渗铌温度与时间对GCr15钢表面渗铌层组织和性能的影响
Effect of Niobiumizing Temperature and Time on Microstructure andProperties of Niobiumizing Layer on GCr15 Steel Surface
摘 要
采用固体粉末包埋法,在不同温度(910,930,950,970℃)和不同保温时间(1,2,4,5,6 h)下在销轴用GCr15钢表面制备渗铌层,研究了渗铌温度与时间对渗铌层的微观形貌、物相组成、显微硬度、耐磨性能和耐腐蚀性能的影响。结果表明:在不同条件下制备的渗铌层与基体结合紧密,主要由NbC和α-Fe组成;随着渗铌温度的升高或渗铌时间延长,NbC相增多,α-Fe相逐渐消失,渗铌层厚度和显微硬度增大;当渗铌温度为950℃、渗铌时间为2 h时,渗铌层的自腐蚀电位最大,自腐蚀电流密度最小,耐腐蚀性能最好。综合考虑厚度、耐腐蚀性能和耐磨性能,较佳的渗铌工艺为渗铌温度950℃、渗铌时间5 h,在该条件下制备的渗铌层耐腐蚀性能较好,摩擦因数波动小,平均摩擦因数仅为0.22。
渗铌
显微组织
耐磨性能
耐腐蚀性能
solid powder packing
niobiumizing
microstructure
wear resistance
corrosion resistance
Abstract
Niobiumizing layer was prepared on surface of GCr15 steel for pin shaft by solid powder packing method at different temperatures (910, 930, 950, 970℃) for different holding times (1, 2, 4, 5, 6 h). The effect of niobiumizing temperature and time on micromorphology, phase composition, microhardness, wear resistance and corrosion resistance of the niobiumizing layer was investigated. The results show that the niobiumizing layer prepared under different conditions was closely combined with the matrix. The niobiumizing layer was composed of NbC and α-Fe. With increasing niobiumizing temperature or niobiumizing time, the amount of NbC phase increased, the α-Fe phase disappeared gradually, and the thickness and microhardness of the niobiumizing layer increased. When the niobiumizing temperature was 950℃ and the niobiumizing time was 2 h, the self-corrosion potential of the niobiumizing layer was the largest and the self-corrosion current density was the smallest, indicating the corrosion resistance was the best. Considering the thickness, corrosion resistance and wear resistance comprehensively, the optimal niobiumizing process was niobiumizing temperature of 950℃ and niobiumizing time of 5 h. The niobiumizing layer prepared under this condition had relatively good corrosion resistance and small fluctuation of friction coefficients, and the average friction coefficient was only 0.22.
中图分类号 TG178 DOI 10.11973/jxgccl202302011
所属栏目 材料性能及应用
基金项目 辽宁省科技厅指导计划项目(2019-ZD-0703)
收稿日期 2022/1/28
修改稿日期 2022/12/22
网络出版日期
作者单位点击查看
备注孟令耀(1997-),男,山东济南人,硕士研究生
引用该论文: MENG Lingyao,SHANG Jian,ZHANG Mengjiu,XIE Aijun,ZHANG Yue. Effect of Niobiumizing Temperature and Time on Microstructure andProperties of Niobiumizing Layer on GCr15 Steel Surface[J]. Materials for mechancial engineering, 2023, 47(2): 61~66
孟令耀,商剑,张孟九,谢爱军,张越. 渗铌温度与时间对GCr15钢表面渗铌层组织和性能的影响[J]. 机械工程材料, 2023, 47(2): 61~66
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参考文献
【1】陈龙, 颉潭成, 夏新涛.滚动轴承应用技术[M].北京:机械工业出版社, 2010. CHEN L, XIE T C, XIA X T.Rolling bearing application technology[M].Beijing:China Machine Press, 2010.
【2】徐玉兰, 赵航.渗碳型高温轴承钢的研究[J].钢铁研究学报, 1995, 7(3):85-89. XU Y L, ZHAO H.Carburized high temperature bearing steels[J].Journal of Iron and Steel Research, 1995, 7(3):85-89.
【3】王德勇, 张群, 齐锐.GCr15轴承钢成品套圈热处理后点线状缺陷原因分析[J].金属热处理, 2020, 45(10):241-245. WANG D Y, ZHANG Q, QI R.Reason analysis of punctiform and linear defects on GCr15 bearing steel ring after heat treatment[J].Heat Treatment of Metals, 2020, 45(10):241-245.
【4】扈林庄, 郭浩, 雷建中, 等.控锻控冷工艺对GCr15轴承钢组织演变规律的影响[J].金属热处理, 2020, 45(9):134-138. HU L Z, GUO H, LEI J Z, et al.Influence of controlled forging and cooling process on microstructure evolution of GCr15 bearing steel[J].Heat Treatment of Metals, 2020, 45(9):134-138.
【5】张艳君, 闵永安, 刘湘江, 等.GCr15轴承套圈组织分布特点及碳化物均匀性[J].金属热处理, 2019, 44(12):6-12. ZHANG Y J, MIN Y A, LIU X J, et al.Microstructure distribution characteristics and carbide homogeneity of GCr15 bearing ring[J].Heat Treatment of Metals, 2019, 44(12):6-12.
【6】万海鑫, 马思远, 刘立峰, 等.工程机械齿轮的表面改性层及其摩擦磨损性能[J].金属热处理, 2018, 43(8):77-83. WAN H X, MA S Y, LIU L F, et al.Surface modification layer of engineering machinery gear and its friction and wear resistance[J].Heat Treatment of Metals, 2018, 43(8):77-83.
【7】BHADESHIA H K D H.Steels for bearings[J].Progress in Materials Science, 2012, 57(2):268-435.
【8】齐宝森, 陈路宾, 王忠诚.化学热处理技术[M].北京:化学工业出版社, 2006. QI B S, CHEN L B, WANG Z C.Chemical heat treatment technology[M].Beijing:Chemical Industry Press, 2006.
【9】王浩, 叶健熠, 薛文方, 等.渗氮预处理对GCr15轴承钢性能的影响[J].轴承, 2016(7):37-38. WANG H, YE J Y, XUE W F, et al.Effect of nitriding pretreatment on properties of bearing steel GCr15[J].Bearing, 2016(7):37-38.
【10】陈跃勤, 唐英.GCr15钢不同热处理后的磨损特征[J].金属热处理, 2000, 25(11):18-20. CHEN Y Q, TANG Y.Wear resistance of GCr15 steel through different heat treatment[J].Heat Treatment of Metals, 2000, 25(11):18-20.
【11】FERNANDES F A P, GALLEGO J, PICON C A, et al.Wear and corrosion of niobium carbide coated AISI 52100 bearing steel[J].Surface and Coatings Technology, 2015, 279:112-117.
【12】YAN S J, WANG H F, SUN Q K, et al.Growth characteristics and kinetics of niobium carbide coating obtained on AISI 52100 by thermal-reactive diffusion technique[J].Journal of Wuhan University of Technology (Materials Science Edition), 2014, 29(4):808-812.
【13】周超梅, 解生泽, 杜弘.硼砂盐浴渗铌工艺及渗层性能的研究[J].热加工工艺, 2008, 37(4):84-85. ZHOU C M, XIE S Z, DU H.Study on permeating Nb technology of borax salt-bathing and property of permeating layer[J].Hot Working Technology, 2008, 37(4):84-85.
【14】孙启坤, 王华昌, 王华君.TD法盐浴渗铌工艺及覆层性能研究[J].热加工工艺, 2012, 41(4):181-184. SUN Q K, WANG H C, WANG H J.Research on niobium carbide coating process by TD technique in salt bath and properties of coating[J].Hot Working Technology, 2012, 41(4):181-184.
【15】严茂芳.渗铌层的组织与性能研究[J].热加工工艺, 1991, 20(4):28-30. YAN M F.The study of the microstructure and properties of niobium case-hardening layer[J].Hot Working Technology, 1991, 20(4):28-30.
【16】宗晓明, 蒋文明, 樊自田, 等.GCr15轴承钢表面渗硼层生长动力学与机械性能[J].工程科学学报, 2018, 40(9):1108-1114. ZONG X M, JIANG W M, FAN Z T, et al.Kinetics and mechanical properties of borided GCr15 bearing steel[J].Chinese Journal of Engineering, 2018, 40(9):1108-1114.
【17】魏祥, 蒋彦清, 庾灵颉, 等.65Mn钢渗硼层的微观组织、硬度及生长动力学[J].金属热处理, 2021, 46(11):110-119. WEI X, JIANG Y Q, YU L J, et al.Microstructure, hardness and growth kinetics of 65Mn steel borided layer[J].Heat Treatment of Metals, 2021, 46(11):110-119.
【18】潘邻.表面改性热处理技术与应用[M].北京:机械工业出版社, 2006. PAN L.Surface modification heat treatment technology and application[M].Beijing:China Machine Press, 2006.
【2】徐玉兰, 赵航.渗碳型高温轴承钢的研究[J].钢铁研究学报, 1995, 7(3):85-89. XU Y L, ZHAO H.Carburized high temperature bearing steels[J].Journal of Iron and Steel Research, 1995, 7(3):85-89.
【3】王德勇, 张群, 齐锐.GCr15轴承钢成品套圈热处理后点线状缺陷原因分析[J].金属热处理, 2020, 45(10):241-245. WANG D Y, ZHANG Q, QI R.Reason analysis of punctiform and linear defects on GCr15 bearing steel ring after heat treatment[J].Heat Treatment of Metals, 2020, 45(10):241-245.
【4】扈林庄, 郭浩, 雷建中, 等.控锻控冷工艺对GCr15轴承钢组织演变规律的影响[J].金属热处理, 2020, 45(9):134-138. HU L Z, GUO H, LEI J Z, et al.Influence of controlled forging and cooling process on microstructure evolution of GCr15 bearing steel[J].Heat Treatment of Metals, 2020, 45(9):134-138.
【5】张艳君, 闵永安, 刘湘江, 等.GCr15轴承套圈组织分布特点及碳化物均匀性[J].金属热处理, 2019, 44(12):6-12. ZHANG Y J, MIN Y A, LIU X J, et al.Microstructure distribution characteristics and carbide homogeneity of GCr15 bearing ring[J].Heat Treatment of Metals, 2019, 44(12):6-12.
【6】万海鑫, 马思远, 刘立峰, 等.工程机械齿轮的表面改性层及其摩擦磨损性能[J].金属热处理, 2018, 43(8):77-83. WAN H X, MA S Y, LIU L F, et al.Surface modification layer of engineering machinery gear and its friction and wear resistance[J].Heat Treatment of Metals, 2018, 43(8):77-83.
【7】BHADESHIA H K D H.Steels for bearings[J].Progress in Materials Science, 2012, 57(2):268-435.
【8】齐宝森, 陈路宾, 王忠诚.化学热处理技术[M].北京:化学工业出版社, 2006. QI B S, CHEN L B, WANG Z C.Chemical heat treatment technology[M].Beijing:Chemical Industry Press, 2006.
【9】王浩, 叶健熠, 薛文方, 等.渗氮预处理对GCr15轴承钢性能的影响[J].轴承, 2016(7):37-38. WANG H, YE J Y, XUE W F, et al.Effect of nitriding pretreatment on properties of bearing steel GCr15[J].Bearing, 2016(7):37-38.
【10】陈跃勤, 唐英.GCr15钢不同热处理后的磨损特征[J].金属热处理, 2000, 25(11):18-20. CHEN Y Q, TANG Y.Wear resistance of GCr15 steel through different heat treatment[J].Heat Treatment of Metals, 2000, 25(11):18-20.
【11】FERNANDES F A P, GALLEGO J, PICON C A, et al.Wear and corrosion of niobium carbide coated AISI 52100 bearing steel[J].Surface and Coatings Technology, 2015, 279:112-117.
【12】YAN S J, WANG H F, SUN Q K, et al.Growth characteristics and kinetics of niobium carbide coating obtained on AISI 52100 by thermal-reactive diffusion technique[J].Journal of Wuhan University of Technology (Materials Science Edition), 2014, 29(4):808-812.
【13】周超梅, 解生泽, 杜弘.硼砂盐浴渗铌工艺及渗层性能的研究[J].热加工工艺, 2008, 37(4):84-85. ZHOU C M, XIE S Z, DU H.Study on permeating Nb technology of borax salt-bathing and property of permeating layer[J].Hot Working Technology, 2008, 37(4):84-85.
【14】孙启坤, 王华昌, 王华君.TD法盐浴渗铌工艺及覆层性能研究[J].热加工工艺, 2012, 41(4):181-184. SUN Q K, WANG H C, WANG H J.Research on niobium carbide coating process by TD technique in salt bath and properties of coating[J].Hot Working Technology, 2012, 41(4):181-184.
【15】严茂芳.渗铌层的组织与性能研究[J].热加工工艺, 1991, 20(4):28-30. YAN M F.The study of the microstructure and properties of niobium case-hardening layer[J].Hot Working Technology, 1991, 20(4):28-30.
【16】宗晓明, 蒋文明, 樊自田, 等.GCr15轴承钢表面渗硼层生长动力学与机械性能[J].工程科学学报, 2018, 40(9):1108-1114. ZONG X M, JIANG W M, FAN Z T, et al.Kinetics and mechanical properties of borided GCr15 bearing steel[J].Chinese Journal of Engineering, 2018, 40(9):1108-1114.
【17】魏祥, 蒋彦清, 庾灵颉, 等.65Mn钢渗硼层的微观组织、硬度及生长动力学[J].金属热处理, 2021, 46(11):110-119. WEI X, JIANG Y Q, YU L J, et al.Microstructure, hardness and growth kinetics of 65Mn steel borided layer[J].Heat Treatment of Metals, 2021, 46(11):110-119.
【18】潘邻.表面改性热处理技术与应用[M].北京:机械工业出版社, 2006. PAN L.Surface modification heat treatment technology and application[M].Beijing:China Machine Press, 2006.
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