低铬白口铸铁腐蚀磨损特性研究
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摘要
低铬白口铸铁由于具有良好的耐磨性和较低的价格而在实际生产中得到广泛应用。随着环保要求的提高,有色金属矿山采用回用水进行生产,其中主要包括一定量的Cu~(2+)、Fe~(2+)/Fe_(3+)、SO_4~(2-)等,回用水中存在的这些离子增加了低铬白口铸铁磨球的磨耗量。
本试验采用三体腐蚀磨损试验方法研究了含有不同浓度离子的介质中低铬白口铸铁的腐蚀磨损特性。结果表明:随料浆中Cu~(2+)浓度的增加,低铬白口铸铁的抗腐蚀磨损能力降低。其原因是Cu~(2+)与低铬铸铁中的铁单质发生氧化还原反应,产生化学腐蚀而造成材料质量的减少。而磨损的增加又促进化学腐蚀速度加快;同时,低铬铸铁中的铁被置换为铜,铜附着于试样表面,从而使磨料磨损对试样质量的去除更加容易。当料浆中含有一定量Fe~(2+)\Fe~(3+)时,作用与Cu~(2+)类似,也会与低铬铸铁发生氧化还原反应,造成试样质量流失。同时,磨损又促进浆料中Fe~(2+)\Fe~(3+)浓度的增高,加快化学腐蚀。随料浆中SO_4~(2-)浓度的增加,低铬铸铁腐蚀磨损性能下降,但下降幅度小于同摩尔浓度的Cu~(2+)、Fe~(2+)\Fe~(3+)料浆。其原因是,中性硫酸盐作为电解质存在于料浆中,促进了试样的电化学腐蚀,进而降低了其腐蚀磨损性能。
为了提高低铬白口铸铁试样的使用性能,在其制作过程中加入合金元素镍、铜,并增加含硅量,尽管合金元素镍、铜的加入及增加硅量,可以提高金属防腐蚀能力,但在本试验条件下,低铬铸铁磨损主要以磨料磨损为主,腐蚀相对较弱,而合金元素的加入降低了其硬度,因此对低铬铸铁在不同离子浆料中的腐蚀磨损耐磨性改善不明显。
The low chromium white cast iron has been widely used in the field production as a result of better wear resistance and lower price. With the environmental protection request enhancement, the non-ferrous metal mine uses the water used to carry on the production, in which mainly includes Cu~(2+), Fe~(2+)/Fe~(3+), SO_4~(2-) and so on. In the field production, these ions existences increase the wear of low chromium white cast iron grinding balls.
The corrosion wear behaviors of low chromium white cast iron were studied by using three-body corrosion wear tester in slurries contained with different ions concentration in this paper. The results showed that the corrosion wear resistance of low chromium cast iron would be decreased with the increase of Cu~(2+) concentration in slurries. Because Cu~(2+) ion will react with the iron in low chromium white cast iron by oxidation-deoxidation reaction, the quality-loss of low chromium white cast iron would be increased. The speed of chemistry corrosion of low chromium white cast iron would be accelerated with the increase of its wear; At the same time, iron in the surface of low chromium cast iron was changed into copper and deposited in the wear surface. This would lead to the quality of samples removes easily. When the slurries contained some Fe~(2+)\Fe~(2+) ions, the Fe~(2+)\Fe~(3+) ions acted the same action as Cu~(2+) ion in the slurries. The Fe~(2+)\Fe~(3+) ions would react with iron in low chromium cast iron by oxidation-deoxidation reaction, and made the quality-loss of low chromium cast iron increase. The concentration of Fe~(2+)\Fe~(3+) in slurries would be increased with the increase of wear of low chromium cast iron, and led the speed of chemistry corrosion increase. With the increase of SO_4~(2-) ion concentration in slurries, the corrosion-wear resistance of low chromium cast iron would be also decreased, but the decrease degree of corrosion-wear resistance would be smaller than in Cu~(2+), Fe~(2+)\Fe~(3+) in slurries. This is because that neutral sulfate existed as electrolyte in the slurries, which could accelerate the electrochemistry corrosion of low chromium cast iron. Therefore the SO_4~(2-) ion would decrease
本试验采用三体腐蚀磨损试验方法研究了含有不同浓度离子的介质中低铬白口铸铁的腐蚀磨损特性。结果表明:随料浆中Cu~(2+)浓度的增加,低铬白口铸铁的抗腐蚀磨损能力降低。其原因是Cu~(2+)与低铬铸铁中的铁单质发生氧化还原反应,产生化学腐蚀而造成材料质量的减少。而磨损的增加又促进化学腐蚀速度加快;同时,低铬铸铁中的铁被置换为铜,铜附着于试样表面,从而使磨料磨损对试样质量的去除更加容易。当料浆中含有一定量Fe~(2+)\Fe~(3+)时,作用与Cu~(2+)类似,也会与低铬铸铁发生氧化还原反应,造成试样质量流失。同时,磨损又促进浆料中Fe~(2+)\Fe~(3+)浓度的增高,加快化学腐蚀。随料浆中SO_4~(2-)浓度的增加,低铬铸铁腐蚀磨损性能下降,但下降幅度小于同摩尔浓度的Cu~(2+)、Fe~(2+)\Fe~(3+)料浆。其原因是,中性硫酸盐作为电解质存在于料浆中,促进了试样的电化学腐蚀,进而降低了其腐蚀磨损性能。
为了提高低铬白口铸铁试样的使用性能,在其制作过程中加入合金元素镍、铜,并增加含硅量,尽管合金元素镍、铜的加入及增加硅量,可以提高金属防腐蚀能力,但在本试验条件下,低铬铸铁磨损主要以磨料磨损为主,腐蚀相对较弱,而合金元素的加入降低了其硬度,因此对低铬铸铁在不同离子浆料中的腐蚀磨损耐磨性改善不明显。
The low chromium white cast iron has been widely used in the field production as a result of better wear resistance and lower price. With the environmental protection request enhancement, the non-ferrous metal mine uses the water used to carry on the production, in which mainly includes Cu~(2+), Fe~(2+)/Fe~(3+), SO_4~(2-) and so on. In the field production, these ions existences increase the wear of low chromium white cast iron grinding balls.
The corrosion wear behaviors of low chromium white cast iron were studied by using three-body corrosion wear tester in slurries contained with different ions concentration in this paper. The results showed that the corrosion wear resistance of low chromium cast iron would be decreased with the increase of Cu~(2+) concentration in slurries. Because Cu~(2+) ion will react with the iron in low chromium white cast iron by oxidation-deoxidation reaction, the quality-loss of low chromium white cast iron would be increased. The speed of chemistry corrosion of low chromium white cast iron would be accelerated with the increase of its wear; At the same time, iron in the surface of low chromium cast iron was changed into copper and deposited in the wear surface. This would lead to the quality of samples removes easily. When the slurries contained some Fe~(2+)\Fe~(2+) ions, the Fe~(2+)\Fe~(3+) ions acted the same action as Cu~(2+) ion in the slurries. The Fe~(2+)\Fe~(3+) ions would react with iron in low chromium cast iron by oxidation-deoxidation reaction, and made the quality-loss of low chromium cast iron increase. The concentration of Fe~(2+)\Fe~(3+) in slurries would be increased with the increase of wear of low chromium cast iron, and led the speed of chemistry corrosion increase. With the increase of SO_4~(2-) ion concentration in slurries, the corrosion-wear resistance of low chromium cast iron would be also decreased, but the decrease degree of corrosion-wear resistance would be smaller than in Cu~(2+), Fe~(2+)\Fe~(3+) in slurries. This is because that neutral sulfate existed as electrolyte in the slurries, which could accelerate the electrochemistry corrosion of low chromium cast iron. Therefore the SO_4~(2-) ion would decrease
引文
[1] 姜晓霞,李诗卓,李曙等.金属的腐蚀磨损[M].北京:化学工业出版社,2003
[2] Riemer. S. C and Orlich. J. NCorrosive and abrasive weevil art grinding[M]. Wear: 1985, 103
[3] 材料耐磨抗蚀及其表面技术丛书编委会.材料的磨料磨损[M].北京:机械工业出版社,1990
[4] 饶启昌,吕振林,周平安.腐蚀磨损及耐磨蚀材料的选择.铸造[J],2000,49:584~591.
[5] 张裕新,吕振林等.湿式磨机磨球的腐蚀磨损.水利电力机械[J],1999,(10):6~10.
[6] 史美堂.金属材料及热处理[M].上海:上海科学技术出版社,1991
[7] R.J.D Richardson. The Wear of Metals by Hard Abrasive[M]. Wear: 1967, 10: 291~309.
[8] 欧阳习科.我国金属矿山球磨机磨球的应用现状及选材.铸造设备研究[J],2004,4:40~44
[9] 于春田,肖军等.中铬抗磨铸铁磨球的研制.铸造[J],1998,(2):17~20
[10] 李茂林.建材工业用磨球的研制与使用.铸造[J],1998,(2):32~35
[11] 邓文英,郭小鹏.金属工艺学[M].高等教育出版,1981
[12] 朱先勇,杜军.Cu、Cr、Mo、Ni多元低合金化对铸铁组织和性能的影响.汽车工艺与材料[J],2003(1):18~20
[13] 饶启昌,蔡安辉.魏承辉.施居俯.Cr、Si、Mn、Cu对中低白口铸铁抗磨蚀性能的影响.常德师范学院学报[J],2003(1):49~53
[14] 黄明富,邓世萍,吕振林.湿式磨机中低铬铸铁磨球的磨损形貌分析.水利电力机械[J],2003,25(4):41~44.
[15] 黄保旦.低铬合金磨球的生产与应用.柳钢科技[J],2000,(3):27~281
[16] 饶启昌,高义民,刘福玲.高铬铸铁三体腐蚀磨损过程中腐蚀与磨损的交互作用.机械工程学报[J],1991,27:1~5.。
[17] 江燕云,黄明富,吕振林.低铬白口铸铁腐蚀磨损特性研究.热加工工艺[J],2003,4:17
[18] D. J. Duun. Wear of study[M]. Now York, 1985: 501~508
[19] J. Heidemeyer. Influence of the plastic deformation of metals during mixed friction on their chemical reaction rate. Wear[J], 1981, 66:379~381
[20] 张裕新,吕振林,饶启昌,周平安.湿式磨机磨球的腐蚀磨损.水利电力机械[J],1999,(5):6~10
[21] Stott F H, Breakell J E. The influence of corrosion on the wear of cast iron in sulfuric acid solutions. Wear[J], 1989, 135(1): 119~134
[22] LujA W, Hoey G R. Corrosive and erosive wear of metals in mineral slurries. Can Metall Q, 1973, 12 (2): 185~190
[23] Weiser P F, Beck F H, Fontana M G. Resistance to erosion-corrosion of commercially cast steels. Mater Perform[J], 1973, 12 (7): 34~38
[24] Stott F H, Breakell J E, Newman R C. The corrosive wear of cast iron under potention statically-controlled conditions insulphuricacid solutions. CorroSci[J], 1990, 30(809): 813~830
[25] Madsen BW. Measurement of erosion-corrosion synergism with aslurry wear test apparatus. Wear[J], 1988, 123(2): 127~142
[26] 吴荫顺,顾正秋.腐蚀磨损协同作用率的研究.摩擦学学报,1998,16:157~161
[27] 黄明富,邓世萍,吕振林,饶启昌.湿式磨机中低铬铸铁磨球的磨损形貌分析.水利电力机械[J],2003,(2):41~44
[28] 周永欣,吕振林.合金元素对马氏体球墨铸铁腐蚀磨损的影响.铸造技术[J],2001,4:51~53
[29] 蔡安辉.Cr、Si、Mn、Cu对中低铬白口铸铁抗磨蚀性能的影响.铸造技术[J],2003,5:108~109
[30] 杨院生.两种金属材料腐蚀磨损的交互作用.摩擦学学报[J],1996,1:47~54
[31] 黄彦良.腐蚀磨损中几种测量纯机械磨损分量方法的比较.腐蚀科学与防护技术[J],1996,1:49~54
[32] 赵麦群,雷阿丽.金属的腐蚀与防护[M].北京:国防工业出版社,2002
[33] 孙秋霞.材料腐蚀与防护[M].北京:冶金工业出版社,2001
[34] 王海舟主编.铁合金分析:上册[M].北京:科学出版社,2003:214~216
[35] 马冲先.化学分析[M].上海:上海科学普及出版社,2003:128~129
[36] 梁英教.物理化学[M].冶金工业,1983
[37] 吕振林,邓月声,饶启昌.马氏体球球磨铸铁腐蚀磨损特性研究.机械工程材料[J],2001,2(5):32~35
[38] 袁森.金属材料及凝固[M].西安理工大学校内教材,1999
[2] Riemer. S. C and Orlich. J. NCorrosive and abrasive weevil art grinding[M]. Wear: 1985, 103
[3] 材料耐磨抗蚀及其表面技术丛书编委会.材料的磨料磨损[M].北京:机械工业出版社,1990
[4] 饶启昌,吕振林,周平安.腐蚀磨损及耐磨蚀材料的选择.铸造[J],2000,49:584~591.
[5] 张裕新,吕振林等.湿式磨机磨球的腐蚀磨损.水利电力机械[J],1999,(10):6~10.
[6] 史美堂.金属材料及热处理[M].上海:上海科学技术出版社,1991
[7] R.J.D Richardson. The Wear of Metals by Hard Abrasive[M]. Wear: 1967, 10: 291~309.
[8] 欧阳习科.我国金属矿山球磨机磨球的应用现状及选材.铸造设备研究[J],2004,4:40~44
[9] 于春田,肖军等.中铬抗磨铸铁磨球的研制.铸造[J],1998,(2):17~20
[10] 李茂林.建材工业用磨球的研制与使用.铸造[J],1998,(2):32~35
[11] 邓文英,郭小鹏.金属工艺学[M].高等教育出版,1981
[12] 朱先勇,杜军.Cu、Cr、Mo、Ni多元低合金化对铸铁组织和性能的影响.汽车工艺与材料[J],2003(1):18~20
[13] 饶启昌,蔡安辉.魏承辉.施居俯.Cr、Si、Mn、Cu对中低白口铸铁抗磨蚀性能的影响.常德师范学院学报[J],2003(1):49~53
[14] 黄明富,邓世萍,吕振林.湿式磨机中低铬铸铁磨球的磨损形貌分析.水利电力机械[J],2003,25(4):41~44.
[15] 黄保旦.低铬合金磨球的生产与应用.柳钢科技[J],2000,(3):27~281
[16] 饶启昌,高义民,刘福玲.高铬铸铁三体腐蚀磨损过程中腐蚀与磨损的交互作用.机械工程学报[J],1991,27:1~5.。
[17] 江燕云,黄明富,吕振林.低铬白口铸铁腐蚀磨损特性研究.热加工工艺[J],2003,4:17
[18] D. J. Duun. Wear of study[M]. Now York, 1985: 501~508
[19] J. Heidemeyer. Influence of the plastic deformation of metals during mixed friction on their chemical reaction rate. Wear[J], 1981, 66:379~381
[20] 张裕新,吕振林,饶启昌,周平安.湿式磨机磨球的腐蚀磨损.水利电力机械[J],1999,(5):6~10
[21] Stott F H, Breakell J E. The influence of corrosion on the wear of cast iron in sulfuric acid solutions. Wear[J], 1989, 135(1): 119~134
[22] LujA W, Hoey G R. Corrosive and erosive wear of metals in mineral slurries. Can Metall Q, 1973, 12 (2): 185~190
[23] Weiser P F, Beck F H, Fontana M G. Resistance to erosion-corrosion of commercially cast steels. Mater Perform[J], 1973, 12 (7): 34~38
[24] Stott F H, Breakell J E, Newman R C. The corrosive wear of cast iron under potention statically-controlled conditions insulphuricacid solutions. CorroSci[J], 1990, 30(809): 813~830
[25] Madsen BW. Measurement of erosion-corrosion synergism with aslurry wear test apparatus. Wear[J], 1988, 123(2): 127~142
[26] 吴荫顺,顾正秋.腐蚀磨损协同作用率的研究.摩擦学学报,1998,16:157~161
[27] 黄明富,邓世萍,吕振林,饶启昌.湿式磨机中低铬铸铁磨球的磨损形貌分析.水利电力机械[J],2003,(2):41~44
[28] 周永欣,吕振林.合金元素对马氏体球墨铸铁腐蚀磨损的影响.铸造技术[J],2001,4:51~53
[29] 蔡安辉.Cr、Si、Mn、Cu对中低铬白口铸铁抗磨蚀性能的影响.铸造技术[J],2003,5:108~109
[30] 杨院生.两种金属材料腐蚀磨损的交互作用.摩擦学学报[J],1996,1:47~54
[31] 黄彦良.腐蚀磨损中几种测量纯机械磨损分量方法的比较.腐蚀科学与防护技术[J],1996,1:49~54
[32] 赵麦群,雷阿丽.金属的腐蚀与防护[M].北京:国防工业出版社,2002
[33] 孙秋霞.材料腐蚀与防护[M].北京:冶金工业出版社,2001
[34] 王海舟主编.铁合金分析:上册[M].北京:科学出版社,2003:214~216
[35] 马冲先.化学分析[M].上海:上海科学普及出版社,2003:128~129
[36] 梁英教.物理化学[M].冶金工业,1983
[37] 吕振林,邓月声,饶启昌.马氏体球球磨铸铁腐蚀磨损特性研究.机械工程材料[J],2001,2(5):32~35
[38] 袁森.金属材料及凝固[M].西安理工大学校内教材,1999