Preparation and Anti-Oxidation Mechanism of an Inventive Preprocessing Method for Press-Hardened Steels

doi:10.1007/s40195-025-01866-6

Abstract

Abstract:

Press hardening with manganese-boron steels is a prominent manufacturing technique that allows for reduced weight and expense in automotive construction, while providing enhanced crash performance. Nevertheless, the development of a loosely attached oxide layer during press hardening and following additional processing of the layer presents a significant risk to the dimensional precision of the completed product. Here, we develop a new preprocessing approach to address the scale spallation issue by introducing trace amounts of silicate and tungstate into the rinsing solution following pickling. We demonstrate that the pre-deposited membrane promotes the formation of a noticeably thinner, more continuous and stickier oxide scale at high temperatures, enabling the direct application of automobile painting onto the scale. Our research provides an economical remedy to the troublesome scale flaking issue without requiring any modifications to the existing production line, and conveys a thorough comprehension of the mechanism by which the preprocessed membrane resists high-temperature oxidation.

Key words: Press hardened steels, High temperature oxidation, Scale spallation, Inhibitor

Hongliang Liu, Jingpei Nie, Liwei Bai, Yujing Fu, Xiaoguang Yang, Zhen Chang, Xue Zhang, Ying Li. Preparation and Anti-Oxidation Mechanism of an Inventive Preprocessing Method for Press-Hardened Steels[J]. Acta Metallurgica Sinica (English Letters), 2025, 38(9): 1604-1612.

Figures/Tables 6

Fig. 1 EIS results of the steels subjected to preprocessing in solutions F1-F3: a-c Nyquist and Bode plots and corresponding equivalent circuit model for fitting the plots, d Rp values of the steels

Fig. 2 XPS wide-scan spectra a and narrow-scan spectra for b Si2p, c W4f and W5p, d Fe3/2p, e O1s of the steel subjected to pretreatment in solution F3 and f the corresponding atomic percent of elements as a function of sputtering depth

Fig. 3 Cross-sectional morphologies, relevant EDS analysis and corresponding average scale thicknesses of the preprocessed steels (F1-F3) following oxidation. F0 represents the oxidized bare reference devoid of preprocessing. The scale thickness of F0 was evaluated using a profilometer on the oxidized surface due to severe oxide spallation and associated difficulties in getting a cross section with detectable scale

Fig. 4 3D relief patterns and scratched morphologies of the oxidized steels without (F0) and without pretreatment (F1-F3)

Fig. 5 Snapshots of the structures following silicate and tungstate adsorption on the surface of Fe(110) and adsorption energy of the two structures within 1000 ps at 50 °C

Fig. 6 Phase diagram of the pretreated steel depicting oxygen partial pressure against W content at 950 °C. The Mn content in the system was set at 1.25 wt%, the Si content at 0.2 wt% and the W content was maximized at 10 wt%

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