锻压技术

非等温模具对2024铝合金弯曲回弹和残余应力的影响

英文标题：Influence of non-isothermal dies on bending springback and residual stress for aluminum alloy 2024

作者：夏良俊邓磊金俊松王新云

单位：华中科技大学

关键词：2024铝合金非等温模具 V型弯曲回弹残余应力

分类号：TG389

出版年,卷(期):页码：2016,41(9):92-95

摘要：

主要研究了2024铝合金在差温模具下弯曲成形时回弹和残余应力的变化规律。实验中选取板坯温度为25 ℃

室温，凸模和凹模温度分别选取25，200，300和400 ℃共16组温度组合进行V型弯曲；然后进行板坯、凸模

和凹模均为200 ℃的等温弯曲，并与差温弯曲进行对比分析。研究结果表明：分别提高凸模和凹模的温度均

能够减小回弹角和残余应力；在成形结束后，当差温弯曲板坯和等温弯曲板坯开始回弹前的温度相接近时，

由于温度梯度和贴模后温升的影响，差温弯曲件的回弹角和内、外表面残余应力及其差值能够达到与等温弯

曲数值相近或更小的效果；通过合理控制凸、凹模温度能够使室温板坯获得与高温等温成形时同样较小的回

弹和残余应力。

The regulations of springback and residual stress in non-isothermal dies bending process of

aluminum alloy 2024 were researched. The V-shape bending tests were conducted that the blank

was set at 25 ℃(room temperature), and the punch and the die were set at 25 ℃, 200 ℃, 300

℃, 400 ℃ respectively. Then the isothermal bending of blank and die at 200 ℃ was conducted

to compare with the non-isothermal bending. The results show that the springback and residual

stress decrease when the punch and die temperatures rise. When the blank temperatures of non-

isothermal bending after processing before springback is close to that of isothermal bending,

the springback and the residual stress of inner and outer layers and their difference with

non-isothermal bending are close to the value with isothermal bending or even less due to the

temperature gradient during processing and the influence of the temperature rise after

hydroforming. By controlling the temperature of punch and die properly, the springback and

residual stress of blank with room temperature are as small as those of the high temperature

isothermal bending.

基金项目：

国家自然科学基金资助项目（51205143）

夏良俊（1987-），男，硕士王新云（1973-），男，博士，教授

参考文献：

［1］马鸣图，易红亮，路洪洲，等. 论汽车轻量化[J].中国工程科学，2009，11(9): 20-27.

Ma M T, Yi H L, Lu H Z, et al. On the light weighting of automobile[J]. Engineering

Sciences, 2009，11(9)：20-27.

［2］苑世剑，何祝斌，刘钢. 轻合金热态液力成形技术[J]. 锻压技术, 2005，30(6): 75-80.

Yuan S J, He Z B, Liu G. Warm hydroforming process of lightweight alloys[J]. Forging &

Stamping Technology, 2005，30(6): 75-80.

［3］ Hadley S W, Das S, Miller J W. Aluminum R & D for automotive uses and the department

of energys role[R]. USA:Oak Ridge National Laboratory, 2000.

［4］郭玉琴，朱新峰，杨艳，等. 汽车轻量化材料及制造工艺研究现状[J]. 锻压技术，2015， 40

(3): 1-6.

Guo Y Q, Zhu X F, Yang Y, et al. Research state of lightweight material and manufacture

processes in automotive industry[J]. Forging & Stamping Technology，2015，40(3): 1-6.

［5］侯英玮, 王莹. 5083铝合金弯曲性能的试验研究[J]. 大连交通大学学报，2012，33(1): 65-68.

Hou Y W, Wang Y. Bending properties of 5083 aluminum alloy[J]. Journal of Dalian Jiaotong

University， 2012，33(1): 65-68.

［6］ Ho K C, Lin J, Dean T A. Modelling of springback in creep forming thick aluminum

sheets[J]. International Journal of Plasticity，2004, 20(4): 733-751.

［7］刘志文, 李落星, 肖罡，等.热处理状态和工艺顺序对铝型材弯曲回弹的影响[J]. 湖南大学学报

:自然科学版，2014, 41(7): 23-29.

Liu Z W, Li L X, Xiao G, et al, Influence of heat-treated condition and process sequences on

the springback of aluminum bent profiles[J]. Journal of Hunan University:Natural Science，

2014, 41(7): 23-29.

［8］黎俊初, 李明华, 刘大海. 电场固溶处理对2A12铝合金时效成形的影响[J]. 锻压技术，

2015,40(6): 102-107,115.

Li J C, Li M H, Liu D H. Influences of solution treatment in an electric field on creep age

forming of 2A12 aluminum alloy sheets[J]. Forging & Stamping Technology, 2015,40(6): 102-

107,115.

［9］王巍, 刘春, 李东升. 2024铝合金筒形件拉深成形试验与有限元仿真[J]. 锻压技术, 2014,39

(11): 1-6.

Wang W, Liu C, Li D S. Cylindrical deep drawing test and finite element simulation of 2024

aluminum alloy sheet[J]. Forging & Stamping Technology, 2014,39(11): 1-6.

［10］Moon Y H, Kang S S, Cho J R, et al. Effect of tool temperature on the reduction of the

springback of aluminum sheets[J]. Journal of Materials Processing Technology, 2003, 132(1):

365-368.

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