新型球磨机衬板耐磨钢的研究及生产应用
摘要
通过对球磨机衬板用耐磨材料的应用情况,工况条件、性能要求,合金元素作用的分析,在充分考虑德兴铜矿选矿厂球磨机特殊性的条件下,设计了一种新型耐磨铸钢—CHMe钢,其控制成分为:C:0.7%~0.9%,Si:0.2%~0.4%,Mn:0.3%~0.5%,Cr:2.8%~3.2%,Ni:0.4%~0.6%,W:0.05%~0.1%,Ti:0.03%~0.05%,V:0.005%~0.01%;Mo:0.3%~0.5%,Cu:0.3%~0.5%,P:<0.06%,S:<0.06%.在此基础上,对CHMe钢的淬透性,热处理工艺、耐磨性进行了试验研究,并制定了熔炼、铸造、热处理工艺,进行了生产小试和装机试运行。
试验结果表明,设计的CHMe钢淬透性良好,能满足大型球磨机衬板的淬透性要求。其在900℃~950℃奥氏体化后淬火+500℃~550℃×2小时回火后的综合机械性能最佳,硬度可达HRC44以上,抗拉强度σ_b>1500MPa,无缺口冲击韧性α_k>50J/cm~2。组织分析表明,此时形成的回火马氏体+贝氏体+回火屈氏体+残余奥氏体+弥散碳化物的组织是其具有优良的综合机械性能的原因。此时其耐磨性好,比2GMn13提高15%~35%。磨面分析表明,CHMe钢基体高强度,高硬度、良好的强韧性配合和碳化物硬质点的弥散分布,磨痕细短浅小,挤塑变形区细小均匀,抵抗冲击滑动累积塑性疲劳能力强,是其耐磨性比ZGMn13高的原因。
生产小试与装机运行结果表明,CHMe钢衬板的生产工艺较为05单,熔炼、铸造、热处理工艺易于掌握,使用寿命是ZGMn13衬板的1.3倍。而技术经济分析则表明,CHMe钢衬板的生产成本虽然略高于2GMn13衬板,但综合考虑磨矿效率与磨耗成本后,生产每吨CHMe钢衬板仍可比ZGMn13衬板多获利1230元,具有明显的经济与社会效益。
This paper designed a new kind of anti-wearing cast steel which is also called CHMe steel after reviewed the development of anti-wearing iron and steel and analysed the wear behaviour of the lining boards using in ball mills, the actions of alloy elements and the particular demands of lining boards using in DEXIN copper mine's ball mills. The controlled alloy elements' composition range is list as follows: C: 0.7%-0.9%, Si: 0.2%-0.4%, Mn: 0.3%-0.5%, Cr: 2.8%-3.2%, Ni: 0.4/%-0.6%, W: 0.05%-0.1%, Ti: 0.03%-0.05%, V: 0.005%-0.01%; Mo: 0.3%-0.5%, Cu: 0.3%-0.5%. P: <0.06% S: <0.06%. The cast structure, the quenched structure and mechanical property, the anti-wearing property and the producing process of the CHMe steel has been studied in the paper. The main contents of the experiments includes such items as follows: design of the new wear-resisting cast steel's chemical composition, determination and analysis of the new wear-resisting steel's quench degree and CCT curve, ananysis of the cast structure, study of t
he new wear-resisting steel's heat treatment process.
Some useful conclusions have get from the result of the above experiments. The new wear-resisting steel's quench degree is so good that it can meet the demand of huge ball mills. The mechanical properties and anti-wearing property of CHMe steel are best after the heat treatment of quenching after austenized at 900X-950 and tempering at 500-550 for 2 hours. The hardness, the intensity and the toughness can exceed HRC44, 1500MPa and 50J/cm2 apart. The anti-wearing property of CHMe steel is 15 percent to 35percent higher than ZGMnl3, which is a widely used anti-wearing steel. The reason of the excellent mechanical properties and anti-wearing property of CHMe steel is that the heat treatment sturcture of CHMe steel is composed of tempered martensite, bainite, temper troostite, remaining austenite and carbonide.
Industrial application and the analysis of technological economy showed that CHMe steel lining board's producing process is simple and controllable and the duriablity of CHMe steel lining board is 30 percent higer than ZGMnl3 lining board while the first price of CHMe steel lining board is little higer than ZGMnl3 lining board. It is feasible and economic to produce CHMe steel lining board instead of ZGMnl3 lining board with high ratio of property to price.
试验结果表明,设计的CHMe钢淬透性良好,能满足大型球磨机衬板的淬透性要求。其在900℃~950℃奥氏体化后淬火+500℃~550℃×2小时回火后的综合机械性能最佳,硬度可达HRC44以上,抗拉强度σ_b>1500MPa,无缺口冲击韧性α_k>50J/cm~2。组织分析表明,此时形成的回火马氏体+贝氏体+回火屈氏体+残余奥氏体+弥散碳化物的组织是其具有优良的综合机械性能的原因。此时其耐磨性好,比2GMn13提高15%~35%。磨面分析表明,CHMe钢基体高强度,高硬度、良好的强韧性配合和碳化物硬质点的弥散分布,磨痕细短浅小,挤塑变形区细小均匀,抵抗冲击滑动累积塑性疲劳能力强,是其耐磨性比ZGMn13高的原因。
生产小试与装机运行结果表明,CHMe钢衬板的生产工艺较为05单,熔炼、铸造、热处理工艺易于掌握,使用寿命是ZGMn13衬板的1.3倍。而技术经济分析则表明,CHMe钢衬板的生产成本虽然略高于2GMn13衬板,但综合考虑磨矿效率与磨耗成本后,生产每吨CHMe钢衬板仍可比ZGMn13衬板多获利1230元,具有明显的经济与社会效益。
This paper designed a new kind of anti-wearing cast steel which is also called CHMe steel after reviewed the development of anti-wearing iron and steel and analysed the wear behaviour of the lining boards using in ball mills, the actions of alloy elements and the particular demands of lining boards using in DEXIN copper mine's ball mills. The controlled alloy elements' composition range is list as follows: C: 0.7%-0.9%, Si: 0.2%-0.4%, Mn: 0.3%-0.5%, Cr: 2.8%-3.2%, Ni: 0.4/%-0.6%, W: 0.05%-0.1%, Ti: 0.03%-0.05%, V: 0.005%-0.01%; Mo: 0.3%-0.5%, Cu: 0.3%-0.5%. P: <0.06% S: <0.06%. The cast structure, the quenched structure and mechanical property, the anti-wearing property and the producing process of the CHMe steel has been studied in the paper. The main contents of the experiments includes such items as follows: design of the new wear-resisting cast steel's chemical composition, determination and analysis of the new wear-resisting steel's quench degree and CCT curve, ananysis of the cast structure, study of t
he new wear-resisting steel's heat treatment process.
Some useful conclusions have get from the result of the above experiments. The new wear-resisting steel's quench degree is so good that it can meet the demand of huge ball mills. The mechanical properties and anti-wearing property of CHMe steel are best after the heat treatment of quenching after austenized at 900X-950 and tempering at 500-550 for 2 hours. The hardness, the intensity and the toughness can exceed HRC44, 1500MPa and 50J/cm2 apart. The anti-wearing property of CHMe steel is 15 percent to 35percent higher than ZGMnl3, which is a widely used anti-wearing steel. The reason of the excellent mechanical properties and anti-wearing property of CHMe steel is that the heat treatment sturcture of CHMe steel is composed of tempered martensite, bainite, temper troostite, remaining austenite and carbonide.
Industrial application and the analysis of technological economy showed that CHMe steel lining board's producing process is simple and controllable and the duriablity of CHMe steel lining board is 30 percent higer than ZGMnl3 lining board while the first price of CHMe steel lining board is little higer than ZGMnl3 lining board. It is feasible and economic to produce CHMe steel lining board instead of ZGMnl3 lining board with high ratio of property to price.
引文
[1] 刘家俊.材料磨损原理及其耐磨性.北京:清华大学出版社,1993
[2] 周平安,磨损失效分析及耐磨材料现状和展望.铸造,2000(1):23~25
[3] 张立波,陈迪林.铸造抗磨材料的发展概况与趋势.现代铸铁,1999(3):12~15
[4] 张清主编.金属磨损和金属耐磨材料手册.北京:冶金出版社,1991
[5] 郝石坚著.高铬耐磨铸铁,煤炭工业出版社.
[6] 李茂林.建材工业用磨球的研制与使用.铸造,1998(2):32~35
[7] 周平安等.德兴铜矿球磨机使用状况及统计分析.辽阳:第八届磨损失效分析及耐磨材料年会,1999。
[8] 张裕新等.湿式磨机磨球的腐蚀磨损.铸造,1999(11).
[9] 邓海金.湿式条件下磨球的磨损及其选材,矿山机械,1988(8):19~26
[10] 罗元良等.磨球的应用与选材.矿山机械,1994(4):26~28
[11] 韩福生.低铬白口铸铁磨球的组织与性能研究.铸造,1993(6):16~20
[12] 邢建东等,在不同磨料磨损下高铬铸铁磨损过程的研究.铬系抗磨铸铁论文集,西安交通大学出版社,1986:15~39
[13] 符寒光.高铬铸铁基体组织对冲击磨损的影响。现代铸铁,1994(1):10~15
[14] 周庆德.发展耐磨材料的设想.球铁,1989(1):1~4
[15] Sate I. R. Metals Technology. 1997(11): 412~419
[16] 金远智等.铸物.1985(1);35~44
[17] Peurece J.T.H. The British Foundryman. 1985(1): 13~24
[18] Dawson J.V. The British Foundryman. 1982(8): 134~149
[19] 苏俊义等.含钒铸态马氏体高铬铸铁的研究.铬系抗磨铸铁论文集.西安交通大学出版社,1986:125~129
[20] 陈琚等,合金高铬铸铁及其应用.北京:冶金工业出版社,1999
[21] 王玉玮等,钒在高铬铸铁中的应用,铸造,1989(5):9~12
[22] 张景辉等.变质高铬铸铁组织与性能的研究.铸造,1993(8):7~10
[23] 苏勇等.多元变质高铬铸铁的研究.铸造技术,1996(2):43~48
[24] 朴东学等.改善高铬白口铸铁韧性扩大其应用范围的研究.铸造,1986(10):1~8
[25] 朴东学等.铬白口铸铁及其生产工艺的研究与发展.铸造,1996(10):1~5
[26] 王文才等.铸态高铬铸铁磨球的组织和有效应用的研究.第九届中国铸造学术会议论文集.东北大学出版社,1997:143~149
[27] Braidwood w.w. Foundry Trade Journal,1949(12):649~653.
[28] Johansson M.Transaction of the A.F.S.1977(85):117~122.
[29] 郭新立,苏华钦.奥贝球铁最佳等温淬火时间的确定方法.现代铸铁,1994(1):16~19
[30] Janowak. J. F. Modern Casting, 1981; (12):34~36
[31] 周世权.等温淬火球铁组织与性能间的关系.热加工工艺,1990(1):9~12
[32] TrudeI.A.et.al Effect of composition and heat treatment paramenters on the characteristics ofaustempered ductile irons. Can Metall 1997,36(5):289~298
[33] 朱君贤,邹德扬.含硅量及等温时间对奥贝球铁机械性能的影响.现代铸铁,1988(3)
[34] 赵伯鄱.锰对奥贝球铁组织和性能的影响.球铁,1991(2)
[35] 宋良国,鲍永富.铸态贝氏体球铁中(M-A)组织及其在材料断裂过程中的行为.球铁,1995(3):6~12
[36] 严密,董鄂,苏华钦,奥/贝球铁中贝氏体亚元结构及其对力学性能的影响.铸造,1995(3):11~14
[37] Delia. M. et al Effect of austenitizing conditions on the impact properties of an alloyed austempered ductile iron of initially ferritic matrix Structure. Damage Mech. 1998,7(2): 103~128
[38] 周寤生.孟寿康.周庆德.等温淬火球墨铸铁滑动摩擦磨损性能的研究.现代铸铁.1992.2.
[39] Bela V. Kovacs, Sr. Austempered Ductile Iron Fact and Fiction. Morden Casting, March 1990
[40] Ahmadabadi.M. Banitic transformation in austempered ductile iron with reference to untransformed austenite volume phenomenon. Metal Mat Trans 1997 28A(10):2159~2162
[41] 王子龙等.铸态贝氏体抗磨铸铁的研究.现代铸铁,1992(2):16~21
[42] Kovacs B.V. AFS Transactions, 1994(83):417~420
[43] Y.J.Park, M.Gagne. Continuous Cooling Transformation and Auate- mpering Behavior of Cu-Mo Ductile Iron. AFS Tranactions, 1984
[44] J.F.Janowak,R.B.Gundlack.傅江译.在铸造过程中控制铸件冷却获得等温淬火球铁相近的性能.现代铸铁,1987(3)
[45] 顾涣玉等.模拟等温处理Cu-Ni-Mo球铁应用于球磨机衬板的可行性研究.现代铸铁,1995(2):42~46
[46] 顾涣玉等.贝氏体球墨铸铁球磨机衬板的可行性研究.铸造,1994(7):11~14
[47] 陈希杰.高锰钢.北京:机械工业出版社,1989(2)
[48] 李茂林.破碎粉磨设备的磨损与耐磨材料的发展.第九届中国铸造学术会议论文集.东北大学出版社,1997:143~149
[49] 吕振林等.破碎机械上易碎磨损件的材质选择.机械工程材料,1997(10):44~48
[50] H.A. Fabert. Jr. Manganese steels in crushing and grinding service, Symposium: Materials for the mining Industry. Vail, Colorado,1974,7(30,31):163~166
[51] 吕宇鹏等.超高锰合金钢的组织与性能研究.矿山机械,1998(6):69~71
[52] 程必国等.超高锰合金钢的试验研究及应用.第八届全国耐磨材料学术会议论文集,1997:51~56
[53] 方英照.ZGMn18钢铸件的研制.金属热处理,1998(9):36~37
[54] 朴东学等.改进材质提高高锰钢铸件的使用性能.铸造,1998(6):43~45
[55] 赵四勇等.关于高锰钢的若干问题.铸造技术,1999(4):34~36
[56] 杨东方等.奥氏体/贝氏体钢的显微组织和力学性能.中国矿业大学学报,1993(9):7~12
[57] 荣守范等.热处理工艺参数对高碳低合金贝氏体抗磨钢组织与性能的影响.热加工工艺,1998(3):34~36
[58] 方鸿生等.中碳贝氏体/马氏体复相组织强韧性的研究.金属热处理学报,1986(6):1018
[59] Sawley. Kevin. Development of baintic steels for rails. Proceedings of the 1997 39th Mechanical Working and Steel Processing Con- ference, Indianapolis. In USA,1997:1007~1014
[60] Kern.A. Development of baintic Steels for special rail-way system requirements. Proceedings of the 1997 39th Mechanical Working and Steel Processing Conference, Indianapolis. In USA, 1997:1015~1021
[61] E.B.Pickering, "Physical Metallurgy and the Design of Steels", Applied Science Publishers LID,London, 1980
[62] 俞德刚.钢的强韧化理论与设计.上海交通大学出版社,1990
[63] 方鸿生等.发展新型贝氏体钢.兵器材料科学与工程,1988(1):1~12.
[64] 康沫狂等.钢中贝氏体.上海:上海科学技术出版社,1990
[65] 康沫狂.现代材料科学进展.北京:国防工业出版社,1992
[66] 司鹏程等.下贝氏体/马氏体耐磨钢的研制.金属热处理,1994(8):9~13
[67] 李凤照等.多元微合金化空冷贝氏体钢.金属学报,1997(5):492~498.
[68] 方鸿生等.贝氏体组织与贝氏体钢.金属热处理,1999,11
[69] 方鸿生等.我国贝氏体钢的前景.金属热处理,1998,7
[70] 魏成富,栾道成.铸态奥氏体/贝氏体耐磨钢的研究.热加工工艺,1995(3):42~44
[71] 丁霖溥等.铸态低合金Mo-Nb贝氏体钢的研制.机械工程材料,1993(12):6~9。
[72] 张裕新等,德兴铜矿大型球磨机磨球使用状况和统计分析。水利电力机械,1999,5。
[73] 赵学胜,球磨机衬板新材料的研究。中国矿业,2000,第9卷,总第49期。
[74] 刘方云,特大型球磨机衬板材料的研究。矿业研究与开发,2000,Vol.20,No.4。
[75] 周平安,磨损失效分析及耐磨材料的现状和展望。铸造,2000,Vol.49,No.1。
[76] 余柏海,钢的计算机设计及冶炼成分微调。特殊钢,1998,第18卷第5期。
[77] 要玉海,孙伟成。高碳低合金耐磨钢的试验研究。铸造技术,1998,1。
[781 吕奎龙,高碳低合金抗磨钢的研制与应用。佳木斯工学院学报。1997,Vol.15,No.2。
[79] 秦紫瑞等,新型高铬铸铁的组织及磨蚀行为研究。上海金属,1999,6。
[80] 斯松华等。碳铬系合金耐磨钢试验研究。华东冶金学院学报,2000,4。
[81] 胡海明,E型磨煤机磨球材质的研制。水利电力机械。1994,4。
[82] 于秀云,孙荣玖,王洪发。高碳Mo-B系贝氏体耐磨钢的工业生产与应用。金属矿山,2000,8。
[83] 谢祖华,多元微合金高耐磨颚板的研制。福建农机,1998年增刊。
[84] 荣守范等。淬火工艺及含碳、硅量对B钢机械性能的影响。哈尔滨理工大学学报,2000,6。
[85] 崔忠圻,金属学及热处理。机械工业出版社,1988。
[2] 周平安,磨损失效分析及耐磨材料现状和展望.铸造,2000(1):23~25
[3] 张立波,陈迪林.铸造抗磨材料的发展概况与趋势.现代铸铁,1999(3):12~15
[4] 张清主编.金属磨损和金属耐磨材料手册.北京:冶金出版社,1991
[5] 郝石坚著.高铬耐磨铸铁,煤炭工业出版社.
[6] 李茂林.建材工业用磨球的研制与使用.铸造,1998(2):32~35
[7] 周平安等.德兴铜矿球磨机使用状况及统计分析.辽阳:第八届磨损失效分析及耐磨材料年会,1999。
[8] 张裕新等.湿式磨机磨球的腐蚀磨损.铸造,1999(11).
[9] 邓海金.湿式条件下磨球的磨损及其选材,矿山机械,1988(8):19~26
[10] 罗元良等.磨球的应用与选材.矿山机械,1994(4):26~28
[11] 韩福生.低铬白口铸铁磨球的组织与性能研究.铸造,1993(6):16~20
[12] 邢建东等,在不同磨料磨损下高铬铸铁磨损过程的研究.铬系抗磨铸铁论文集,西安交通大学出版社,1986:15~39
[13] 符寒光.高铬铸铁基体组织对冲击磨损的影响。现代铸铁,1994(1):10~15
[14] 周庆德.发展耐磨材料的设想.球铁,1989(1):1~4
[15] Sate I. R. Metals Technology. 1997(11): 412~419
[16] 金远智等.铸物.1985(1);35~44
[17] Peurece J.T.H. The British Foundryman. 1985(1): 13~24
[18] Dawson J.V. The British Foundryman. 1982(8): 134~149
[19] 苏俊义等.含钒铸态马氏体高铬铸铁的研究.铬系抗磨铸铁论文集.西安交通大学出版社,1986:125~129
[20] 陈琚等,合金高铬铸铁及其应用.北京:冶金工业出版社,1999
[21] 王玉玮等,钒在高铬铸铁中的应用,铸造,1989(5):9~12
[22] 张景辉等.变质高铬铸铁组织与性能的研究.铸造,1993(8):7~10
[23] 苏勇等.多元变质高铬铸铁的研究.铸造技术,1996(2):43~48
[24] 朴东学等.改善高铬白口铸铁韧性扩大其应用范围的研究.铸造,1986(10):1~8
[25] 朴东学等.铬白口铸铁及其生产工艺的研究与发展.铸造,1996(10):1~5
[26] 王文才等.铸态高铬铸铁磨球的组织和有效应用的研究.第九届中国铸造学术会议论文集.东北大学出版社,1997:143~149
[27] Braidwood w.w. Foundry Trade Journal,1949(12):649~653.
[28] Johansson M.Transaction of the A.F.S.1977(85):117~122.
[29] 郭新立,苏华钦.奥贝球铁最佳等温淬火时间的确定方法.现代铸铁,1994(1):16~19
[30] Janowak. J. F. Modern Casting, 1981; (12):34~36
[31] 周世权.等温淬火球铁组织与性能间的关系.热加工工艺,1990(1):9~12
[32] TrudeI.A.et.al Effect of composition and heat treatment paramenters on the characteristics ofaustempered ductile irons. Can Metall 1997,36(5):289~298
[33] 朱君贤,邹德扬.含硅量及等温时间对奥贝球铁机械性能的影响.现代铸铁,1988(3)
[34] 赵伯鄱.锰对奥贝球铁组织和性能的影响.球铁,1991(2)
[35] 宋良国,鲍永富.铸态贝氏体球铁中(M-A)组织及其在材料断裂过程中的行为.球铁,1995(3):6~12
[36] 严密,董鄂,苏华钦,奥/贝球铁中贝氏体亚元结构及其对力学性能的影响.铸造,1995(3):11~14
[37] Delia. M. et al Effect of austenitizing conditions on the impact properties of an alloyed austempered ductile iron of initially ferritic matrix Structure. Damage Mech. 1998,7(2): 103~128
[38] 周寤生.孟寿康.周庆德.等温淬火球墨铸铁滑动摩擦磨损性能的研究.现代铸铁.1992.2.
[39] Bela V. Kovacs, Sr. Austempered Ductile Iron Fact and Fiction. Morden Casting, March 1990
[40] Ahmadabadi.M. Banitic transformation in austempered ductile iron with reference to untransformed austenite volume phenomenon. Metal Mat Trans 1997 28A(10):2159~2162
[41] 王子龙等.铸态贝氏体抗磨铸铁的研究.现代铸铁,1992(2):16~21
[42] Kovacs B.V. AFS Transactions, 1994(83):417~420
[43] Y.J.Park, M.Gagne. Continuous Cooling Transformation and Auate- mpering Behavior of Cu-Mo Ductile Iron. AFS Tranactions, 1984
[44] J.F.Janowak,R.B.Gundlack.傅江译.在铸造过程中控制铸件冷却获得等温淬火球铁相近的性能.现代铸铁,1987(3)
[45] 顾涣玉等.模拟等温处理Cu-Ni-Mo球铁应用于球磨机衬板的可行性研究.现代铸铁,1995(2):42~46
[46] 顾涣玉等.贝氏体球墨铸铁球磨机衬板的可行性研究.铸造,1994(7):11~14
[47] 陈希杰.高锰钢.北京:机械工业出版社,1989(2)
[48] 李茂林.破碎粉磨设备的磨损与耐磨材料的发展.第九届中国铸造学术会议论文集.东北大学出版社,1997:143~149
[49] 吕振林等.破碎机械上易碎磨损件的材质选择.机械工程材料,1997(10):44~48
[50] H.A. Fabert. Jr. Manganese steels in crushing and grinding service, Symposium: Materials for the mining Industry. Vail, Colorado,1974,7(30,31):163~166
[51] 吕宇鹏等.超高锰合金钢的组织与性能研究.矿山机械,1998(6):69~71
[52] 程必国等.超高锰合金钢的试验研究及应用.第八届全国耐磨材料学术会议论文集,1997:51~56
[53] 方英照.ZGMn18钢铸件的研制.金属热处理,1998(9):36~37
[54] 朴东学等.改进材质提高高锰钢铸件的使用性能.铸造,1998(6):43~45
[55] 赵四勇等.关于高锰钢的若干问题.铸造技术,1999(4):34~36
[56] 杨东方等.奥氏体/贝氏体钢的显微组织和力学性能.中国矿业大学学报,1993(9):7~12
[57] 荣守范等.热处理工艺参数对高碳低合金贝氏体抗磨钢组织与性能的影响.热加工工艺,1998(3):34~36
[58] 方鸿生等.中碳贝氏体/马氏体复相组织强韧性的研究.金属热处理学报,1986(6):1018
[59] Sawley. Kevin. Development of baintic steels for rails. Proceedings of the 1997 39th Mechanical Working and Steel Processing Con- ference, Indianapolis. In USA,1997:1007~1014
[60] Kern.A. Development of baintic Steels for special rail-way system requirements. Proceedings of the 1997 39th Mechanical Working and Steel Processing Conference, Indianapolis. In USA, 1997:1015~1021
[61] E.B.Pickering, "Physical Metallurgy and the Design of Steels", Applied Science Publishers LID,London, 1980
[62] 俞德刚.钢的强韧化理论与设计.上海交通大学出版社,1990
[63] 方鸿生等.发展新型贝氏体钢.兵器材料科学与工程,1988(1):1~12.
[64] 康沫狂等.钢中贝氏体.上海:上海科学技术出版社,1990
[65] 康沫狂.现代材料科学进展.北京:国防工业出版社,1992
[66] 司鹏程等.下贝氏体/马氏体耐磨钢的研制.金属热处理,1994(8):9~13
[67] 李凤照等.多元微合金化空冷贝氏体钢.金属学报,1997(5):492~498.
[68] 方鸿生等.贝氏体组织与贝氏体钢.金属热处理,1999,11
[69] 方鸿生等.我国贝氏体钢的前景.金属热处理,1998,7
[70] 魏成富,栾道成.铸态奥氏体/贝氏体耐磨钢的研究.热加工工艺,1995(3):42~44
[71] 丁霖溥等.铸态低合金Mo-Nb贝氏体钢的研制.机械工程材料,1993(12):6~9。
[72] 张裕新等,德兴铜矿大型球磨机磨球使用状况和统计分析。水利电力机械,1999,5。
[73] 赵学胜,球磨机衬板新材料的研究。中国矿业,2000,第9卷,总第49期。
[74] 刘方云,特大型球磨机衬板材料的研究。矿业研究与开发,2000,Vol.20,No.4。
[75] 周平安,磨损失效分析及耐磨材料的现状和展望。铸造,2000,Vol.49,No.1。
[76] 余柏海,钢的计算机设计及冶炼成分微调。特殊钢,1998,第18卷第5期。
[77] 要玉海,孙伟成。高碳低合金耐磨钢的试验研究。铸造技术,1998,1。
[781 吕奎龙,高碳低合金抗磨钢的研制与应用。佳木斯工学院学报。1997,Vol.15,No.2。
[79] 秦紫瑞等,新型高铬铸铁的组织及磨蚀行为研究。上海金属,1999,6。
[80] 斯松华等。碳铬系合金耐磨钢试验研究。华东冶金学院学报,2000,4。
[81] 胡海明,E型磨煤机磨球材质的研制。水利电力机械。1994,4。
[82] 于秀云,孙荣玖,王洪发。高碳Mo-B系贝氏体耐磨钢的工业生产与应用。金属矿山,2000,8。
[83] 谢祖华,多元微合金高耐磨颚板的研制。福建农机,1998年增刊。
[84] 荣守范等。淬火工艺及含碳、硅量对B钢机械性能的影响。哈尔滨理工大学学报,2000,6。
[85] 崔忠圻,金属学及热处理。机械工业出版社,1988。