Increasing the performance of hot forming parts by resistance heating in XHV-adequate atmosphere

Bernd-Arno Behrens; Sven Hübner; Ulrich Holländer; André Langohr; Alexander Schnettger; Jan-Ulrich Gellermann; Jörn Wehmeyer; Lorenz Franz Josef Albracht

doi:10.1051/matecconf/202540801025

Increasing the performance of hot forming parts by resistance heating in XHV-adequate atmosphere

Bernd-Arno Behrens (Mitwirkende*r), Sven Hübner (Mitwirkende*r), Ulrich Holländer (Mitwirkende*r), André Langohr (Mitwirkende*r), Alexander Schnettger, Jan-Ulrich Gellermann (Mitwirkende*r), Jörn Wehmeyer (Mitwirkende*r), Lorenz Franz Josef Albracht

Publikation: Beitrag in Buch/Bericht/Sammelwerk/Konferenzband › Aufsatz in Konferenzband › Forschung › Peer-Review

Abstract

In hot stamping, manganese-boron steel is heated above the austenitisation temperature and subsequently cooled at a rate of 27 K/s using a water-cooled process, resulting in lightweight components with ultra-high strength that enhance passenger safety, such as A- or B-pillars. Industrial heating takes place in roller hearth furnaces, where the sheet metal is heated up to 950 °C within 6 to 10 minutes and the AlSi coating bonds with the base material to protect it from scaling. Resistance heating is an alternative heating method. The direct current flow through the sheet enables heating rates of more than 100 K/s and heats the sheet in less than 10 seconds. This rapid heating also improves the mechanical properties by reducing the growth of coarse grains. However, the AlSi coating is not designed for such rapid heating, as there is not enough time for the diffusion layer to form. However, an XHV (extreme high vacuum)-adequate protective atmosphere with nitrogen and silane offers an alternative for scale-free heating without coatings. This process atmosphere binds oxygen, effectively preventing scale formation.

Originalsprache	Englisch
Titel des Sammelwerks	44th Conference of the International Deep Drawing Research Group (IDDRG 2025)
Seitenumfang	5
DOIs	https://doi.org/10.1051/matecconf/202540801025
Publikationsstatus	Veröffentlicht - 7 Mai 2025
Veranstaltung	44th Conference of the International Deep Drawing Research Group (IDDRG 2025) - Lisbon, Portugal Dauer: 1 Juni 2025 → 5 Juni 2025

Publikationsreihe

Name	MATEC web of conferences
Band	408
ISSN (elektronisch)	2261-236X

Konferenz

Konferenz	44th Conference of the International Deep Drawing Research Group (IDDRG 2025)
Kurztitel	IDDRG 2025
Land/Gebiet	Portugal
Ort	Lisbon
Zeitraum	1 Juni 2025 → 5 Juni 2025

Zugriff auf Dokument

10.1051/matecconf/202540801025Lizenz: CC BY 4.0

Dieses zitieren

Behrens, B.-A., Hübner, S., Holländer, U., Langohr, A., Schnettger, A., Gellermann, J.-U., Wehmeyer, J., & Albracht, L. F. J. (2025). Increasing the performance of hot forming parts by resistance heating in XHV-adequate atmosphere. in 44th Conference of the International Deep Drawing Research Group (IDDRG 2025) Artikel 01025 (MATEC web of conferences; Band 408). https://doi.org/10.1051/matecconf/202540801025

@inproceedings{7856fcfb086049d6a5d8770080f02143,

title = "Increasing the performance of hot forming parts by resistance heating in XHV-adequate atmosphere",

abstract = "In hot stamping, manganese-boron steel is heated above the austenitisation temperature and subsequently cooled at a rate of 27 K/s using a water-cooled process, resulting in lightweight components with ultra-high strength that enhance passenger safety, such as A- or B-pillars. Industrial heating takes place in roller hearth furnaces, where the sheet metal is heated up to 950 °C within 6 to 10 minutes and the AlSi coating bonds with the base material to protect it from scaling. Resistance heating is an alternative heating method. The direct current flow through the sheet enables heating rates of more than 100 K/s and heats the sheet in less than 10 seconds. This rapid heating also improves the mechanical properties by reducing the growth of coarse grains. However, the AlSi coating is not designed for such rapid heating, as there is not enough time for the diffusion layer to form. However, an XHV (extreme high vacuum)-adequate protective atmosphere with nitrogen and silane offers an alternative for scale-free heating without coatings. This process atmosphere binds oxygen, effectively preventing scale formation.",

author = "Bernd-Arno Behrens and Sven H{\"u}bner and Ulrich Holl{\"a}nder and Andr{\'e} Langohr and Alexander Schnettger and Jan-Ulrich Gellermann and J{\"o}rn Wehmeyer and Albracht, {Lorenz Franz Josef}",

year = "2025",

month = may,

day = "7",

doi = "10.1051/matecconf/202540801025",

language = "English",

series = "MATEC web of conferences",

booktitle = "44th Conference of the International Deep Drawing Research Group (IDDRG 2025)",

note = "44th Conference of the International Deep Drawing Research Group (IDDRG 2025), IDDRG 2025 ; Conference date: 01-06-2025 Through 05-06-2025",

}

Behrens, B-A, Hübner, S, Holländer, U, Langohr, A, Schnettger, A, Gellermann, J-U, Wehmeyer, J & Albracht, LFJ 2025, Increasing the performance of hot forming parts by resistance heating in XHV-adequate atmosphere. in 44th Conference of the International Deep Drawing Research Group (IDDRG 2025)., 01025, MATEC web of conferences, Bd. 408, 44th Conference of the International Deep Drawing Research Group (IDDRG 2025), Lisbon, Portugal, 1 Juni 2025. https://doi.org/10.1051/matecconf/202540801025

Increasing the performance of hot forming parts by resistance heating in XHV-adequate atmosphere. / Behrens, Bernd-Arno (Mitwirkende*r); Hübner, Sven (Mitwirkende*r); Holländer, Ulrich (Mitwirkende*r) et al.
44th Conference of the International Deep Drawing Research Group (IDDRG 2025). 2025. 01025 (MATEC web of conferences; Band 408).

Publikation: Beitrag in Buch/Bericht/Sammelwerk/Konferenzband › Aufsatz in Konferenzband › Forschung › Peer-Review

TY - GEN

T1 - Increasing the performance of hot forming parts by resistance heating in XHV-adequate atmosphere

AU - Schnettger, Alexander

AU - Albracht, Lorenz Franz Josef

A2 - Behrens, Bernd-Arno

A2 - Hübner, Sven

A2 - Holländer, Ulrich

A2 - Langohr, André

A2 - Gellermann, Jan-Ulrich

A2 - Wehmeyer, Jörn

PY - 2025/5/7

Y1 - 2025/5/7

N2 - In hot stamping, manganese-boron steel is heated above the austenitisation temperature and subsequently cooled at a rate of 27 K/s using a water-cooled process, resulting in lightweight components with ultra-high strength that enhance passenger safety, such as A- or B-pillars. Industrial heating takes place in roller hearth furnaces, where the sheet metal is heated up to 950 °C within 6 to 10 minutes and the AlSi coating bonds with the base material to protect it from scaling. Resistance heating is an alternative heating method. The direct current flow through the sheet enables heating rates of more than 100 K/s and heats the sheet in less than 10 seconds. This rapid heating also improves the mechanical properties by reducing the growth of coarse grains. However, the AlSi coating is not designed for such rapid heating, as there is not enough time for the diffusion layer to form. However, an XHV (extreme high vacuum)-adequate protective atmosphere with nitrogen and silane offers an alternative for scale-free heating without coatings. This process atmosphere binds oxygen, effectively preventing scale formation.

AB - In hot stamping, manganese-boron steel is heated above the austenitisation temperature and subsequently cooled at a rate of 27 K/s using a water-cooled process, resulting in lightweight components with ultra-high strength that enhance passenger safety, such as A- or B-pillars. Industrial heating takes place in roller hearth furnaces, where the sheet metal is heated up to 950 °C within 6 to 10 minutes and the AlSi coating bonds with the base material to protect it from scaling. Resistance heating is an alternative heating method. The direct current flow through the sheet enables heating rates of more than 100 K/s and heats the sheet in less than 10 seconds. This rapid heating also improves the mechanical properties by reducing the growth of coarse grains. However, the AlSi coating is not designed for such rapid heating, as there is not enough time for the diffusion layer to form. However, an XHV (extreme high vacuum)-adequate protective atmosphere with nitrogen and silane offers an alternative for scale-free heating without coatings. This process atmosphere binds oxygen, effectively preventing scale formation.

U2 - 10.1051/matecconf/202540801025

DO - 10.1051/matecconf/202540801025

M3 - Conference contribution

T3 - MATEC web of conferences

BT - 44th Conference of the International Deep Drawing Research Group (IDDRG 2025)

T2 - 44th Conference of the International Deep Drawing Research Group (IDDRG 2025)

Y2 - 1 June 2025 through 5 June 2025

ER -