热冲压过程中冷速对高强塑积硼钢性能的影响<sup>*</sup>

doi:10.11901/1005.3093.2013.378

材料研究学报

2014, Vol. 28

Issue (2): 88-92 DOI: 10.11901/1005.3093.2013.378

本期目录 | 过刊浏览

热冲压过程中冷速对高强塑积硼钢性能的影响^*

林涛¹,宋鸿武¹,张士宏¹(

),程明¹,刘伟杰²

1. 中国科学院金属研究所沈阳 110016
2. 东北大学研究生院沈阳 110819

Effect of Cooling Rate During Hot Punching on Property of High-performance 22MnB5 Steel Parts

Tao LIN¹,Hongwu SONG¹,Shihong ZHANG^1,^**(

),Ming CHEN¹,Weijie LIU²

1. Institute of Metal Research Chinese Academy of Sciences, Shengyang, 110016
2. Graduate School of Northeastern University, Shenyang, 110819

引用本文:

林涛,宋鸿武,张士宏,程明,刘伟杰. 热冲压过程中冷速对高强塑积硼钢性能的影响^*[J]. 材料研究学报, 2014, 28(2): 88-92.
Tao LIN, Hongwu SONG, Shihong ZHANG, Ming CHEN, Weijie LIU. Effect of Cooling Rate During Hot Punching on Property of High-performance 22MnB5 Steel Parts[J]. Chinese Journal of Materials Research, 2014, 28(2): 88-92.

全文: PDF(4848 KB) HTML

摘要:

通过对比通有保护气、无保护气、仿工业化热冲压的热冲压件的性能, 研究了热冲压过程中冷速对硼钢22MnB5组织性能的影响规律。结果表明, 在三种工艺条件下实验件的冷却速度均大于马氏转变的临界冷却速度, 组织均为板条状马氏体, 抗拉强度在1500 MPa以上。冲压模具的温度升高, 板料表面存在氧化皮, 都会使板料的冷却速度减小, 马氏体片层变粗, 性能下降。通过降低模具温度, 增加板料加热时的起保护, 可使得板料冷速增加, 马氏体组织细小, 获得强度为1600 MPa以上, 强塑积接近20, 000 MPa％的热冲压硼钢件。

关键词 ：金属材料, 热冲压, 气体保护, 冷却速度, 强塑积

Abstract：

The effect of cooling rate during punching process on the microstructure and mechanical property of the 22MnB steel was investigated by three different processing conditions i.e. the processes with and without argon protection as well as a simulated industrial process. The results show that the cooling rates of all the hot punched parts with the three different processing conditions are higher than the critical cooling rate of 22MnB5 steel, thus the hot punched steels with a microstructure of lath martensite exhibit tensile stresses higher than 1500 MPa. When the temperature of hot punch tools is higher, an oxide scale appeared on the punched workpiece surface, thereby, the cooling rate and the mechanical property of the steel become lower, and the martensitic plate becomes thicker. The hot punched part with tensile strength about 1600 MPa and strength multiplied ductility c.a. 20, 000 MPa% was available by heating with argon protection while reducing the initial temperature of punch tools to ambient temperature. This is because the cooling rate of the punched part was high and thereby the martensite plates of the steel became fine for the process with protective gas.

Key words： metallic materials hot punching gas-protection cooling rate strength multiplied ductility

收稿日期: 2013-06-04

基金资助:* 国家自然科学基金51034009 项目资助。

作者简介:

本文联系人: 张士宏, 研究员

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https://www.cjmr.org/CN/10.11901/1005.3093.2013.378 或 https://www.cjmr.org/CN/Y2014/V28/I2/88

表1 实验钢22MnB5化学成分

Fig.1 板料的组织和尺寸

图2 热冲压实验设备

表2 三种工艺的参数

图3 冲压后的板料与拉伸试样尺寸(mm)

图4 三种工艺冲板的温度历程曲线

图5 冲压件的力学性能

图6 三种工艺热冲件的组织

图7 用通保护气热冲压(工艺1(a))与未通保护气热冲压(工艺2(b))试制的盒型件

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