷轧辊;组织;摩擦性能

Abstract:

Keywords:

基金项目(Foundation): 揭阳市科技计划项目(2017xm066)

作者(Author): 何臻毅,程永奇,陈宇航,麦兴广,林灿鑫,鲁一田

DOI: 10.13289/j.issn.1009-6264.2021-0255

参考文献(References)：

• [1] 朱元健，李亨，王汉，等.8Cr5MoV冷轧工作辊用钢的热变形行为[J].锻压技术，2020,45(9):171-176.ZHU Yuan-jian,LI Heng,WANG Han,et al.Hot deformation behavior of 8Cr5MoV steel for cold working roller[J].Forging and Stamping Technology,2020,45(9):171-176.
• [2] 王泽，王婷婷，金东浩，等.高合金钢冷轧工作辊锻造过程数值模拟[J].锻压技术，2020,45(1):22-29.WANG Ze,WANG Ting-ting,JIN Dong-hao,et al.Numerical simulation of forging process for high alloy steel cold work roller[J].Forging and Stamping Technology,2020,45(1):22-29.
• [3] 陈星，刘新灵，陶春虎，等.轧辊服役损伤行为及失效机制研究[J].失效分析与预防，2018,13(1):60-66.CHEN Xing,LIU Xin-ling,TAO Chun-hu,et al.Study on damage behavior and failure mechanism of rollers[J].Failure Analysis and Prevention,2018,13(1):60-66.
• [4] 白万真，魏世忠，龙锐，等.冷轧辊典型失效形式分析综述[J].铸造技术，2006(9):1010-1014.BAI Wan-zhen,WEI Shi-zhong,LONG Rui,et al.Analysis and reviews on the typical failure forms of cold roll[J].Foundry Technology,2006(9):1010-1014.
• [5] 符寒光，汪长安.高速钢轧辊的热处理工艺[J].金属热处理，2010,35(9):60-65.FU Han-guang,WANG Chang-an.Heat treatment process of high speed steel roll[J].Heat Treatment of Metals,2010,35(9):60-65.
• [6] 王天义，曹建芳，饶建华.轧辊材料及其热处理工艺发展的现状与趋势[J].南方金属，2005(1):4-6.WANG Tian-yi,CAO Jian-fang,RAO Jian-hua.Present status and development trends of roll material and its heat treatments[J].Southern Metals,2005(1):4-6.
• [7] 徐锟，侯兴慧，刘喜海，等.冷轧辊用MC5锻钢的碳化物超细化工艺[J].金属热处理，2018,43(8):103-107.XUN Kun,HOU Xing-hui,LIU Xi-hai,et al.Carbide ultra-fine process of MC5 forging steel for cold roller[J].Heat Treatment of Metals,2018,43(8):103-107.
• [8] 孙世清，梁文瑞，张楠.9Cr5MoV钢的磁性分析与深冷处理[J].河北科技大学学报，2013,34(1):75-78.SUN Shi-qing,LIANG Wen-rui,ZHANG Nan.Magnetic analysis and deep cryogenic treatment of 9Cr5MoV steel[J].Journal of Hebei University of Science and Technology,2013,34(1):75-78.
• [9] Liu X N,Fu H G,Qu Y H,et al.Effect of quenching temperature on microstructure and properties of Al-bearing high-boron high-speed steel[J].Transactions of the Indian Institute of Metals,2019,72(12):3107-3116.
• [10] 元亚莎，王文焱，许开辉，等.差温热处理工艺对Cr5钢摩擦磨损性能的影响[J].钢铁，2015,50(10):71-76.YUAN Ya-sha,WANG Wen-yan,XU Kai-hui,et al.Influence of differential heat treatment on wear resistance of Cr5 steel[J].Iron and Steel,2015,50(10):71-76.
• [11] 郭威.冷轧工作辊水淬油冷工艺参数控制[D].北京：机械科学研究总院，2016.GUO Wei.Process parameter control of water quenching and oil cooling for cold work roller[D].Beijing:China Academy of Machinery Science and Technology,2016.
• [12] 冯浩，姜周华，李花兵，等.淬火温度对30Cr15Mo1N高氮轴承钢组织和性能的影响[J].钢铁，2017,52(9):92-98.FENG Hao,JIANG Zhou-hua,LI Hua-bing,et al.Influence of austenitizing temperature on microstructure and mechanical properties of high nitrogen bearing steel 30Cr15Mo1N[J].Iron and Steel,2017,52(9):92-98.
• [13] 张晓东，夏佃秀，王守仁，等.奥氏体化温度对51CrV4钢淬火组织和性能的影响[J].钢铁，2019,54(3):76-81.ZHANG Xiao-dong,XIA Dian-xiu,WANG Shou-ren,et al.Effect of austenitizing temperature on quenching microstructure and properties of 51CrV4 steel[J].Iron and Steel,2019,54(3):76-81.
• [14] 杨继兰，蒋元凯，顾剑锋，等.奥氏体化温度对中碳淬火-配分钢干滑动摩擦磨损性能的影响[J].金属学报，2018,54(1):21-30.YANG Ji-lan,JIANG Yuan-kai,GU Jian-feng,et al.Effect of austenitization temperature on the dry sliding wear properties of a medium carbon quenching and partitioning steel[J].Acta Metallurgica Sinica,2018,54(1):21-30.
• [15] 刘正林.摩擦学原理[M].北京：高等教育出版社，2009.
• [16] Ju J,Fu H,Lei Y.Effect of Al addition on microstructure and properties of an Fe-B-Al alloy[J].Materials Testing,2016,58(9):753-762.
• [17] 孔永华，李思贝，周江龙，等.等温淬火工艺对GCr15钢领组织和耐磨性的影响[J].金属热处理，2016,41(7):95-99.KONG Yong-hua,LI Si-bei,ZHOU Jiang-long,et al.Effect of austempering process parameters on microstructure and wear resistance of GCr15 steel spinning ring[J].Heat Treatment of Metals,2016,41(7):95-99.
• [18] 孙宇凡，杨鹏辉，符寒光，等.奥氏体化温度对高锰含碳化物等温淬火球墨铸铁组织和性能的影响[J].材料热处理学报，2020,41(10):44-50.SUN Yu-fan,YANG Peng-hui,FU Han-guang,et al.Effect of austenitizing temperature on microstructure and properties of high manganese carbidic austempered ductile iron[J].Transactions of Materials and Heat Treatment,2020,41(10):44-50.
• [19] Quinn T F J.Oxidational wear modelling Part III.The effects of speed and elevated temperatures[J].Wear,1998,216(2):262-275.
• [20] 陈康敏，王兰，王树奇，等.H13钢氧化磨损行为的研究[J].摩擦学学报，2011,31(4):317-322.CHEN Kang-min,WANG Lan,WANG Shu-qi,et al.Oxidative wear behavior of H13 steel[J].Tribology,2011,31(4):317-322.
• [21] 陈康敏，王树奇，杨子润，等.钢的高温氧化磨损及氧化物膜的研究[J].摩擦学学报，2008(5):475-479.CHEN Kang-min,WANG Shu-qi,YANG Zi-run,et al.High temperature wear and oxide film of steels[J].Tribology,2008(5):475-479.
• [22] Archard J F.The temperature of rubbing surfaces[J].Wear,1959,2(6):438-455.
• [23] Archard J F.The wear of metals under unlubricated conditions[J].Proceedings of the Royal Society of London.Series A,Mathematical and Physical Sciences,1956,236(1206):397-410.

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