研究纯镍丝材单向微拉伸塑性变形过程中的流动应力和非均匀变形行为尺寸效应。实验发现,流动应力随晶粒尺寸的增加(或直径方向上晶粒数量的减少)而降低,而非均匀变形程度增加。当直径方向上少于9.3个晶粒时,流动应力随晶粒尺寸增加而快速降低。通过引入晶界尺寸因子构建介观尺度材料本构模型揭示丝材微拉伸流动应力尺寸效应。结果表明,断裂应变和断裂应力随着晶粒尺寸的增加而减小。当试样直径方向上少于14.7个晶粒时,断裂应变和断裂应力快速降低,表明微拉伸过程中的非均匀变形程度随着直径方向上晶粒数量的减小而增加。当试样直径方向上的晶粒数量减少时,断口形貌变得越来越不规则。从材料微观组织分布方面分析了不规则断口形貌的形成机理。
Size effects on plastic deformation behaviors in uniaxial micro tension of pure nickel fine wires were investigated experimentally, including flow stress and inhomogeneous deformation behaviors. It is found that with the increase of grain size or the decrease of number of grains across the diameter, the flow stress decreases and inhomogeneous deformation degree increases. When there are less than 9.3 grains across the diameter, the flow stress decreases quickly with the increase of grain size. Then, the flow stress size effect in micro tension of fine wires is revealed by a proposed model by introducing the grain boundary size factor. These results also indicate that both the fracture strain and stress decrease with the increase of grain size. When there are less than 14.7 grains across the diameter, both the fracture strain and stress decrease quickly. This indicates that the inhomogeneous deformation degree in micro tension increases with the decrease of the number of grains across the diameter. The fracture topography tends to be more and more irregular with the decrease of the number of grains across the diameter. Then, the formation mechanism of irregular fracture topography was analyzed considering the inhomogeneous distribution of microstructure when there are a few grains across the diameter.
参考文献
| [1] | M. Geiger;M. Kleiner;R. Eckstein;N. Tiesler;U. Engel.Microforming[J].CIRP Annals,20012(2):445-462. |
| [2] | M. W. Fu;W. L. Chan.A review on the state-of-the-art microforming technologies[J].The International Journal of Advanced Manufacturing Technology,20139/12(9/12):2411-2437. |
| [3] | Yi Qin;A. Brockett;Y. Ma;A. Razali;J. Zhao;C. Harrison;W. Pan;X. Dai;D. Loziak.Micro-manufacturing: research, technology outcomes and development issues[J].The International Journal of Advanced Manufacturing Technology,20109/12(9/12):821-837. |
| [4] | T. A. Kals;Ralf Eckstein.Miniaturization in sheet metal working[J].Journal of Materials Processing Technology,20001(1):95-101. |
| [5] | S. Geissdorfer;U. Engel;M. Geiger.FE-simulation of microforming processes applying a mesoscopic model[J].International Journal of Machine Tools & Manufacture: Design, research and application,200611(11):1222-1226. |
| [6] | Chuan-Jie Wang;Chun-Ju Wang;Bin Guo;De-Bin Shan;Yan-Yan Chang.Mechanism of size effects in microcylindrical compression of pure copper considering grain orientation distribution[J].稀有金属(英文版),2013(01):18-24. |
| [7] | 林晓娟;王广春;郑伟;姜华;李锦.微细薄板尺度依赖的材料本构模型的构建[J].中国有色金属学报(英文版),2014(2):470-476. |
| [8] | Keller, C;Hug, E;Chateigner, D.On the origin of the stress decrease for nickel polycrystals with few grains across the thickness[J].Materials Science and Engineering. A, Structural Materials: Properties, Microstructure and Processing,20091/2(1/2):207-215. |
| [9] | TEM study of dislocation patterns in near-surface and core regions of deformed nickel polycrystals with few grains across the cross section[J].Mechanics of materials,20101(1):44. |
| [10] | Chen, X.X.;Ngan, A.H.W..Tensile deformation of silver micro-wires of small thickness-to-grain-size ratios[J].Materials Science & Engineering, A. Structural Materials: Properties, Misrostructure and Processing,2012:74-84. |
| [11] | X.X. Chen;A.H.W. Ngan.Specimen size and grain size effects on tensile strength of Ag microwires[J].Scripta materialia,20118(8):717-720. |
| [12] | A. Diehl;U. Engel;M. Geiger.Influence of microstructure on the mechanical properties and the forming behaviour of very thin metal foils[J].The International Journal of Advanced Manufacturing Technology,20101/4(1/4):53-61. |
| [13] | G. Simons;Ch. Weippert;J. Dual;J. Villain.Size effects in tensile testing of thin cold rolled and annealed Cu foils[J].Materials Science & Engineering, A. Structural Materials: Properties, Misrostructure and Processing,20061/2(1/2):290-299. |
| [14] | L. V. Raulea;A. M. Goijaerts;L. E. Govaert.Size effects in the processing of thin metal sheets[J].Journal of Materials Processing Technology,20011(1):44-48. |
| [15] | W.L. Chan;M.W. Fu;B. Yang.Study of size effect in micro-extrusion process of pure copper[J].Materials & design,20117(7):3772-3782. |
| [16] | Neil Krishnan;Jian Cao;Kuniaki Dohda.Study of the Size Effects on Friction Conditions in Microextrusion - Part I: Microextrusion Experiments and Analysis[J].Journal of manufacturing science and engineering,20074(4):669-676. |
| [17] | Jian Cao;Weimin Zhuang;Shiwen Wang;Jianguo Lin.Development of a VGRAIN system for CPFE analysis in micro-forming applications[J].The International Journal of Advanced Manufacturing Technology,20109/12(9/12):981-991. |
| [18] | G. C. Wang;W. Zheng;T. Wu;H. Jiang;G. Q. Zhao;D. B. Wei;Z. Y. Jiang.A multi-region model for numerical simulation of micro bulk forming[J].Journal of Materials Processing Technology,20123(3):678-684. |
| [19] | Chuanjie Wang;Chunju Wang;Bin Guo;Debin Shan;Guan Huang.Size effect on flow stress in uniaxial compression of pure nickel cylinders with a few grains across thickness[J].Materials Letters,2013Sep.1(Sep.1):294-296. |
| [20] | Wang, Chuan-jie;Wang, Chun-ju;Xu, Jie;Zhang, Peng;Shan, De-bin;Guo, Bin.Plastic deformation size effects in micro-compression of pure nickel with a few grains across diameter[J].Materials Science & Engineering, A. Structural Materials: Properties, Misrostructure and Processing,2015:352-360. |
| [21] | Sasawat Mahabunphachai;Muammer Koc.Investigation of size effects on material behavior of thin sheet metals using hydraulic bulge testing at micro/meso-scales[J].International Journal of Machine Tools & Manufacture: Design, research and application,20089(9):1014-1029. |
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