研究了铸造热锻模具钢4Cr3Mo2NiV从室温到600℃的磨损行为,采用SEM,XRD和EPMA等对试样磨损表面和磨屑的形貌、成分和结构进行了分析,探讨了铸造热锻模具钢的高温磨损机理.结果表明:铸造热锻模具钢的高温磨损机理是氧化磨损和疲劳剥层磨损.磨损过程中氧化和疲劳剥层交替进行,使摩擦系数大幅度波动.高温磨损形成的氧化物主要是Fe2O3和Fe3O4,氧化磨损使磨损率降低;疲劳剥层使磨损率增加,磨屑呈脆性块状.
参考文献
| [1] | Fang J R, Jiang Q C, Zhao Y G, Zhao Y Q, Wang S Q.Foundry, 2002; 51:7(方健儒,姜启川,赵宇光,赵玉谦,王树奇.铸造,2002;51:7) |
| [2] | He J J, Lan J, Zhai C Q, Ding W J. Foundry, 2000; 49:156(贺俊杰,兰杰,翟春泉,丁文江.铸造,2000;49:156) |
| [3] | Lan J, He J J, Ding W J, Wang Q D, Zhu Y P, Zhai C Q,Xu X P, Lu C. Iron Steel, 2000; 35(10): 49(兰杰,贺俊杰,丁文江,王渠东,朱燕萍,翟春泉,徐小平,卢晨.钢铁,2000;35(10):49) |
| [4] | Cui X H, Wang S Q, Jiang Q C, Fang J R, Zhao Y G,Zhao Y Q, Guan Q F, Zhan S J. Heat Treat Met, 2001;(1): 17(崔向红,王树奇,姜启川,方健儒,赵宇光,赵玉谦,关庆丰,战松江.金属热处理,2001;(1):17) |
| [5] | Czupryk W. Wear, 2000; 237:288 |
| [6] | Panjan P, Urankar I, Navinsek B, Tercelj M, Turk R,Cekada M, Leskovsek V. Surf Coat Technol, 2002; 151-152:505 |
| [7] | Woydt M, Skopp A, Witke K. Wear, 1998; 218:84 |
| [8] | Wang Y, Lei T Q. Wear, 1996; 194:44 |
| [9] | Marui E, Hasegawa N, Endo H, Tanaka K, Hattori TWear, 1997; 205:186 |
| [10] | Cheng X H, Wang C H, Xie C Y. Tribology, 2003; 23:326(程先华,王从鹤,谢超英.摩擦学学报,2003;23:326) |
| [11] | Barrau O, Boher C, Gras R, Rezai-Aria E. Wear, 2003;255:1444 |
| [12] | Li Z, Qu J X, Zhou P A, Zhao Z Y, Shao H S. J Iron Steel Res, 2000; 12(4): 36(李志,曲敬信,周平安,赵振业,邵荷生.钢铁研究学报,2000;12(4):36) |
| [13] | Jie X H, Mao Z Y. J Zhejiang Univ (Nat Sci), 1998; 32:769(揭晓华,毛志远.浙江大学学报(自然科学版),1998;32:769) |
| [14] | Archard J F, Rowntre R A. Wear, 1988; 128: 1 |
上一张
下一张
上一张
下一张
计量
- 下载量()
- 访问量()
文章评分
- 您的评分:
-
10%
-
20%
-
30%
-
40%
-
50%