Strain rate sensitivity of ultra-high strength hot stamping steel

LIANG Jiang-tao; ZHAO Zheng-zhi; YIN Hong-xiang; LU Hong-zhou; CHEN Wei-jian; TANG Di

doi:10.13374/j.issn2095-9389.2018.09.009

Volume 40 Issue 9

Sep. 2018

Turn off MathJax

Article Contents

Article Navigation > Chinese Journal of Engineering > 2018 > 40(9): 1083-1090

LIANG Jiang-tao, ZHAO Zheng-zhi, YIN Hong-xiang, LU Hong-zhou, CHEN Wei-jian, TANG Di. Strain rate sensitivity of ultra-high strength hot stamping steel[J]. Chinese Journal of Engineering, 2018, 40(9): 1083-1090. doi: 10.13374/j.issn2095-9389.2018.09.009

Citation:

LIANG Jiang-tao, ZHAO Zheng-zhi, YIN Hong-xiang, LU Hong-zhou, CHEN Wei-jian, TANG Di. Strain rate sensitivity of ultra-high strength hot stamping steel[J]. Chinese Journal of Engineering, 2018, 40(9): 1083-1090. doi: 10.13374/j.issn2095-9389.2018.09.009

Citation:

PDF( 916 KB)

Strain rate sensitivity of ultra-high strength hot stamping steel

doi: 10.13374/j.issn2095-9389.2018.09.009

1) Collaborative Innovation Center of Steel Technology, University of Science and Technology Beijing, Beijing 100083, China
2) Metal and Chemistry Research Institute, China Academy of Railway Sciences, Beijing 100081, China
3) China International Trust and Investment Corporation Metal Co., Ltd, Beijing 100004, China

Received Date: 2017-10-09

Abstract

Abstract

The tensile test of an ultra-high strength hot stamping steel was tested using the CMT5105 electronic universal testing machine and HTM 16020 electro-hydraulic servo high-speed material testing machine. The impacts of the hot stamping parts were simulated at strain rates range of 10^-3-10³ s^-1. The results show that in the low strain rate (10^-3-10^-1 s^-1), the strain rate sensitivity of the tested steel is not very high, and the steel strength and elongation change little with an increase of strain rate. In the high strain rate stage (10⁰-10³ s^-1), the strain rate sensitivity of the steel is very high, and the steel strength and elongation increase with strain rate. The strain rate sensitivity of the tensile strength is higher than the yield strength mainly because of the adiabatic temperature rise phenomenon and the strain working phenomenon that simultaneously occur during the high strain rate stage. The elongation after necking decreases with an increase of strain rate, mainly because of the local inhomogeneous deformation of the martensite at the high strain rate. The impact energy absorption capacity of the experimental steel increases with strain rate, and is more sensitive at the uniform elongation. Compared with the low strain rate stage, the average fracture diameter of the dimple in the high strain rate stage is smaller, and its depth is deeper; this is related to the fragmentation of the martensite grains region in the high strain rate stage. Scanning elec-tron microscope and transmission electron microscope images reveal that the grains are elongated at high strain rate stage and some microvoids are present in the stress-concentrated regions. Moreover, the fragmentation phenomenon can be found in part of region at the 10³ s^-1 strain rate.
- ultra-high strength hot stamping steel,
- high strain rate tensile,
- strain hardening,
- dislocation pile-up,
- adiabatic temperature rise

FullText(HTML)

References(13)

References

[4]	Ramezani M, Ripin Z M. Combined experimental and numerical analysis of bulge test at high strain rates using split Hopkinson pressure bar apparatus. J Mater Process Technol, 2010, 210(8):1061
[5]	Singh N K, Cadoni E, Singha M K, et al. Dynamic tensile behavior of multi phase high yield strength steel. Mater Des, 2011, 32(10):5091
[6]	Kim J H, Kim D, Han H N, et al. Strain rate dependent tensile behavior of advanced high strength steels:experiment and constitutive modeling. Mater Sci Eng A, 2013, 559:222
[7]	Ulacia I, Salisbury C P, Hurtado I, et al. Tensile characterization and constitutive modeling of AZ31B magnesium alloy sheet over wide range of strain rates and temperatures. J Mater Process Technol, 2011, 211(5):830
[8]	Wang W R, Li M, He C W, et al. Experimental study on high strain rate behavior of high strength 600-1000 MPa dual phase steels and 1200 MPa fully martensitic steels. Mater Des, 2013, 47:510
[9]	Yu H D, Guo Y J, Lai X M. Rate-dependent behavior and constitutive model of DP600 steel at strain rate from 10^-4 to 10³ s^-1. Mater Des, 2009, 30(7):2501
[10]	Wei X C, Fu R Y, Li L. Tensile deformation behavior of coldrolled TRIP-aided steels over large range of strain rates. Mater Sci Eng A, 2007, 465(1-2):260
[12]	Feng F, Huang S Y, Meng Z H, et al. Experimental study on tensile property of AZ31B magnesium alloy at different high strain rates and temperatures. Mater Des, 2014, 57:10
[13]	Qin J G, Chen R, Wen X J, et al. Mechanical behaviour of dual-phase high-strength steel under high strain rate tensile loading. Mater Sci Eng A, 2013, 586:62
[14]	Liu Y, Dong D Y, Wang L, et al. Strain rate dependent deformation and failure behavior of laser weld DP780 steel joint under dynamic tensile loading. Mater Sci Eng A, 2015, 627:296
[15]	Dong D Y, Liu Y, Yang Y L, et al. Microstructure and dynamic tensile behavior of DP600 dual phase steel joint by laser welding. Mater Sci Eng A, 2014, 594:17
[16]	Kim S B, Huh H, Bok H H, et al. Forming limit diagram of auto-body steel sheets for high-speed sheet metal forming. J Mater Process Technol, 2011, 211(5):851
[17]	Wang M Q, Akiyama E, Tsuzaki K. Crosshead speed dependence of the notch tensile strength of a high strength steel in the presence of hydrogen. Scripta Mater, 2005, 53(6):713