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限制模压变形均匀性研究与定量表征 被引量:2

Investigation and quantitative characterization of homogeneity in constrained groove pressing
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摘要 采用限制模压法(Constrained Groove Pressing,CGP)变形商业5052铝合金,考察了经不同道次变形后试样的显微硬度均匀性,即CGP的变形均匀性,并讨论了模具齿宽对变形均匀性的影响。结果表明,CGP变形能够显著提高5052铝合金的显微硬度值,但模具齿宽对显微硬度的提高影响不大;CGP变形1道次后,试样显微硬度分布极不均匀,但是随变形道次的增加,试样显微硬度分布趋于均匀;弯曲延展区的存在是导致CGP变形不均匀的根本原因,这种不均匀性可通过增加变形道次或增加模具齿宽加以改善。 Samples of 5052 Al were subjected to constrained groove pressing (CGP) under the conditions with different tooth widths and pass numbers.The microhardness was recorded on the polished XOZ plane of each sample and the results were plotted to provide a pictorial depiction of the homogeneity.The results show that the microhardness increases significantly after CGP but is independent upon tooth width.The microhardness distribution is homogeneous in the non-pressed condition but inhomogeneous after a single pass and then reasonably homogeneous in subsequent passes.The results reveal that the essential reason of inhomogeneity is the existence of the interface region between the shear and flat regions.It is shown that good homogeneity may be achieved through CGP pressing by increase the number of pass or the width of pressing tooth.
作者 杨开怀 彭开萍 陈文哲
机构地区 福州大学材料科学与工程学院 福建工程学院
出处 《塑性工程学报》 CAS CSCD 北大核心 2010年第4期8-12,共5页 Journal of Plasticity Engineering
基金 福建省科技厅重点资助项目(2009H0023) 福建省教育厅资助项目(JB07027)
关键词 限制模压变形 均匀性 显微硬度 5052铝合金 constrained groove pressing homogeneity microhardness 5052 aluminum alloy
分类号 TG113 [金属学及工艺—物理冶金] TG115 [金属学及工艺—物理冶金]
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参考文献14

  • 1Valiev R Z, Islamgaliev R K, Alexandrov I V. Bulk nanostructured materials from severe plastic deformation[J]. Progress in Materials Science, 2000. 45: 103- 189.
  • 2Langdon T G. The processing of ultrafine-grained materials through the application of severe plastic deformation[J]. Journal of Materials Science, 2007. 42: 3388- 3397.
  • 3杨开怀,陈文哲.大体积超细晶金属材料的剧烈塑性变形法制备技术[J].塑性工程学报,2010,17(2):123-129. 被引量:17
  • 4Shin D H, Park J J, Kim Y S, Park K T. Constrained groove pressing and its application to grain refinement of aluminum[J].Materials Science &Engineering A, 2002. 328:98-103.
  • 5Krishnaiah A, Chakkingal U,Venugopal P. Applicability of the groove pressing technique for grain refinement in commercial purity copper[J]. Materials Science &Engineering A,2005. 410-411 : 337-340.
  • 6Krishnaiah A, Chakkingal U, Venugopal P. Production of ultrafine grain sizes in aluminium sheets by severe plastic deformation using the technique of groove pressing[J]. Scripta Materialia,2005.52: 1229-1233.
  • 7Zrnik J, Kovarik T, Novy Z, Cieslar M. Ultrafine- grained structure development and deformation behavior of aluminium processed by constrained groove pressing[J]. Materials Science & Engineering A,2009. 503: 126-129.
  • 8PENG Kai-ping, SU Li-feng. , SHAW L L, QIAN Kuang-wu. Grain refinement and crack prevention in constrained groove pressing of two-phase Cu Zn alloys [J]. Scripta Materialia, 2007. 56: 987-990.
  • 9Yoon S C, Krishaniah A, Chakkingal U, Kim H S. Severe plastic deformation and strain localization in groove pressing[J].Computational Materials Science, 2008.43: 641-645.
  • 10许泽建,李玉龙,李朋洲.0Cr18Ni10Ti不锈钢焊接接头的显微硬度研究[J].金属学报,2008,44(5):636-640. 被引量:15

二级参考文献93

  • 1徐锦锋,翟秋亚.AZ91B镁合金TIG焊接头组织与性能[J].特种铸造及有色合金,2004,24(4):23-25. 被引量:27
  • 2刘黎明,宋刚,王继锋,梁国俐.Microstructure and mechanical properties of wrought magnesium alloy AZ31B welded by laser-TIG hybrid[J].中国有色金属学会会刊:英文版,2004,14(3):550-555. 被引量:3
  • 3R Z Valiev, R K Islamgaliev, I V Alexandrov. Bulk nanostructured materials from severe plastic deformation[J]. Progress in Materials Science, 2000. 45: 103- 189.
  • 4H Gleiter. Nanocrystalline materials [J]. Progress in Materials Science, 1989,33: 223-315.
  • 5Y T Zhu, T C Lowe, T G Langdon Performance and applications of nanostructured materials produced by severe plastic deformation[J]. Scripta Materialia, 2004. 51:825-830.
  • 6Y T Zhu, T G LangdorL The Fundamentals of Nanostructured Materials Processed by Severe Plastic Deformation[J]. JOM, 2004. 56 : 58-63.
  • 7J R Weertman. Hall-Petch strengthening in nanocrystalline metals[J]. Material Science & Engineering A, 1993. 166: 161-167.
  • 8U Erb, A M El-Sherik, G Palumbo, et al. Synthesis, structure and properties of electroplated nanocrystalline materials[J]. Nanostructured Materials, 1993. (2) : 383- 390.
  • 9C C Koch, Y S Cho. Nanocrystals by high energy ball milling[J]. Nanostructured Materials, 1992. ( 1 ):207- 212.
  • 10Z Horita,T Fujinami, T G Langdon. The potential for scaling ECAP: effect of sample size on grain refinement and mechanical properties[J]. Materials Science & Engineering A, 2001. 318: 34-41.

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塑性工程学报
2010年 第4期

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