时效强化CuNiMnFe_x合金研究
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- 英文论文题名:Study on Aging Strengthened CuNiMnFe_x Alloy
- 论文作者:邹军涛 ; 石浩 ; 李涛 ; 王献辉 ; 梁淑华
- 英文论文作者:ZOU Juntao ; SHI Hao ; LI Tao ; WANG Xianhui ; LIANG Shuhua ; Key Laboratory of Electrical Materials and Infiltration Technology Shaanxi Province ; School of Materials Science and Engineering ; Xi'an University of Technolog
- 年:2016
- 作者机构:西安理工大学材料科学与工程学院陕西省电工材料与熔渗技术重点实验室;
- 论文关键词:CuNiMnFe合金 ; 树枝晶 ; 析出相 ; 时效处理
- 英文论文关键词:CuNiMnFe alloy ; dendrite ; precipitated phase ; aging treatment
- 会议召开时间:2016-11-18
- 会议录名称:第一届先进材料前沿学术会议论文集(《材料导报》2016年第30卷第Z1期)
- 语种:中文
- 分类号:TG146.11;TG166.2
- 学会代码:CLDB
- 会议名称:第一届先进材料前沿学术会议
- 会议地点:中国陕西西安
- 主办单位:《材料导报》杂志社
- 学会名称:材料导报编辑部
- 页数:5
- 文件大小:1715k
- 原文格式:O
- 会议级别:全国
摘要
为了细化晶粒,弱化树枝晶尺寸以及获得力学性能良好的CuNiMnFe合金,采用真空感应熔炼制备了Fe含量0%~7.5%(质量分数)的CuNiMnFe合金,并采用固溶处理和时效处理进行强化。通过扫描电镜(SEM)、透射电镜(TEM)、能谱仪(EDS)及X射线衍射仪(XRD)对合金组织形貌及物相分布进行表征分析,并利用布氏硬度计检测合金硬度,采用材料力学试验机测试合金强度等力学性能。结果表明:随着Fe含量增加,CuNiMnFe合金组织中树枝晶得到细化,一次枝晶臂变短,铸态CuNiMnFe合金硬度、抗拉强度及伸长率增加。经过固溶处理及时效处理后,CuNiMnFe合金中产生颗粒状析出相,合金的硬度和抗拉强度显著提高,硬度最高达335HB,抗拉强度最高为889 MPa,但合金断裂机制由韧性断裂转变为脆性断裂。
In order to refine the grain size and dendrite weakening of CuNiMnFe alloy with good mechanical properties,the content of Fe 0%-7.5%(mass fraction) CuNiMnFe alloy prepared by vacuum induction melting process,and the use of solid solution treatment and aging treatment were enhanced.By scanning electron microscopy(SEM),transmission electron microscope(TEM),energy dispersive spectrometer(EDS) and X-ray diffractometer(XRD) on the microstructure morphology and phase distribution were analyzed.And the Brinell hardness test the hardness of the alloy,the mechanical properties such as strength of the alloy were measured by the mechanical testing machine.The results show that with the increase of Fe content,dendritic microstructure in CuNiMnFe alloy is refined and the second dendrite arm becomes shorter,the hardness of cast CuNiMnFe alloy,the tensile strength and elongation increase.After solution treatment and aging treatment,generate granular precipitation in CuNiMnFe alloy,the hardness and tensile strength of the alloy increased,the hardness of up to 335 HB,the maximum tensile strength of 889 MPa alloy,but the fracture mechanism by the change from ductile fracture to brittle fracture.
In order to refine the grain size and dendrite weakening of CuNiMnFe alloy with good mechanical properties,the content of Fe 0%-7.5%(mass fraction) CuNiMnFe alloy prepared by vacuum induction melting process,and the use of solid solution treatment and aging treatment were enhanced.By scanning electron microscopy(SEM),transmission electron microscope(TEM),energy dispersive spectrometer(EDS) and X-ray diffractometer(XRD) on the microstructure morphology and phase distribution were analyzed.And the Brinell hardness test the hardness of the alloy,the mechanical properties such as strength of the alloy were measured by the mechanical testing machine.The results show that with the increase of Fe content,dendritic microstructure in CuNiMnFe alloy is refined and the second dendrite arm becomes shorter,the hardness of cast CuNiMnFe alloy,the tensile strength and elongation increase.After solution treatment and aging treatment,generate granular precipitation in CuNiMnFe alloy,the hardness and tensile strength of the alloy increased,the hardness of up to 335 HB,the maximum tensile strength of 889 MPa alloy,but the fracture mechanism by the change from ductile fracture to brittle fracture.
引文
1 Zhang Changjun,Yu Jian,He Xianghua,et al.Age hardening of cast Cu20Ni20Mn alloy[J].J Chang'an University:Nat Sci Ed,2006,26(3):100(in Chinese).张长军,俞剑.何向华,等.铸造锰白铜合金的时效强化[J].长安大学学报:自然科学版,2006,26(3):100.
2 Pan Qihan.A highly elastic Cu-20Ni-20Mn alloy[J].Chin J Nonferrous Met,1996,6(4):91(in Chinese).潘奇汉.高弹性Cu20Ni20Mn合金[J].中国有色金属学报,1996,6(4):91.
3 Pan Qihan,Wang Deming.Observation on precipitation along grain boundary in Cu-Ni-Mn alloy[J].Acta Metall Sin,1985,21(5).379(in Chinese).潘奇汉,王德明.Cu-Ni-Mn合金晶界析出特点的观察[J].金属学报,1985,21(5):379.
4 Xie Weibin,Wang Qiangsong,et al.Microstructure evolutionand properties of Cu20Ni20Mn alloy during agingprocess[J].Trans Nonferrous Met Soc China,2015,10(25):3247.
5 Zhang Changjun,Yu Jian,He Xianghua.Age hardening of casting alloy Cu20Ni35Mn[J].Mater Sci Technol,2008,16(6):855(in Chinese).张长军,俞剑,何向华.铸态Cu20Ni35Mn合金的直接时效强化研究[J].材料科学与工艺,2008,16(6):855.
6 Xie Weibin,Wang Qiangsong,et al.Kinetics of discontinuous precipitation in Cu-20Ni-20Mn alloy[J].Metall Mater,2016,3(23):323.
7 Zhang Changjun,Zhang Baojun.Study of aging technology in cast Cu-Ni-Mn alloy[J].Hot Working Technol,2005(9):43(in Chinese).张长军,张宝军.铸态锰白铜合金时效工艺的研究[J].热加工工艺,2005(9):43.
8 Lin Gaoyong,Zeng Juhua,Wang Li,et al.Solution and aging strengthening of novel Cu-Al-Fe-Ni wrought aluminum bronze[J].Chin J Nonferrous Met,2012,22(6):1586(in Chinese).林高用,曾菊花,王莉,等.新型Cu-Al-Fe-Ni变形铝青铜的固溶和时效强化[J].中国有色金属学报,2012,22(6):1586.
9 Leijingguo,Liu Ping,ZhaoDongmei,et al.Aging precipitation and recrystallization of Cu-Ni-Si alloy[J].Ordnance Mater Sci Eng,2004,27(1):47(in Chinese).雷静果,刘平,赵冬梅,等.CuNiSi合金的时效析出与再结晶[J].兵器材料科学与工程,2004,27(1):47.
10 Zou Juntao,Liu Yanfeng,Wang Xianhui,et al.Effect of melt-casting temperature on bonding zone of CuNiMnFe/30CrMnSi integral material[J].Adv Mater Res,2011,148-149:664.
11 Zou Juntao,Wang Xianhui,Xiao Peng,et al.Investigation into fracture behaviors of CuNiMnFe/30CrMnSi Bi-metal composite materials[J].J Xi'an University of Technology,2011,27(3):359(in Chinese).邹军涛,王献辉,削鹏,等.CuNiMnFe/30CrMnSi双金属复合材料断裂行为研究[J].西安理工大学学报,2011,27(3):359.
12 Wang Chunjian,Jin Qinglin,Zhou Rong,et al.Grain refinement mechanism of Fe on Mg-3A1 alloy[J].Rare Metal Mater Eng,2012,44(2):266(in Chinese).王春建,金青林,周荣,等.Fe元素对Mg-3Al合金的晶粒细化与机理[J].稀有金属材料与工程,2012,44(2):266.
13 Zhang Z W,Liu C T,Guo S,et al.Boron effects on the ductility of a nano-cluster-strengthened ferritic steel[J].Mater Sci Eng A,2011,528(3):855.
14 Empl D,Laporte V,Vincent E,et al.Improvement of elevated temperature mechanical properties of Cu-Ni-Sn-Pb alloys[J].Mater Sci Eng A,2010,527(16-17):4326.
15 Ai Yunlong,Xie Yaohui,Chen Weihua,et al.Microstructure evolution of high silicon nickel-copper alloy NCu30-4-2-l during heattreatment[J].Trans Mater Heat Treatment,2014,35(8):64(in Chinese).艾云龙,谢耀辉,陈卫华,等.高硅镍铜合金NCu30-4-2-1热处理组织演变[J].材料热处理学报,2014,35(8):64.
16 Dong Qiyi,Wang Mingpu,Jia Yanlin,et al.Effect of P content on microstructure and property of Cu-Fe-P alloys[J].Trans Mater Heat Treatment,2013,34(6):75(in Chinese).董琦祎,汪明朴,贾延琳,等.磷含量对Cu-Fe-P合金组织与性能的影响[J].材料热处理学报,2013,34(6):75.
2 Pan Qihan.A highly elastic Cu-20Ni-20Mn alloy[J].Chin J Nonferrous Met,1996,6(4):91(in Chinese).潘奇汉.高弹性Cu20Ni20Mn合金[J].中国有色金属学报,1996,6(4):91.
3 Pan Qihan,Wang Deming.Observation on precipitation along grain boundary in Cu-Ni-Mn alloy[J].Acta Metall Sin,1985,21(5).379(in Chinese).潘奇汉,王德明.Cu-Ni-Mn合金晶界析出特点的观察[J].金属学报,1985,21(5):379.
4 Xie Weibin,Wang Qiangsong,et al.Microstructure evolutionand properties of Cu20Ni20Mn alloy during agingprocess[J].Trans Nonferrous Met Soc China,2015,10(25):3247.
5 Zhang Changjun,Yu Jian,He Xianghua.Age hardening of casting alloy Cu20Ni35Mn[J].Mater Sci Technol,2008,16(6):855(in Chinese).张长军,俞剑,何向华.铸态Cu20Ni35Mn合金的直接时效强化研究[J].材料科学与工艺,2008,16(6):855.
6 Xie Weibin,Wang Qiangsong,et al.Kinetics of discontinuous precipitation in Cu-20Ni-20Mn alloy[J].Metall Mater,2016,3(23):323.
7 Zhang Changjun,Zhang Baojun.Study of aging technology in cast Cu-Ni-Mn alloy[J].Hot Working Technol,2005(9):43(in Chinese).张长军,张宝军.铸态锰白铜合金时效工艺的研究[J].热加工工艺,2005(9):43.
8 Lin Gaoyong,Zeng Juhua,Wang Li,et al.Solution and aging strengthening of novel Cu-Al-Fe-Ni wrought aluminum bronze[J].Chin J Nonferrous Met,2012,22(6):1586(in Chinese).林高用,曾菊花,王莉,等.新型Cu-Al-Fe-Ni变形铝青铜的固溶和时效强化[J].中国有色金属学报,2012,22(6):1586.
9 Leijingguo,Liu Ping,ZhaoDongmei,et al.Aging precipitation and recrystallization of Cu-Ni-Si alloy[J].Ordnance Mater Sci Eng,2004,27(1):47(in Chinese).雷静果,刘平,赵冬梅,等.CuNiSi合金的时效析出与再结晶[J].兵器材料科学与工程,2004,27(1):47.
10 Zou Juntao,Liu Yanfeng,Wang Xianhui,et al.Effect of melt-casting temperature on bonding zone of CuNiMnFe/30CrMnSi integral material[J].Adv Mater Res,2011,148-149:664.
11 Zou Juntao,Wang Xianhui,Xiao Peng,et al.Investigation into fracture behaviors of CuNiMnFe/30CrMnSi Bi-metal composite materials[J].J Xi'an University of Technology,2011,27(3):359(in Chinese).邹军涛,王献辉,削鹏,等.CuNiMnFe/30CrMnSi双金属复合材料断裂行为研究[J].西安理工大学学报,2011,27(3):359.
12 Wang Chunjian,Jin Qinglin,Zhou Rong,et al.Grain refinement mechanism of Fe on Mg-3A1 alloy[J].Rare Metal Mater Eng,2012,44(2):266(in Chinese).王春建,金青林,周荣,等.Fe元素对Mg-3Al合金的晶粒细化与机理[J].稀有金属材料与工程,2012,44(2):266.
13 Zhang Z W,Liu C T,Guo S,et al.Boron effects on the ductility of a nano-cluster-strengthened ferritic steel[J].Mater Sci Eng A,2011,528(3):855.
14 Empl D,Laporte V,Vincent E,et al.Improvement of elevated temperature mechanical properties of Cu-Ni-Sn-Pb alloys[J].Mater Sci Eng A,2010,527(16-17):4326.
15 Ai Yunlong,Xie Yaohui,Chen Weihua,et al.Microstructure evolution of high silicon nickel-copper alloy NCu30-4-2-l during heattreatment[J].Trans Mater Heat Treatment,2014,35(8):64(in Chinese).艾云龙,谢耀辉,陈卫华,等.高硅镍铜合金NCu30-4-2-1热处理组织演变[J].材料热处理学报,2014,35(8):64.
16 Dong Qiyi,Wang Mingpu,Jia Yanlin,et al.Effect of P content on microstructure and property of Cu-Fe-P alloys[J].Trans Mater Heat Treatment,2013,34(6):75(in Chinese).董琦祎,汪明朴,贾延琳,等.磷含量对Cu-Fe-P合金组织与性能的影响[J].材料热处理学报,2013,34(6):75.
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