期刊文献+
任意字段
题名或关键词
题名
关键词
文摘
作者
第一作者
机构
刊名
分类号
参考文献
作者简介
基金资助
栏目信息

不同结构纳米晶镍钴合金的力学性能 被引量:6

Mechanical properties of nanocrystalline Ni-Co alloy with different microstructures
在线阅读 下载PDF
导出
摘要 采用直流电沉积方法制备晶粒尺寸为15 nm的Ni-49.2%Co(质量分数)和16 nm的Ni-66.7%Co(质量分数)合金。采用XRD、TEM和MTS-810万能材料试验机对其微观结构和力学性能进行分析。结果表明:两种合金分别是单相FCC结构和FCC与HCP共存的双相结构。固溶强化和晶粒细化的作用使两种Ni-Co合金都具有很高的抗拉强度;且Co元素的引入降低材料的层错能,提高其应变硬化能力,使Ni-Co合金的塑性也明显提高;Ni-49.2%Co合金的抗拉强度(σb)和断裂伸长率(δ)分别为1 650 MPa和9%,Ni-66.7%Co合金的σb和δ分别为2 200 MPa和12%。Ni-66.7%Co合金中FCC和HCP结构相互协调,在变形过程中释放内应力,使材料应变硬化能力得以保持,所以获得更高的强度和塑性。 Nanocrystalline Ni-49.2%Co (mass fraction) and Ni-66.7%Co (mass fraction) alloys were synthesized by direct current electrodeposition with grain sizes of 15 and 16 nm, respectively. The Ni-49.2%Co alloy shows single FCC phase, and Ni-66.7%Co alloy possesses a mixture structure of FCC and HCP phase. The microstructure and mechanical properties of were studied by XRD, TEM and tensile tests carried out on MTS-810 tester. The high strength of Ni-Co alloys is attributed to the grain refinement and solid-solution hardening effects. The addition of Co element decreases the stacking fault energy of nanocrystailine Ni alloy, which improves the strain hardening ability and thus enhances the ductility. The ultimate tensile strength (%) and elongation to failure (c5) of Ni-49.2%Co alloy are 1 650 MPa and 9%, respectively. Correspondingly, the ab and δ of Ni-66.7%Co alloy are 2 200 MPa and 12%, respectively. Cooperative deformation of the two phases releases the stress during deformation effectively, which contributes to the sustained high strain hardening and ductility of the Ni-66.7%Co alloy.
作者 秦丽元 连建设 蒋恩臣 刘中原
机构地区 东北农业大学工程学院 吉林大学材料科学与工程学院
出处 《中国有色金属学报》 EI CAS CSCD 北大核心 2013年第10期2846-2850,共5页 The Chinese Journal of Nonferrous Metals
基金 国家博士后基金资助项目(2012M520698) 黑龙江省教育厅科技项目(12531002) 东北农业大学博士启动基金资助项目(2012RCB97)
关键词 镍钴合金 电沉积 纳米晶 双相结构 力学性能 Ni-Co alloy electrodeposition nanocrystalline dual-phase microstructure mechanical property
分类号 TG113 [金属学及工艺—物理冶金]
  • 相关文献

参考文献17

  • 1HIBBARD G D, AUST K T, ERB U. Thermal stability of electrodeposited nanocrystalline Ni-Co alloys[J]. Materials Science and Engineering A, 2006, 433(1/2): 195-202.
  • 2许伟长,戴品强.电沉积微纳米镍的组织结构与力学性能[J].中国有色金属学报,2009,19(10):1815-1821. 被引量:8
  • 3冯广海,杜忠泽,闫敦,王经涛.纳米/微米Cu的力学性能数值模拟[J].中国有色金属学报,2012,22(1):201-207. 被引量:1
  • 4QIN Li-yuan. Microstructures and properties characteristic of electrodeposited nanocrystalline Ni and Ni-Co alloys[D]. Changchun: College of Materials Science and Engineering, Jilin University, 2010: 1-122.
  • 5VALIEV R. Nanostructuring of metals by severe plastic deformation for advanced properties[J]. Nature Materials, 2004, 3(8): 511-516.
  • 6LU L, CHEN X, HUANG X, LU K. Revealing the maximum strength in nanotwinned copper[J]. Science, 2009, 323(5914): 607-610.
  • 7SHEN X, LIAN J, JIANG Z, JIANG Q. The optimal grain sized nanocrystalline Ni with high strength and good ductility fabricated by a direct current electrodeposition[J]. Advanced Engineering Materials, 2008, 10(6): 539-546.
  • 8LI H. EBRAHIMI F. Transition of deformation and fracture behaviors in nanostructured face-centered-cubic metals[J]. Applied Physics Letters, 2004, 84(12): 4307-4309.
  • 9许伟长,戴品强,郑耀东.钴含量对电沉积纳米晶镍钴合金组织与力学性能的影响[J].中国有色金属学报,2010,20(1):92-99. 被引量:20
  • 10LIU Y, YANG H, LIU Y, JIANG B, DING J, WOODWARD R. Thermally induced fcc,--~hcp martensitic transformation in Co-Ni[J]. Acta Materialia, 2005, 53(13): 3625-3634.

二级参考文献50

  • 1谢子令,武晓雷,洪友士.微纳米晶金属的应变率敏感性及应变硬化行为分析[J].固体力学学报,2007,28(1):43-48. 被引量:6
  • 2李伯林,朱敏,李隆,罗堪昌,李祖鑫.机械合金化形成的Fe-Cu纳米晶过饱和固溶体的硬化及软化[J].金属学报,1997,33(4):420-426. 被引量:9
  • 3杜林秀,熊明鲜,姚圣杰,刘相华,王国栋.利用相变进行低碳钢的亚微米化[J].金属学报,2007,43(1):59-63. 被引量:8
  • 4BIRRINGER R, GLEITER H, KLEIN H P, MARQUARDT P. Nanocrystalline materials an approach to a novel solid structure with gas-like disorder[J]. Physics Letters A, 1984, 102(8): 365-369.
  • 5LI H Q, EBRAHIMI F. Tensile behavior of a nanocrystalline Ni-Fe alloy[J]. Acta Materialia, 2006, 54: 3977-3986.
  • 6GU C D, LIAN J S, JIANG Q, JIANG Z H. Ductile-brittle-ductile transition in an electrodeposited 13 nanometer grain sized Ni-8.6 wt.%Co alloy[J]. Mater Sci Eng A, 2007, 459: 75-81.
  • 7DAO M, LU L, ASARO R J, DE HOSSON J T M, MA E. Toward a quantitative understanding of mechanical behavior of nanocrystalline metals[J]. Acta Materialia, 2007, 55(12):4041-4065.
  • 8KUMAR K S, SURESH S, CHISHOLM M F, HORTOM J A, WANG E Deformation of electrodeposited nanocrystalline nickel[J]. Acta Materialia, 2003, 51 (2): 387-405.
  • 9BUDROVIC Z, van SWYGENHOVEN H, DERLET P M, van PETEGEM S, BERND S. Plastic deformation with reversible peak broadening in nanocrystalline nickel[J]. Science, 2004, 304: 273-276.
  • 10Mc FADDEN S X, MISHRA R S, VALIEV R Z, ZHILYAEV A P, MUKHERJEE A K. Low-temperature superplasticity in nanostructure nickel and metal alloys[J]. Nature, 1999, 398: 684-686.

共引文献26

同被引文献76

  • 1王立平,高燕,刘惠文,徐洮.电沉积梯度Ni-Co纳米合金镀层的研究[J].电镀与涂饰,2004,23(6):5-7. 被引量:14
  • 2Nairong TAO Ke LU.Dynamic Plastic Deformation (DPD):A Novel Technique for Synthesizing Bulk Nanostructured Metals[J].Journal of Materials Science & Technology,2007,23(6):771-774. 被引量:10
  • 3WEN Hai-ming, TOPPING T D, ISHEIM D, SEIDMAN D N, LAVERNIA E J. Strengthening mechanisms in a high-strength bulk nanostructured Cu-Zn-A1 alloy processed via cryomilling and spark plasma sintering[J]. Acta Mater, 2013, 61: 2769-2782.
  • 4ZHAO Yong-hao, ZHU Yun-tian, LAVERNIA E J. Strategies for improving tensile ductility of bulk nanostructured materials[J]. Adv Eng Mater, 2010, 12: 769-778.
  • 5VALIEV R Z, ISLAMGALIEV R K, ALEXANDROV I V. Bulk nanostructured materials from severe plastic deformation[J]. Prog Mater Sci, 2000, 45: 103-189.
  • 6ZHU Yun-tian, LIAO Xiao-zhou. Nanostructured metals: Retaining ductility[J]. Nat Mater, 2004, 3: 351-352.
  • 7GONG Yu-lan, WEN Cen-e, WU Xiao-xiang, REN Shi-ying, CHENG Lian-ping, ZHU Xin-kun. The influence of strain rate, deformation temperature and stacking fault energy on the mechanical properties of Cu alloys[J]. Mater Sci Eng A, 2013, 583: 199-204.
  • 8CHRISTIAN J W, MAHAJAN S. Deformation twinning[J]. Prog Mater Sci, 1995, 39: 1-157.
  • 9KANG D H, KIM T W. Mechanical behavior and microstructural evolution of commercially pure titanium in enhanced multi-pass equal channel angular pressing and cold extrusion[J]. Mater Des, 2010, 31: S54-S60.
  • 10KAWASAKI M, AHN B, LANGDON T G. Effect of strain reversals on the processing of high-purity aluminum by high-pressure torsion[J]. J Mater Sci, 2010, 45: 4583-4893.

引证文献6

二级引证文献28

中国有色金属学报
2013年 第10期

相关作者

内容加载中请稍等...

相关机构

内容加载中请稍等...

相关主题

内容加载中请稍等...

浏览历史

内容加载中请稍等...
;
使用帮助 返回顶部