温度与应变速率对Invar 36合金变形行为的影响

doi:10.11900/0412.1961.2017.00043

金属学报

2017, Vol. 53

Issue (8): 968-974 DOI: 10.11900/0412.1961.2017.00043

本期目录 | 过刊浏览

温度与应变速率对Invar 36合金变形行为的影响

李细锋¹, 陈楠楠¹, 李佼佼¹, 何雪婷², 刘红兵², 郑兴伟², 陈军¹(

)

1 上海交通大学模具CAD国家工程研究中心上海 200030
2 上海飞机制造有限公司上海 201324

Effect of Temperature and Strain Rate on Deformation Behavior of Invar 36 Alloy

Xifeng LI¹, Nannan CHEN¹, Jiaojiao LI¹, Xueting HE², Hongbing LIU², Xingwei ZHENG², Jun CHEN¹(

)

1 National Engineering Research Center of Die and Mold CAD, Shanghai Jiao Tong University, Shanghai 200030, China
2 Shanghai Aircraft Manufacturing Co., Ltd., Shanghai 201324, China

引用本文:

李细锋, 陈楠楠, 李佼佼, 何雪婷, 刘红兵, 郑兴伟, 陈军. 温度与应变速率对Invar 36合金变形行为的影响[J]. 金属学报, 2017, 53(8): 968-974.
Xifeng LI, Nannan CHEN, Jiaojiao LI, Xueting HE, Hongbing LIU, Xingwei ZHENG, Jun CHEN. Effect of Temperature and Strain Rate on Deformation Behavior of Invar 36 Alloy[J]. Acta Metall Sin, 2017, 53(8): 968-974.

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摘要:

在室温至900 ℃温度范围内、不同初始应变速率(8×10^-5、8×10^-4和8×10^-3 s^-1)下,利用单向拉伸实验研究了温度与应变速率对Invar 36合金拉伸力学性能的影响,并选择室温、600和800 ℃进行三点弯曲实验,分析温度对Invar 36合金厚板回弹规律的影响。结果表明,Invar 36合金的屈服强度、抗拉强度随温度的升高而大幅降低;延伸率则先升高后降低,在600 ℃时出现峰值,达到69.2%,比室温提高了55%,这主要由于动态再结晶使塑性提高所致。当温度较低时(室温和500 ℃),应变速率对Invar 36合金力学性能影响不大;但当温度升高至800 ℃时,Invar 36合金的强度和塑性均随初始应变速率的减小而大幅减小,初始应变速率由8×10^-3 s^-1降至8×10^-5 s^-1,屈服强度、抗拉强度和延伸率分别降低了38%、47%和50%;由室温升高至800 ℃时,三点弯曲回弹量减小87.0%。

关键词 ： Invar 36合金, 温度, 应变速率, 力学性能, 回弹

Abstract：

Since the thermal expansion coefficient of Invar 36 alloy is so low that it matches the composite materials well. It is very suitable as the material of composite material forming mould. Invar 36 alloy mould surface is usually produced by hot pressing technology. The hot pressing temperature and strain rate severely affect the quality of mould surface. In this work, the mechanical properties of Invar 36 alloy were studied in the temperature range from room temperature to 900 ℃ under different initial strain rates (8×10^-5, 8×10^-4 and 8×10^-3 s^-1) by using uniaxial tensile tests. The effect of temperature on the springback trend of thick Invar 36 alloy sheet by three-point bending tests at room temperature, 600 ℃ and 800 ℃ was investigated. The results indicate that the yield strength and ultimate tensile strength of Invar 36 alloy significantly decrease with increasing temperature. Meanwhile, the elongation firstly increases and then decreases with the increase of temperature. It reaches a peak value of 69.2% at 600 ℃ and increases by 55% than that at ambient temperature, which mainly results from the plasticity improvement by dynamic recrystallization. Invar 36 alloy at lower temperature (room temperature and 500 ℃) shows insensitive to the strain rate. Nevertheless, the strength and plasticity at 800 ℃ substantially decrease with decreasing strain rate. When the strain rate decreases from 8×10^-3 s^-1 to 8×10^-5 s^-1, the yield strength, ultimate tensile strength and elongation reduce by 38%, 47% and 50%, respectively. The three-point bending springback value decreases by 87.0% when the tested temperature increases from room temperature to 800 ℃.

Key words： Invar 36 alloy temperature strain rate mechanical property springback

收稿日期: 2017-02-13

ZTFLH:

TG142.76

作者简介:

作者简介李细锋,男,1980年生,副研究员,博士

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https://www.ams.org.cn/CN/10.11900/0412.1961.2017.00043 或 https://www.ams.org.cn/CN/Y2017/V53/I8/968

图1 三点弯曲实验模具

图2 不同温度拉伸后试样的宏观断口

图3 不同温度下Invar 36合金的拉伸工程应力-应变曲线

表1 不同温度下Invar 36合金的拉伸力学性能

图4 初始Invar 36合金和不同温度拉伸后组织的OM像

图5 Invar 36合金高温拉伸断口附近纵截面组织OM像

图6 不同温度下应变速率对Invar 36合金工程应力-应变曲线的影响

表2 Invar 36合金厚板不同温度下三点弯曲回弹实验数据

[1]	Nan J M, Li G X, Xu K W.Yielding behavior of low expansion invar alloy at elevated temperature[J]. J. Mater. Process. Technol., 2001, 114: 36
[2]	Wang J P.Process development for invar shadow mask[J]. Vac. Electron., 1999, (4): 54(王建平. 殷钢荫罩的加工工艺[J]. 真空电子技术, 1999, (4): 54)
[3]	Shiga M.Invar alloys[J]. Curr. Opin. Solid State Mater. Sci., 1996, 1: 340
[4]	Gibbons G, Wimpenny D.Mechanical and thermomechanical properties of metal spray invar for composite forming tooling[J]. J. Mater. Eng. Perform., 2000, 9: 630
[5]	Ha T K, Min S H.Effect of C content on the microstructure and physical properties of Fe-36Ni Invar alloy[J]. Mater. Sci. Forum, 2015, 804: 293
[6]	Zhao Y, Sato Y S, Kokawa H, et al.Microstructure and properties of friction stir welded high strength Fe-36 wt%Ni alloy[J]. Mater. Sci. Eng., 2011, A528: 7768
[7]	DeBra D B. Vibration isolation of precision machine tools and instruments[J]. CIRP Ann. Manuf. Technol., 1992, 41: 711
[8]	Wimpenny D I, Gibbons G J.Metal spray invar tooling for composites[J]. Aircr. Eng. Aerosp. Technol., 2000, 72: 430
[9]	Schell W R. Invar tooling for composites, tooling for composites [R]. Long Beach, CA: Society of Manufacturing Engineers, 1989, TE89/503: 1
[10]	Durham S, Duquenne C.New developments in the manufacture of invar tooling for composite components [A]. Proceedings of the 71st Annual Forum[C]. Virginia Beach, Virginia: American Helicopter Society International, Inc., 2015: 1803
[11]	Xiong W, Zhang H, Vitos L, et al.Magnetic phase diagram of the Fe-Ni system[J]. Acta Mater., 2011, 59: 521
[12]	Zhang J M.Welding process optimization for Invar steel mold used in civil aircraft composite structures [D]. Harbin: Harbin Institute of Technology, 2013(张家铭. 民机复材结构用Invar钢模具焊接工艺优化研究 [D]. 哈尔滨: 哈尔滨工业大学, 2013)
[13]	Waeckerlé T.Low nickel content FCC alloys: Recent evolution and applications[J]. IEEE Trans. Magn., 2010, 46: 326
[14]	Yang B, Li H, Cao Z H.Application of Invar in mould for composites[J]. Fiber Reinf. Plast./Compos., 2010, (6): 68(杨博, 李宏, 曹正华. 殷钢在复合材料成形模具中的应用[J]. 玻璃钢/复合材料, 2010, (6): 68)
[15]	Vinogradov A, Hashimoto S, Kopylov V I.Enhanced strength and fatigue life of ultra-fine grain Fe-36Ni Invar alloy[J]. Mater. Sci. Eng., 2003, A355: 277
[16]	Huang G H, Zhang D M, Yan D X, et al.Manufacturing technology research on Invar steel mould[J]. Adv. Aeron. Sci. Eng., 2011, 2: 485(黄钢华, 张冬梅, 晏冬秀等. Invar钢模具制造工艺研究[J]. 航空工程进展, 2011, 2: 485)
[17]	Michler T.Influence of gaseous hydrogen on the tensile properties of Fe-36Ni INVAR alloy[J]. Int. J. Hydrogen Energy, 2014, 39: 11807
[18]	Nan J M, Li G X, Xu K W, et al.Elevated temperature deformation behaviour and mechanical characteristics of Invar alloy used for shadow mask[J]. J. Mater. Eng., 2001, 1(1): 19(南俊马, 李光新, 徐可为等. 显示器荫罩用因瓦合金的高温变形行为与力学特性[J]. 材料工程, 2001, 1(1): 19)
[19]	Yuan J P, Yi D Q, Yu Z M, et al.Influence of the deformation and heat treatment on the microstructures and properties of Invar alloy[J]. Heat Treat. Met., 2005, 30(2): 50(袁均平, 易丹青, 余志明等. 变形与热处理对Invar合金组织及性能的影响[J]. 金属热处理, 2005, 30(2): 50)
[20]	Liu H W, Sun Z H, Wang G K, et al.Effect of aging on microstructures and properties of Mo-alloyed Fe-36Ni invar alloy[J]. Mater. Sci. Eng., 2016, A654: 107
[21]	Guo X P, Kusabiraki K, Saji S.High-temperature scale formation of Fe-36% Ni bicrystals in air[J]. Oxid. Met., 2002, 58: 589
[22]	Yu Y C, Chen W Q, Zheng H G.High-temperature oxidation behavior and formation mechanism of rolling cracks of Fe-36Ni Invar alloy[J]. High Temp. Mater. Process., 2013, 32: 83
[23]	Yu Y C, Chen W Q, Zheng H G.Influence of heating conditions on the oxidation behavior of Fe-36Ni Invar alloy[J]. High Temp. Mater. Process., 2014, 33: 253
[24]	Yu Y C, Chen W Q, Zheng H G.Research on the hot ductility of Fe-36Ni Invar alloy[J]. Rare Met. Mater. Eng., 2014, 43: 2969
[25]	Li G H, Wang M J, Kang R K.Dynamic mechanical properties and constitutive model of Fe-36Ni invar alloy at high temperature and high strain rate[J]. Mater. Sci. Technol., 2010, 18: 824(李国和, 王敏杰, 康仁科. Fe-36Ni高温高应变率动态力学性能及其本构关系[J]. 材料科学与工艺, 2010, 18: 824)
[26]	Li G H, Cai Y J, Qi H J. Study on constitutive relationship of Fe-36Ni Invar alloy [J]. Adv. Mater. Res., 2011, 291-294: 1131

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