New Developments and Future Trends in Low-Temperature Hot Stamping Technologies: A Review

Tong, Chenpeng; Rong, Qin; Yardley, Victoria A.; Li, Xuetao; Luo, Jiaming; Zhu, Guangming; Shi, Zhusheng

doi:10.3390/met10121652

Cited by 25 publications

(19 citation statements)

References 120 publications

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“…Consequently, this allows a more robust process control and, in addition, a significantly lower austenitization temperature. In comparison to manganese boron steels, the austenitization temperature of medium manganese steels can be lowered by 100-200 °C [15], which is associated with considerably reduced energy consumption [16]. Furthermore, the lower austenitization temperature leads to a comparatively finer microstructure, which positively influences both the strength and the ductility of the material, respectively [17].…”

Section: Introductionmentioning

confidence: 99%

Influence of Quenching and Partitioning Parameters on Phase Transformations and Mechanical Properties of Medium Manganese Steel for Press-Hardening Application

Blankart

Wesselmecking

Krupp

2021

Metals

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It has been proven that through targeted quenching and partitioning (Q & P), medium manganese steels can exhibit excellent mechanical properties combining very high strength and ductility. In order to apply the potential of these steels in industrial press hardening and to avoid high scrap rates, it is of utmost importance to determine a robust process window for Q & P. Hence, an intensive study of dilatometry experiments was carried out to identify the influence of quenching temperature (TQ) and partitioning time (tp) on phase transformations, phase stabilities, and the mechanical properties of a lean medium manganese steel. For this purpose, additional scanning electron microscopy (SEM), electron backscatter diffraction (EBSD), and energy dispersive X-ray spectroscopy (EDX) examinations as well as tensile testing were performed. Based on the dilatometry data, an adjustment of the Koistinen–Marburger (K-M) equation for medium manganese steel was developed. The results show that a retained austenite content of 12–21% in combination with a low-phase fraction of untempered secondary martensite (max. 20%) leads to excellent mechanical properties with a tensile strength higher than 1500 MPa and a total elongation of 18%, whereas an exceeding secondary martensite phase fraction results in brittle failure. The optimum retained austenite content was adjusted for TQ between 130 °C and 150 °C by means of an adapted partitioning.

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Section: Introductionmentioning

confidence: 99%

Influence of Quenching and Partitioning Parameters on Phase Transformations and Mechanical Properties of Medium Manganese Steel for Press-Hardening Application

Blankart

Wesselmecking

Krupp

2021

Metals

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“…The hot-stamping process considerably reduces the spring back of the products, differing from the cold-stamping process [120]. As the process suppresses the hydrogen embrittlement due to lowering the residual stress, hot-stamping steels such as DIN-22MnB5 and 30MnB5 steels are applied to automotive center pillars with the tensile strength of 1.5 to 1.8 GPa [120,122]. The matrix structure after die-quenching is almost martensite.…”

Section: Hot-and Warm-stampingmentioning

confidence: 99%

“…Recently, warm-stamping at temperatures above M s are developed to improve productivity and reduce manufacturing costs [122][123][124][125] (Figure 16). In the warm-stamping, the blank is austenitized at temperatures above Ac 3 , in the same way as the conventional hot-stamping process.…”

Section: Hot-and Warm-stampingmentioning

confidence: 99%

“…By this warm-stamping, the blank is strain-hardened along with the improvement of the drawability and formability. In addition, productivity can also be increased by shortening the cooling cycle time and decreasing the oxidation [122]. At present, the warm-stamping at 450 to 500 • C is applied to the B-pillar of (0.08-0.2)%C-(4.0-7.0)%Mn D-MMn steels, not M-MMn steel [125].…”

Section: Hot-and Warm-stampingmentioning

confidence: 99%

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Recent Progress of Low and Medium-Carbon Advanced Martensitic Steels

Sugimoto

2021

Metals

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This article introduces the microstructural and mechanical properties of low and medium-carbon advanced martensitic steels (AMSs) subjected to heat-treatment, hot- and warm- working, and/or case-hardening processes. The AMSs developed for sheet and wire rod products have a tensile strength higher than 1.5 GPa, good cold-formability, superior toughness and fatigue strength, and delayed fracture strength due to a mixture of martensite and retained austenite, compared with the conventional martensitic steels. In addition, the hot- and warm-stamping and forging contribute to enhance the mechanical properties of the AMSs due to grain refining and the improvement of retained austenite characteristics. The case-hardening process (fine particle peening and vacuum carburization) is effective to further increase the fatigue strength.

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“…In particular, the addition of Mn (3-10 wt.%) to the material decreases both the lower (Ae1) and upper (Ae3) temperatures of the austenite transformation under equilibrium conditions with respect to those of boron steels, allowing the blanks to be austenitised at lower temperatures. This enables the use of low-temperature hot stamping (LTHS), which is defined as a hot stamping process whereby full austenitisation is attained in the soaking stage while stamping takes place at a lower temperature than in the conventional case (Tong et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

Investigation of austenitising behaviour of medium-Mn steel in the hot-stamping heating process

Tong

Zhu

Rong

et al. 2021

Journal of Materials Processing Technology

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New Developments and Future Trends in Low-Temperature Hot Stamping Technologies: A Review

Cited by 25 publications

References 120 publications

Influence of Quenching and Partitioning Parameters on Phase Transformations and Mechanical Properties of Medium Manganese Steel for Press-Hardening Application

Influence of Quenching and Partitioning Parameters on Phase Transformations and Mechanical Properties of Medium Manganese Steel for Press-Hardening Application

Recent Progress of Low and Medium-Carbon Advanced Martensitic Steels

Investigation of austenitising behaviour of medium-Mn steel in the hot-stamping heating process

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