利用OM,SEM和XRD对单轴非对称应力循环下304不锈钢棘轮变形过程中的微观组织变化进行了实验观察.结果表明:304不锈钢棘轮变形过程中,当棘轮应变达到一定值后会产生应变诱发马氏体相变,形成板条状马氏体,并且随循环周次的增加,形成的应变诱发马氏体相对量逐渐增加.因马氏体相变而诱发的塑性变形对总的棘轮变形量产生一定的影响,材料的棘轮应变应由两部分组成,即应力引起的塑性应变和相变诱发的塑性应变.
Ratcheting behavior of the materials has been extensively investigated and simulated in the last two decades.since it is important in the design and assessment of engineering structure components subjected to asymmetrical stress-controlled cyclic loading.However.most of the referable fiterature concerned only the macroscopic phenomenon of ratcheting and its phenomenological models. Therefore.the microstructure evolution of SS304 stainless steel during uniaxial stress--controlled cyclic loading with the ratcheting deformation was observed by using OM.SEM and XRD methods.Several specimens with the same applied sttess level were first tested under the stress-controlled cyclic loading with diirerent numbers of cycles macroscopically,and then the thin-filmed samples obtained from the specimens subjected to difierent numbers of cycles were microscopically observed.The results show that when the ratcheting strain reaches a certain value high enough,the strain-induced martensite transformation Occurs in the process of ratcheting deformation.The resultant phase is the lath α-martensite and the amount of the induced martensite increases gradually with the number of cycles,which is proved by the quantitative analysis of XRD.It is also concluded that the plastic deformation caused by the martensite transformation has a un-negligible contribution to the total value of ratcheting strain.The total ratcheting deformation should be considered as a superimposition of two parts. I,e the one caused by apphed cyclic stress and the other caused by the strain-induced martensite transformation.
参考文献
[1] | Ohlao N.Mater Sci Res Int,1997;3:1 |
[2] | Kang G Z,Knn Q H,Zhang J,Sun Y F.Int J Plast,2006;22:858 |
[3] | Kang G Z,Kan Q H.Mech Mater,2007;39:488 |
[4] | Abdel-Karim M,Ohno N.Int Plast,2000;16:225 |
[5] | Chen X,Jiao R,Kim K S.Int J Plast,2005;21:161 |
[6] | Chen X,Jiao R.Int J Plast,2004;20:871 |
[7] | Kang G Z,Gao Q,Yang X J.Acta Metall Sin,2000;36:497(康国政,高庆,杨显杰.金属学报,2000;36:497) |
[8] | Kang G Z,Sun Y F,Zhang J,Kava Q H.Acta Metall Sin,2005:41:277(康国政,孙亚芳,张娟,阚前华.金属学报,2005;41:277) |
[9] | Kan Q H,Kang G Z,Zhmag J,Liu Y J.Acta Metall Sin,2005;41:963(阚前华,康国政,张娟,刘宇杰.金属学报,2005;41:963) |
[10] | Kang G Z,Liu Y J.Acta Metall Sin,2006;42:59(康国政,刘宇杰.金属学报,2006;42:59) |
[11] | Yang Z Y,Wang J,Chert J Y.J Mater Therm Treat,2008;29:98(杨卓越,王建,陈嘉砚.材料热处理学报,2008;29:98) |
[12] | Andrade M S,Gomes O A,Vilela J M C,Serrano A T L,de Moraes J M D.Braz Soc Mech,.Sci Eng,2004;26:47 |
[13] | Hong C H,Ha T K,Chang Y W,Scr Mater,2001;45:823 |
[14] | Llewellyn D T.Mater Sci Technol,1997;13:389 |
[15] | Jing C N,Wang Z C,Hart F T.Met Therra Treat,2005;30(2):26(景财年,王作成,韩福涛.金属热处理,2005;30(2):26) |
[16] | Krempl E,Lu H..J Eng Mater Technol,1984;106:376 |
[17] | Kang G Z,Liu Y J,Li Z.Mater Sci Eng,2006;A435-436:396 |
[18] | Fan X.X-ray Metallurgy.Beijing:Mechanical Induatry Press.1980:1 10(范雄.X射线金属学.北京:机械工业出版社,1980:110) |
- 下载量()
- 访问量()
- 您的评分:
-
10%
-
20%
-
30%
-
40%
-
50%