Bending behavior of zinc-coated hot stamping steels

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Bending behavior of zinc-coated hot stamping steels. / Hofer, Christina; Stadler, Manfred; Kurz, Thomas et al.
in: Steel research international, Jahrgang 92, Nr. 10, 2100149, 10.2021, S. 1-9.

Publikationen: Beitrag in FachzeitschriftArtikelForschung(peer-reviewed)

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Hofer C, Stadler M, Kurz T, Maier-Kiener V, Mayerhofer A, Hebesberger T et al. Bending behavior of zinc-coated hot stamping steels. Steel research international. 2021 Okt;92(10):1-9. 2100149. doi: 10.1002/srin.202100149

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@article{544289438db740bba7a770f63ba933df,
title = "Bending behavior of zinc-coated hot stamping steels",
abstract = "In the automotive industry, ultrahigh strength steels allow downgauging while, at the same time, passenger safety is increased. To expand the application fields of martensitic steels, which are frequently produced via hot stamping, cathodic corrosion protection is required. To date, zinc-coated components are mainly processed via the detour of cold forming, but a precooling step to solidify all zinc phases prior to hot stamping shows great potential to overcome this limitation. Therefore, herein, directly quenched 22MnB5 is compared with an adapted alloy (20MnB8) after quenching with a precooling step. Bendability is used to assess the crash performance. In addition to the damage evolution, investigated via interrupted bending tests, a detailed microstructural analysis of the near-surface region with respect to grain size, decaburization, inclusions, and other second phases is carried out. While 22MnB5 shows a fully martensitic microstructure, individual ferrite grains are observed within the martensitic matrix in the near-surface region of 20MnB8. Carbon redistribution from ferrite to the surrounding martensite entails large hardness differences between the constituents as determined by nanoindentation, resulting in an earlier onset of strain localization and, therefore, decreased local formability.",
keywords = "bendability, ferrite islands, hot stamping, inclusion analyses, nanoindentation, zinc-coated steels",
author = "Christina Hofer and Manfred Stadler and Thomas Kurz and Verena Maier-Kiener and Alexander Mayerhofer and Thomas Hebesberger and Ronald Schnitzer",
note = "Publisher Copyright: {\textcopyright} 2021 The Authors. Steel Research International published by Wiley-VCH GmbH",
year = "2021",
month = oct,
doi = "10.1002/srin.202100149",
language = "English",
volume = "92",
pages = "1--9",
journal = "Steel research international",
issn = "0177-4832",
publisher = "Verlag Stahleisen GmbH",
number = "10",

}

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TY - JOUR

T1 - Bending behavior of zinc-coated hot stamping steels

AU - Hofer, Christina

AU - Stadler, Manfred

AU - Kurz, Thomas

AU - Maier-Kiener, Verena

AU - Mayerhofer, Alexander

AU - Hebesberger, Thomas

AU - Schnitzer, Ronald

N1 - Publisher Copyright: © 2021 The Authors. Steel Research International published by Wiley-VCH GmbH

PY - 2021/10

Y1 - 2021/10

N2 - In the automotive industry, ultrahigh strength steels allow downgauging while, at the same time, passenger safety is increased. To expand the application fields of martensitic steels, which are frequently produced via hot stamping, cathodic corrosion protection is required. To date, zinc-coated components are mainly processed via the detour of cold forming, but a precooling step to solidify all zinc phases prior to hot stamping shows great potential to overcome this limitation. Therefore, herein, directly quenched 22MnB5 is compared with an adapted alloy (20MnB8) after quenching with a precooling step. Bendability is used to assess the crash performance. In addition to the damage evolution, investigated via interrupted bending tests, a detailed microstructural analysis of the near-surface region with respect to grain size, decaburization, inclusions, and other second phases is carried out. While 22MnB5 shows a fully martensitic microstructure, individual ferrite grains are observed within the martensitic matrix in the near-surface region of 20MnB8. Carbon redistribution from ferrite to the surrounding martensite entails large hardness differences between the constituents as determined by nanoindentation, resulting in an earlier onset of strain localization and, therefore, decreased local formability.

AB - In the automotive industry, ultrahigh strength steels allow downgauging while, at the same time, passenger safety is increased. To expand the application fields of martensitic steels, which are frequently produced via hot stamping, cathodic corrosion protection is required. To date, zinc-coated components are mainly processed via the detour of cold forming, but a precooling step to solidify all zinc phases prior to hot stamping shows great potential to overcome this limitation. Therefore, herein, directly quenched 22MnB5 is compared with an adapted alloy (20MnB8) after quenching with a precooling step. Bendability is used to assess the crash performance. In addition to the damage evolution, investigated via interrupted bending tests, a detailed microstructural analysis of the near-surface region with respect to grain size, decaburization, inclusions, and other second phases is carried out. While 22MnB5 shows a fully martensitic microstructure, individual ferrite grains are observed within the martensitic matrix in the near-surface region of 20MnB8. Carbon redistribution from ferrite to the surrounding martensite entails large hardness differences between the constituents as determined by nanoindentation, resulting in an earlier onset of strain localization and, therefore, decreased local formability.

KW - bendability

KW - ferrite islands

KW - hot stamping

KW - inclusion analyses

KW - nanoindentation

KW - zinc-coated steels

UR - http://www.scopus.com/inward/record.url?scp=85108810078&partnerID=8YFLogxK

U2 - 10.1002/srin.202100149

DO - 10.1002/srin.202100149

M3 - Article

VL - 92

SP - 1

EP - 9

JO - Steel research international

JF - Steel research international

SN - 0177-4832

IS - 10

M1 - 2100149

ER -