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吉林大学学报(工学版) 2014

高强度热成形钢板冷却速率-强度-硬度预测

, PP. 1716-1722

盈亮, 戴明华, 胡平, 范正帅, 申国哲, 史栋勇

Keywords: 金属材料,分区冷却,强度-硬度指数模型,量纲反推法,数值仿真

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Abstract:

基于高强度钢板热成形平板模具分区冷却试验获得了淬火过程阶段冷却速度对机械强度-硬度的影响规律。采用量纲分析法建立了热成形材料冷却速率-机械强度-硬度指数模型,并验证了该模型的有效性。通过编制用户子程序将该模型引入自主开发的KMAS_HF软件平台中,实现了对典型U形热成形产品淬火后强度硬度的数值仿真预测。结果表明:该模型对热成形高强度钢淬火后机械性能仿真预测具有较好的适用性,为实现梯度硬度复合热成形工艺优化及产品性能分析提供了一种新的仿真分析流程。

References

[1]	Karbasian H, Tekkaya A E. A review on hot stamping[J]. Journal of Materials Processing Technology, 2010,210(15):2103-2118.
[2]	朱敏,姬琳,叶辉. 考虑侧碰的汽车B柱加强板材料性能梯度优化[J]. 吉林大学学报:工学版,2011,41(5):1210-1215. Zhu Min, Ji Lin,Ye Hui. Optimization of yield stress distribution on in B pillar reinforcement panel regarding side crash worthines[J]. Journal of Jilin University (Engineering and Technology Edition), 2011,41(5): 1210-1215.
[3]	Naderi M, Ketabchi M, Abbasi M, et al. Semi-hot stamping as an improved process of hot stamping[J]. Journal of Materials Science & Technology,2011,27(4):369-376.
[4]	Mun D J, Shin E J, Choi Y W, et al. Effects of cooling rate, austenitizing temperature and austenite deformation on the transformation behavior of high-strength boron steel[J]. Materials Science and Engineering A,2012,545: 214-224.
[5]	Cui Jun-jia, Lei Cheng-xi, Xing Zhong-wen, et al. Microstructure distribution and mechanical properties prediction of boron alloy during hot forming using FE simulation[J] Materials Science and Engineering A, 2012,535:241-251.
[6]	Li M V, Niebuhr D V, Meekisho L L, et al. A computational model for the prediction of steel hardenability[J]. Metallurgical and Materials Transactions B: Process Metallurgy and Materials Processing Science,1998,29(3):661-672.
[7]	Bok H H, Lee M G, Pavlina E J, et al. Comparative study of the prediction of microstructure and mechanical properties for a hot-stamped B-pillar reinforcing part[J]. International Journal of Mechanical Sciences, 2011,53(9):744-752.
[8]	Bardelcik A, Salisbury C P, Winkler S,et al. Effect of cooling rate on the high strain rate properties of boron steel[J]. International Journal of Impact Engineering, 2010,37(6):694-702.
[9]	Nishibata T, Kojima N. Effect of quenching rate on hardness and microstructure of hot-stamped steel[J]. Tetsu-To-Hagane/Journal of the Iron and Steel Institute of Japan,2010,96(6):378-385.
[10]	Naderi M, Saeed-Akbari A, Bleck W. The effects of non-isothermal deformation on martensitic transformation in 22MnB5 steel[J]. Materials Science and Engineering A,2008,487(1-2):445-455.
[11]	谈庆明. 量纲分析[M]. 合肥:中国科学技术大学出版社,2005.
[12]	Bhaskar R, Nigam A. Qualitative physics using dimensional analysis[J]. Artificial Intelligence, 1990, 45(1-2):73-111.
[13]	马增胜. 纳米压痕法表征金属薄膜材料的力学性能[D]. 湘潭:湘潭大学材料与光电物理学院,2011. Ma Zeng-sheng. Characterization of the mechanical properties of metallic films by nanoindentation method[D]. Xiangtan: Faculty of Materials,Optoelectronics and Physics, Xiangtan University, 2011.
[14]	Hora P, Roll K, Volk W,et al. Nunmisheet 2008[DB/OL].[2013-02-05]. http://wenku.baidu.com/link?url=SbLuE5QWYXt6ggJXIRGT-XIGY3y1XlZCwS0VpxFt_KIVLrTFTRQ2knmpZwcf79Tm_lyOsShgfzJRCs4VFhZKQRbhbn-2-p0TdnP44AqS2kC.
[15]	Turetta A, Bruschi S, Ghiotti A. Investigation of 22MnB5 formability in hot stamping operations[J]. Journal of Materials Processing Technology,2006,177(1-3): 396-400.

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