基体金属硬度与工艺对复合辊套耐磨性的研究
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摘要
本文对RP中速磨煤机耐磨件进行了运行与磨损情况分析,研究、提出了制备磨辊和盘瓦复合合金成分配比;并对制作的试件进行了固溶、时效等特定的热处理工艺,观察试件金相组织,进行机械强度试验,最后做磨料磨损试验,对磨损失效机理进行了深入的研究分析,对其耐磨性能与低合金钢、高铬铸铁进行了对比。由试验数据得出结论,通过在作为基体铜合金中增加一定比例的Cr等元素,并进行特定热处理工艺,可使复合合金宏观硬度、结合强度进一步提高,试样的耐磨性明显增强。同时对进一步提高复合合金与铸钢母材结合强度的工艺改进做了研究。
The contents of this paper research mostly include abrasion fault analysis of grinding roller and different grain size of tungsten carbide effect on abrasive resistance of the composite alloy. Firstly, analyze under the practically run in the power plant abrasion fault of the grinding roll. Secondly, choose the sample component, as different particle match of tungsten carbide and specifically heat treatment craftworks of solution and aging manufacture test piece, watch metallurgical structure of the test piece and do the tests of hardness and tension, at last do the abrasive wear test on the dynamic load abrasive wear test machine, analyze test datum, From the test data, conclusions are arrived that the hardnees of Composite-alloy can be improved and wear-resistance be better by adding Cr and other elements according to a given ratio. This paper also research the technology to improve the intensity between Composite-alloy and basebody.
Yu Changcheng (Thermal power engineering)
Directed by prof. Bao Zhiyong, Huang Baohai
The contents of this paper research mostly include abrasion fault analysis of grinding roller and different grain size of tungsten carbide effect on abrasive resistance of the composite alloy. Firstly, analyze under the practically run in the power plant abrasion fault of the grinding roll. Secondly, choose the sample component, as different particle match of tungsten carbide and specifically heat treatment craftworks of solution and aging manufacture test piece, watch metallurgical structure of the test piece and do the tests of hardness and tension, at last do the abrasive wear test on the dynamic load abrasive wear test machine, analyze test datum, From the test data, conclusions are arrived that the hardnees of Composite-alloy can be improved and wear-resistance be better by adding Cr and other elements according to a given ratio. This paper also research the technology to improve the intensity between Composite-alloy and basebody.
Yu Changcheng (Thermal power engineering)
Directed by prof. Bao Zhiyong, Huang Baohai
引文
[1]戴为,牛海峰,马洪顺,中速磨煤机,北京:机械工业出版社,1998,24~26,105~108,131,428~430
[2]Rohatgi P K,Asthana R,Das S. Solidification,Structures and
Properties of Cast Metal-Ceramic Particle Composites. International Metals Reviews,1986,(3):115~139
[3]刘耀辉,李庆春,何镇明,金属基铸造颗粒复合材料,复合材料学报,1989,
(1):55~61
[4]杨君友,颗粒复合材料颗粒相/基体相界面结合强度,材料导报,1993,7
(5):73~75
[5]许华忠,实用金属材料手册(下),湖北:湖北科学技术出版社,1705
[6]刘羽辉,金属材料物理性能检验标准工作手册,北京:技术标准出版社,1982,138~139,263~265,271~275,245
[7]张鲁阳,朱起凡,金属热加工,武昌:华中理工大学出版社,1990,177~179
[8]刘淑云,铜及铜合金热处理,北京:机械工业出版社,1990,9~12,25~30
[9]温新林,金属材料及热处理实验指导书,华北电力大学,交流讲义编号:F21000230,1999,27
[10]易又南,杨瑞林,卢达溶,铸渗法制造耐磨复合材料的研究,铸造,1985,
(5):13~18
[11]邵荷生,张清,金属的磨料磨损与耐磨材料,北京:机械工业出版社,1988,97~116,210,398~430
[12]温诗铸,摩擦学原理,北京:清华大学出版社,1990,402~408
[13]R. C. D. Richardson. The Wear of Metals by Relatively Soft Abrasives.
Wear,1968,(11):245~275
[14]R. G. Bayer, W. C. Clinton, C. W. Nelson and R. A. Schumacher.
Engineering Model for Wear. Wear,1962,(5):378~391
[15]J. F. Tavernelli and L. F. Coffin. A Compilation and Interpretation
of Cyclic-Strain Fatigue Tests. Trans. Am. Soc. Metals,1959,(51):438~453
[16]许大庆,铸铁件表面铸渗碳化钨颗粒的耐磨机理,特种铸造及有色金属,
1999,(4):9~11
[17]刑建东,在不同磨料磨损条件下高铬铸铁磨损过程的研究,西安交通大学
学报,1982,(10):115~125
[18]I.Katavie,Untersuchungen Uber Die Beeinflussung Des Gefuges Karbidischer Gusseisen Bei Abrasiver Verschleissbean-Spruchung, Wear,1978,(5):35~53
[19]P.S.Mutton, Some Effects of Microstructure on the Abrasion Resistance of Metals, Wear,1978,(6):385~398
[20]Y.Li, B.Bhushan, Wear and Friction Studies of Contact Recording Interface with Microfabricated Heads, Wear, 1996,(12):60~67
[21]S.L.Rice, F.A.Moslehy, Modeling Friction and Wear Phenomena, Wear, 1997,(5):136~146
[22]西安交通大学耐磨课题组,磨料磨损与耐磨合金(译文集),电力工业出版社,1980,100~104,60~62
[23]J.J.Fisher. The Relationship of Microstructure to Properties In
Ni-Hard 4. AFS Trans.1983,(91):47~54
[24]郝石坚,高铬耐磨铸铁,北京:煤炭工业出版社,1993,288
[25]H.布伦迪克,碾磨辊及其制造方法,德国发明专利,专利号95100524
[26]Qing Ma, R. A. Rosenberg, T. Droubay et al. Comparative
Magnetic-Field Imaging, Electric-Field Imaging, and Scanning Auger Microscopy Study of Metal-Matrix Composites. Journal of Electron Spectroscopy and Related Phenomena,1997,(84):99~107
[27]You Wang, Radovan Kovacevic, Jiajun Liu. Mechanism of Surface Modification of CeO in Laser Remelted Alloy Spray Coatings. Wear,1998,221(1):47~53
[30]B. K. Prasad. Effects of Partially Substituting Copper by Silicon
on the Physical, Mechanical, and Wear Properties of a Zn-37.5% Al-Based Alloy. Materials Characterization, 2000,44(3):301~308
[31]广州市技术监督局,Q/(KQ)FLGS 1-1996,中速磨机复合合金辊套,广州:广州经济技术开发区富莱耐磨产品有限公司,1996,1~2
[32]M. Taniguchi. Ceramic-Metal Joining for Automobiles. Industrial Ceramics, 1999,19(3):203~207
[33]A. H. Elsawy, M. F. Fahmy. Brazing of SiN Ceramic to Copper.
Journal of Materials Processing Technology,1998,(77):266~272
[34]鲍淑慧,一种中速磨的辊套及制造方法,中国发明专利,专利号94103404
[35](英)霍林主编,上海交大摩擦学研究室译,摩擦学原理,北京,机械工业出版社,1981,10,101
[36]B.Л.波诺马年科,以高铬铸铁为基体的组合材料,MйTOM79,11
[37]M.M.赫罗绍夫等,胡绍衣等译,金属的磨损,北京,机械工业出版社,1966
[2]Rohatgi P K,Asthana R,Das S. Solidification,Structures and
Properties of Cast Metal-Ceramic Particle Composites. International Metals Reviews,1986,(3):115~139
[3]刘耀辉,李庆春,何镇明,金属基铸造颗粒复合材料,复合材料学报,1989,
(1):55~61
[4]杨君友,颗粒复合材料颗粒相/基体相界面结合强度,材料导报,1993,7
(5):73~75
[5]许华忠,实用金属材料手册(下),湖北:湖北科学技术出版社,1705
[6]刘羽辉,金属材料物理性能检验标准工作手册,北京:技术标准出版社,1982,138~139,263~265,271~275,245
[7]张鲁阳,朱起凡,金属热加工,武昌:华中理工大学出版社,1990,177~179
[8]刘淑云,铜及铜合金热处理,北京:机械工业出版社,1990,9~12,25~30
[9]温新林,金属材料及热处理实验指导书,华北电力大学,交流讲义编号:F21000230,1999,27
[10]易又南,杨瑞林,卢达溶,铸渗法制造耐磨复合材料的研究,铸造,1985,
(5):13~18
[11]邵荷生,张清,金属的磨料磨损与耐磨材料,北京:机械工业出版社,1988,97~116,210,398~430
[12]温诗铸,摩擦学原理,北京:清华大学出版社,1990,402~408
[13]R. C. D. Richardson. The Wear of Metals by Relatively Soft Abrasives.
Wear,1968,(11):245~275
[14]R. G. Bayer, W. C. Clinton, C. W. Nelson and R. A. Schumacher.
Engineering Model for Wear. Wear,1962,(5):378~391
[15]J. F. Tavernelli and L. F. Coffin. A Compilation and Interpretation
of Cyclic-Strain Fatigue Tests. Trans. Am. Soc. Metals,1959,(51):438~453
[16]许大庆,铸铁件表面铸渗碳化钨颗粒的耐磨机理,特种铸造及有色金属,
1999,(4):9~11
[17]刑建东,在不同磨料磨损条件下高铬铸铁磨损过程的研究,西安交通大学
学报,1982,(10):115~125
[18]I.Katavie,Untersuchungen Uber Die Beeinflussung Des Gefuges Karbidischer Gusseisen Bei Abrasiver Verschleissbean-Spruchung, Wear,1978,(5):35~53
[19]P.S.Mutton, Some Effects of Microstructure on the Abrasion Resistance of Metals, Wear,1978,(6):385~398
[20]Y.Li, B.Bhushan, Wear and Friction Studies of Contact Recording Interface with Microfabricated Heads, Wear, 1996,(12):60~67
[21]S.L.Rice, F.A.Moslehy, Modeling Friction and Wear Phenomena, Wear, 1997,(5):136~146
[22]西安交通大学耐磨课题组,磨料磨损与耐磨合金(译文集),电力工业出版社,1980,100~104,60~62
[23]J.J.Fisher. The Relationship of Microstructure to Properties In
Ni-Hard 4. AFS Trans.1983,(91):47~54
[24]郝石坚,高铬耐磨铸铁,北京:煤炭工业出版社,1993,288
[25]H.布伦迪克,碾磨辊及其制造方法,德国发明专利,专利号95100524
[26]Qing Ma, R. A. Rosenberg, T. Droubay et al. Comparative
Magnetic-Field Imaging, Electric-Field Imaging, and Scanning Auger Microscopy Study of Metal-Matrix Composites. Journal of Electron Spectroscopy and Related Phenomena,1997,(84):99~107
[27]You Wang, Radovan Kovacevic, Jiajun Liu. Mechanism of Surface Modification of CeO in Laser Remelted Alloy Spray Coatings. Wear,1998,221(1):47~53
[30]B. K. Prasad. Effects of Partially Substituting Copper by Silicon
on the Physical, Mechanical, and Wear Properties of a Zn-37.5% Al-Based Alloy. Materials Characterization, 2000,44(3):301~308
[31]广州市技术监督局,Q/(KQ)FLGS 1-1996,中速磨机复合合金辊套,广州:广州经济技术开发区富莱耐磨产品有限公司,1996,1~2
[32]M. Taniguchi. Ceramic-Metal Joining for Automobiles. Industrial Ceramics, 1999,19(3):203~207
[33]A. H. Elsawy, M. F. Fahmy. Brazing of SiN Ceramic to Copper.
Journal of Materials Processing Technology,1998,(77):266~272
[34]鲍淑慧,一种中速磨的辊套及制造方法,中国发明专利,专利号94103404
[35](英)霍林主编,上海交大摩擦学研究室译,摩擦学原理,北京,机械工业出版社,1981,10,101
[36]B.Л.波诺马年科,以高铬铸铁为基体的组合材料,MйTOM79,11
[37]M.M.赫罗绍夫等,胡绍衣等译,金属的磨损,北京,机械工业出版社,1966