引进泵缸体材料激光热处理的研究
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摘要
B系列泵是我国引进技术生产的一种柱塞泵,其中关键零件缸体在国产化过程中不耐磨。生产厂家经过多年努力,寻找到了缸体较理想的代用材料是QT600-3球墨铁,而工件在常规淬火工艺中变形很大。激光淬火以加热冷却速度极快、工艺固定期短优势,能很好地使工件表面强化,增加耐磨性,而变形量又很少。激光淬火能解决B系列泵中缸体不耐磨和变形的问题。
本文从我国高功率CO_2激光工业应用发展水平出发,对激光淬火技术中涉及的工艺参数优化进行了系统的实验研究,简述了激光表面强化技术的研究及最新进展,介绍了QT600-3材料和QT600-3缸体激光淬火强化机理、设备装置,设计了实验方案和具体实验方法。
分析了QT600-3材料的激光淬火中矩形光束对表面硬度分布及淬硬层深度硬度分布的影响,实验过程中保持光斑大小不变,调整激光功率和扫描速度,得到了最佳的激光功率和扫描速度的范围,光斑大小为5mm×4mm时,QT600-3最佳的激光功率密度范围为W=4.5-5kw/cm~2,扫描速度为v=4-5mm/s,淬硬层的宽度为4.5mm左右,淬硬层的平均硬度值达920HV,达到基体硬度的2.3倍左右,深度达0.55mm左右,激光淬硬层为均匀相变区和过渡区二个区域。激光淬火后材料比常规淬火的材料明显耐磨。
以QT600-3材料激光淬火优化工艺参数为基础,对QT600-3缸体工件进行宽带激光淬火研究。研究结果表明:QT600-3材料缸体采用的热处理工艺为:激光淬火,CO_2激光器宽带扫描,工艺参数取值范围为:W=4.5-5kw/cm~2,v=4-5mm/s,就能实现缸体耐磨,变形少,彻底解决B系列泵国产化的关键技问题。
The pump of B array is a filled pillar pump produced by our country with introductive technology, its key part cylinder block doesn't wear resistant in national.QT600-3 Nodular iron, a more ideal substitution of cylinder block, is founded by years' effort, but it deforms greatly in the normal quenching. Laser quenching takes the advantage of having a fast cool speed and a short fix time which can solve the wear resistant less and deformation problems.
With the development of high power laser, much progress has been made in laser quenching processing and parameters optimization included which introduces the QT600-3 material and strengthen principles, facilities as well as the specific steps of experiment
The surface-quenching of QT600-3 material was carried out with a laser rectangle beam. The surface-hardness distribution and hardened depth with the hardened layer were studied. When he light spot is 5mm X 4mm, with the best laser power between 4 and 5.5 kw/cm2,the scanning speed at 4-5.5mm/s,the hardened with 4mm,the average misro-hardeness of Qt600-3 can reach 950Hv, Which is about 2.3 times as high as that of normal hardness, also the depth of 0.55mm is obtained. The hardened layer consists of two sub-layers, uniform phasetransfomation laser and transition layers. The material after laser quenched is obvious much more wear resistant than normal one.
The study of QT600-3 cylinder block with wide-hand laser quenching which bused on the laser quenching optimal parameters of QT600-3 indicates that the hot process used by the QT600-3 cylinder block are: laser quenching wide-band CO2 laser scanning with the processing parameters are 4-5kw/cm2 of power and 4-5.5mm/s at speed. Then the wear resistance and little deformation of cylinder block can realize, so the key technique of B array pump can be solved completely.
本文从我国高功率CO_2激光工业应用发展水平出发,对激光淬火技术中涉及的工艺参数优化进行了系统的实验研究,简述了激光表面强化技术的研究及最新进展,介绍了QT600-3材料和QT600-3缸体激光淬火强化机理、设备装置,设计了实验方案和具体实验方法。
分析了QT600-3材料的激光淬火中矩形光束对表面硬度分布及淬硬层深度硬度分布的影响,实验过程中保持光斑大小不变,调整激光功率和扫描速度,得到了最佳的激光功率和扫描速度的范围,光斑大小为5mm×4mm时,QT600-3最佳的激光功率密度范围为W=4.5-5kw/cm~2,扫描速度为v=4-5mm/s,淬硬层的宽度为4.5mm左右,淬硬层的平均硬度值达920HV,达到基体硬度的2.3倍左右,深度达0.55mm左右,激光淬硬层为均匀相变区和过渡区二个区域。激光淬火后材料比常规淬火的材料明显耐磨。
以QT600-3材料激光淬火优化工艺参数为基础,对QT600-3缸体工件进行宽带激光淬火研究。研究结果表明:QT600-3材料缸体采用的热处理工艺为:激光淬火,CO_2激光器宽带扫描,工艺参数取值范围为:W=4.5-5kw/cm~2,v=4-5mm/s,就能实现缸体耐磨,变形少,彻底解决B系列泵国产化的关键技问题。
The pump of B array is a filled pillar pump produced by our country with introductive technology, its key part cylinder block doesn't wear resistant in national.QT600-3 Nodular iron, a more ideal substitution of cylinder block, is founded by years' effort, but it deforms greatly in the normal quenching. Laser quenching takes the advantage of having a fast cool speed and a short fix time which can solve the wear resistant less and deformation problems.
With the development of high power laser, much progress has been made in laser quenching processing and parameters optimization included which introduces the QT600-3 material and strengthen principles, facilities as well as the specific steps of experiment
The surface-quenching of QT600-3 material was carried out with a laser rectangle beam. The surface-hardness distribution and hardened depth with the hardened layer were studied. When he light spot is 5mm X 4mm, with the best laser power between 4 and 5.5 kw/cm2,the scanning speed at 4-5.5mm/s,the hardened with 4mm,the average misro-hardeness of Qt600-3 can reach 950Hv, Which is about 2.3 times as high as that of normal hardness, also the depth of 0.55mm is obtained. The hardened layer consists of two sub-layers, uniform phasetransfomation laser and transition layers. The material after laser quenched is obvious much more wear resistant than normal one.
The study of QT600-3 cylinder block with wide-hand laser quenching which bused on the laser quenching optimal parameters of QT600-3 indicates that the hot process used by the QT600-3 cylinder block are: laser quenching wide-band CO2 laser scanning with the processing parameters are 4-5kw/cm2 of power and 4-5.5mm/s at speed. Then the wear resistance and little deformation of cylinder block can realize, so the key technique of B array pump can be solved completely.
引文
[1] 何存兴.液压传动与气压传动.(第二版).武汉:华中科技大学出版社,2000.87-92
[2] Remy Fabro, Proc. of the 1994 conf on lasers and Electro-Optics Europe June, 1994, NJ USA
[3] 45#/35#钢的激光表面改性研究,郑州大学硕士论 2001
[4] 徐方大、陈朝晖、张永康,江苏理工大学学报 2001.22(2)18-21
[5] 陈奉斌、毕瑞等,江苏理工大学学报 2001.22(2) 22-25
[6] 林子光,激光淬火提高发动机汽缸抗磨性能的研究,润滑与刻封,2000.6 15-17
[7] 徐春鹰、石岩等,激光淬火齿轮组织分析,长春理工大学学报,2002.25(4),14-16
[8] 周建忠、杨继昌,齿轮激光淬火工艺及性能研究,农业机械学报,2002.22(5),93-96
[9] 张宏等,齿轮激光表面强化技术研究,应用激光,2000.20(2),64-66
[10] 石岩等,齿轮宽带激光淬火工艺研究,中国机械工程,2003.14(6),523-526
[11] 李俊昌著,激光热处理优化控制研究,北京;冶金工业出版社
[12] 莆万林、彭爱萍等,中国激光,1983,10(11)759-764
[13] 张三川,白口铸铁磨辊表面的激光淬火强化工艺。电加工与模具,2001.2 42-44
[14] 张三川,合金铸铁激光淬火工艺规范及组织性能,制造技术与机床,200.12 29-30
[15] 王华明,Bergaman H W,材料研究学报,1998.12(1)
[16] 王月山、张宏、石岩等,金属执处理,1992.(2):14-16
[17] KovalenkOV,GolovkoL.1993,激光热变形材料淬硬,国际会议学报,电子来和激光学报 Rew,美国
[18] 张朝阳,张永康、汽缸表面处的新发展——激光珩磨,激光技术,27(1)58-61
[19] 胡乾午、吕卫文、刘顺洪等,磷化和胶体涂料在汽缸激光淬火中的对比试验(J),金属热处理,1994,(4)37—38。
[20] 刘文今等,第三届全国激光热处理学术年会论文集,1997,43—6。
[21] 梁二军等CO2激光热处理专用涂料,科学技术成果,鉴定材料(豫科鉴委字[1997],第384号)
[22] Miller J.E, Wineman J.A, Metal progress. 1997, 111: 38—42。
[23] Stanford K,Metallurgia 1980,47(3):109—116。
[24] Bresden A S,Gazzade ST,et a1,Surface Engineering,1998(2):107—113。
[25] Camolrtto A,Molino G,Material and~lanufacturing processes,1991,6(1):53—65。
[26] 房为婕,金属表面激光相变硬化、金属热处理,1982(6):12—20。
[27] 姚善长,激光表面相变硬化,金属热处理,1987(2):39—43。
[28] 王家金等,激光加工技术,北京:中国计量出版社,1992。
[29] Gnanamuthu O S, U.S Pateeent 2952180, April, 20, 1976。
[30] Wang H G, Chen Y H, Zhang T A study of Thermal stresses during g Laser Qurnching[J]. Journal of Materiel Processing Technology, 1997(63) :550—553.
[31] Adam Bokota, slawomir I skierka. Numerical Prediction of the Hardened Zone in Carbon steel [J] ARI MASTER, 1996 (2):445—450.
[32] 李俊昌,激光热处理优化控制研究[M]。北京:冶金工业出版社,1995。
[33] 任思扬等,激光相变硬化工艺参数的选择[J],激光技术,1997,2(4):210—214。
[34] 王补宣,工程传热传质学[M],北京:科学出版社,1981。
[35] 吴刚,激光相变硬化温度场模拟及激光参数的优化选择[D]、上海海运学院,1999
[36] 李俊昌,R;谢瓦利埃,J.M.兰热,中国激光1997,A24(7)。
[37] 李俊昌,李行一,陈庆华等,材料研究学报,1998,12(3)。
[38] 吴钢,石娟等,应用激光,1999,19(3)。
[39] 夏国华,杨树容,相代热处理技术、北京:兵器工业出版社,1996,11:18
[40] 杜则裕,刘继元,张世林等工程材料简明手册,北京:电子工业出版社,1996年,112。
[41] 花银群,陈瑞芳,球失曲轴激光淬光工艺的研究新技术、新工艺,2001 33(1) 55—56。
[42] 周建忠等,球铁曲轴激光淬火技术研究,农业机械学校,2001,32(3)109—112。
[43] 张三川,铸铁曲轴激光淬火,金属执处理,2001.3 9-11
[44] 刘怀喜,灰口铸铁磨辊表面激光淬火的组织性能研究,机械工程材料,2000.24(6),27-31
[45] 梁二军等,45#钢宽带激光淬火研究,激光杂志,2001.22(2) 52-54
[46] 刘文今等,45#钢凸轮表面的激光熔凝——合金化复合强化工艺,第六届全国激光热处理学
术年会论文集,1997,2-6
[47] 戴忠森等,齿轮热处理工艺的研究,第六届全国激光热处理学术年会论文集,1997,12-18
[48] Grunenwald B, et al, New technolical development in laser cladding ICALEO, 1993:934
[49] H. vilar, cladding, Journal of lasersapplications, 1999, 11(2)
[50] J. Lin.,W.M. steen, Journal of laser Applications, 1998,10(2):55-63
[51] Depascale O, et al, Optics and lasers in Engineering, 1985(6):157
[52] Idem, Coating characterization in controlled surface temperature laser heat treating IBID, 1988(8):97
[2] Remy Fabro, Proc. of the 1994 conf on lasers and Electro-Optics Europe June, 1994, NJ USA
[3] 45#/35#钢的激光表面改性研究,郑州大学硕士论 2001
[4] 徐方大、陈朝晖、张永康,江苏理工大学学报 2001.22(2)18-21
[5] 陈奉斌、毕瑞等,江苏理工大学学报 2001.22(2) 22-25
[6] 林子光,激光淬火提高发动机汽缸抗磨性能的研究,润滑与刻封,2000.6 15-17
[7] 徐春鹰、石岩等,激光淬火齿轮组织分析,长春理工大学学报,2002.25(4),14-16
[8] 周建忠、杨继昌,齿轮激光淬火工艺及性能研究,农业机械学报,2002.22(5),93-96
[9] 张宏等,齿轮激光表面强化技术研究,应用激光,2000.20(2),64-66
[10] 石岩等,齿轮宽带激光淬火工艺研究,中国机械工程,2003.14(6),523-526
[11] 李俊昌著,激光热处理优化控制研究,北京;冶金工业出版社
[12] 莆万林、彭爱萍等,中国激光,1983,10(11)759-764
[13] 张三川,白口铸铁磨辊表面的激光淬火强化工艺。电加工与模具,2001.2 42-44
[14] 张三川,合金铸铁激光淬火工艺规范及组织性能,制造技术与机床,200.12 29-30
[15] 王华明,Bergaman H W,材料研究学报,1998.12(1)
[16] 王月山、张宏、石岩等,金属执处理,1992.(2):14-16
[17] KovalenkOV,GolovkoL.1993,激光热变形材料淬硬,国际会议学报,电子来和激光学报 Rew,美国
[18] 张朝阳,张永康、汽缸表面处的新发展——激光珩磨,激光技术,27(1)58-61
[19] 胡乾午、吕卫文、刘顺洪等,磷化和胶体涂料在汽缸激光淬火中的对比试验(J),金属热处理,1994,(4)37—38。
[20] 刘文今等,第三届全国激光热处理学术年会论文集,1997,43—6。
[21] 梁二军等CO2激光热处理专用涂料,科学技术成果,鉴定材料(豫科鉴委字[1997],第384号)
[22] Miller J.E, Wineman J.A, Metal progress. 1997, 111: 38—42。
[23] Stanford K,Metallurgia 1980,47(3):109—116。
[24] Bresden A S,Gazzade ST,et a1,Surface Engineering,1998(2):107—113。
[25] Camolrtto A,Molino G,Material and~lanufacturing processes,1991,6(1):53—65。
[26] 房为婕,金属表面激光相变硬化、金属热处理,1982(6):12—20。
[27] 姚善长,激光表面相变硬化,金属热处理,1987(2):39—43。
[28] 王家金等,激光加工技术,北京:中国计量出版社,1992。
[29] Gnanamuthu O S, U.S Pateeent 2952180, April, 20, 1976。
[30] Wang H G, Chen Y H, Zhang T A study of Thermal stresses during g Laser Qurnching[J]. Journal of Materiel Processing Technology, 1997(63) :550—553.
[31] Adam Bokota, slawomir I skierka. Numerical Prediction of the Hardened Zone in Carbon steel [J] ARI MASTER, 1996 (2):445—450.
[32] 李俊昌,激光热处理优化控制研究[M]。北京:冶金工业出版社,1995。
[33] 任思扬等,激光相变硬化工艺参数的选择[J],激光技术,1997,2(4):210—214。
[34] 王补宣,工程传热传质学[M],北京:科学出版社,1981。
[35] 吴刚,激光相变硬化温度场模拟及激光参数的优化选择[D]、上海海运学院,1999
[36] 李俊昌,R;谢瓦利埃,J.M.兰热,中国激光1997,A24(7)。
[37] 李俊昌,李行一,陈庆华等,材料研究学报,1998,12(3)。
[38] 吴钢,石娟等,应用激光,1999,19(3)。
[39] 夏国华,杨树容,相代热处理技术、北京:兵器工业出版社,1996,11:18
[40] 杜则裕,刘继元,张世林等工程材料简明手册,北京:电子工业出版社,1996年,112。
[41] 花银群,陈瑞芳,球失曲轴激光淬光工艺的研究新技术、新工艺,2001 33(1) 55—56。
[42] 周建忠等,球铁曲轴激光淬火技术研究,农业机械学校,2001,32(3)109—112。
[43] 张三川,铸铁曲轴激光淬火,金属执处理,2001.3 9-11
[44] 刘怀喜,灰口铸铁磨辊表面激光淬火的组织性能研究,机械工程材料,2000.24(6),27-31
[45] 梁二军等,45#钢宽带激光淬火研究,激光杂志,2001.22(2) 52-54
[46] 刘文今等,45#钢凸轮表面的激光熔凝——合金化复合强化工艺,第六届全国激光热处理学
术年会论文集,1997,2-6
[47] 戴忠森等,齿轮热处理工艺的研究,第六届全国激光热处理学术年会论文集,1997,12-18
[48] Grunenwald B, et al, New technolical development in laser cladding ICALEO, 1993:934
[49] H. vilar, cladding, Journal of lasersapplications, 1999, 11(2)
[50] J. Lin.,W.M. steen, Journal of laser Applications, 1998,10(2):55-63
[51] Depascale O, et al, Optics and lasers in Engineering, 1985(6):157
[52] Idem, Coating characterization in controlled surface temperature laser heat treating IBID, 1988(8):97