冷变形对铸轧辊用Cu-Be-Co合金组织性能的影响

周延军; 王启峰; 佘京鹏; 宋克兴; 刘海涛; 黄景明; 李韶林

doi:10.15980/j.tzzz.2022.05.005

研究·合金工艺 | 浏览量 : 0 下载量: 36 CSCD: 0

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冷变形对铸轧辊用Cu-Be-Co合金组织性能的影响
Effects of Cold Deformation on Microstructure and Properties of Cu-Be-Co Alloy for Casting Roller
2022年42卷第5期页码：551-554
纸质出版日期： 2022 ，
DOI： 10.15980/j.tzzz.2022.05.005

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周延军, 王启峰, 佘京鹏, 等. 冷变形对铸轧辊用Cu-Be-Co合金组织性能的影响[J]. 特种铸造及有色合金, 2022,42(5):551-554.

Zhou Yanjun, Wang Qifeng, She Jingpeng, et al. Effects of Cold Deformation on Microstructure and Properties of Cu-Be-Co Alloy for Casting Roller[J]. Special Casting & Nonferrous Alloys, 2022,42(5):551-554.
周延军, 王启峰, 佘京鹏, 等. 冷变形对铸轧辊用Cu-Be-Co合金组织性能的影响[J]. 特种铸造及有色合金, 2022,42(5):551-554. DOI： 10.15980/j.tzzz.2022.05.005.

Zhou Yanjun, Wang Qifeng, She Jingpeng, et al. Effects of Cold Deformation on Microstructure and Properties of Cu-Be-Co Alloy for Casting Roller[J]. Special Casting & Nonferrous Alloys, 2022,42(5):551-554. DOI： 10.15980/j.tzzz.2022.05.005.

摘要

对制备的Cu-0.2Be-0.8Co合金进行950℃×1 h固溶+不同变形量冷变形+480℃×4 h时效处理，冷变形量分别为10%、20%、30%、40%、50%

利用硬度计、导电仪等测试了不同冷变形量时效后的合金硬度和电导率，并利用金相显微镜(OM)、透射电镜(TEM)等手段进行了晶粒特征、析出相特征观察和分析。结果表明，固溶和时效之间施加不同程度的冷变形对合金硬度影响显著，而对电导率的影响较小。同未施加冷变形的固溶+时效处理相比，在时效前施加50%的冷变形量，合金硬度(HB)和电导率分别达到176和36.714 MS/m

在较小降低电导率的前提下大幅提升了合金的硬度，达50.4%。合金经形变热处理后晶粒发生不同程度的塑性变形，析出相形貌、大小和分布发生显著变化，且与位错之间的交互作用增加，冷变形的施加为后续时效析出储备了能量，提高了析出效率和析出率，使合金硬度显著提高。

Abstract

The prepared Cu-0.2 Be-0.8 Co alloy was treated by 950 ℃×1 h solid solution+different deformation rate of cold deformation+480 ℃×4 h aging treatment

where the cold deformation rate are 10%

20%

30%

40%

50%

respectively. The hardness and conductivity rate of the alloy after different cold deformation treatments were tested by sclerometer and conductometer. The grain and precipitate characteristics are also observed and analyzed by optical microscopy（OM） and transmission electron microscopy（TEM）. The results indicate that different degrees of cold deformation between solution and aging have a significant effect on the hardness of the alloy

while little effect on the conductivity. Compared with the solution+aging treatment without cold deformation

the hardness and conductivity of the alloy reach 176 HB and 36.714 MS/m

respectively

with 50% cold deformation applied before aging

greatly increasing the hardness by 50.4% on the premise of small sacrificial conductivity. Grains of the alloy undergo different degrees of plastic deformation

where the morphology

dimension and distribution of precipitates are changed significantly

and the interaction with dislocations is increased. The cold deformation exerting reserves energy for subsequent aging precipitation

improving precipitation efficiency and precipitation rate

thus enhancing the hardness of the alloy significantly.