A novel way to reduce the critical deformation for cold roll bonding

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Original languageEnglish
Pages (from-to)9-12
Number of pages4
JournalManufacturing Letters
Volume36
Early online date13 Jan 2023
Publication statusPublished - Jul 2023

Abstract

In the present study, a novel approach is presented to achieve oxygen partial pressures corresponding to extremely high vacuum (XHV) to foster cold roll bonding. Cold roll bonding of Al/Al and Cu/Cu as well as the heterogeneous combination Al/Cu were investigated with a focus on the minimum degree of deformation required to form a solid bond. By applying XHV-adequate conditions, the minimum degree of deformation for the formation of a solid bond could be reduced by up to 35%. Furthermore, it was evident that the adhesion behaviour changed during bond formation in XHV-adequate conditions.

Keywords

    Aluminum, Cold roll bonding, Copper, Rolling, Silane

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A novel way to reduce the critical deformation for cold roll bonding. / Barienti, Khemais; Werwein, Stefan; Herbst, Sebastian et al.
In: Manufacturing Letters, Vol. 36, 07.2023, p. 9-12.

Research output: Contribution to journalArticleResearchpeer review

Barienti K, Werwein S, Herbst S, Maier HJ, Nürnberger F. A novel way to reduce the critical deformation for cold roll bonding. Manufacturing Letters. 2023 Jul;36:9-12. Epub 2023 Jan 13. doi: 10.1016/j.mfglet.2022.12.006
Barienti, Khemais ; Werwein, Stefan ; Herbst, Sebastian et al. / A novel way to reduce the critical deformation for cold roll bonding. In: Manufacturing Letters. 2023 ; Vol. 36. pp. 9-12.
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abstract = "In the present study, a novel approach is presented to achieve oxygen partial pressures corresponding to extremely high vacuum (XHV) to foster cold roll bonding. Cold roll bonding of Al/Al and Cu/Cu as well as the heterogeneous combination Al/Cu were investigated with a focus on the minimum degree of deformation required to form a solid bond. By applying XHV-adequate conditions, the minimum degree of deformation for the formation of a solid bond could be reduced by up to 35%. Furthermore, it was evident that the adhesion behaviour changed during bond formation in XHV-adequate conditions.",
keywords = "Aluminum, Cold roll bonding, Copper, Rolling, Silane",
author = "Khemais Barienti and Stefan Werwein and Sebastian Herbst and Maier, {Hans J{\"u}rgen} and Florian N{\"u}rnberger",
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Download

TY - JOUR

T1 - A novel way to reduce the critical deformation for cold roll bonding

AU - Barienti, Khemais

AU - Werwein, Stefan

AU - Herbst, Sebastian

AU - Maier, Hans Jürgen

AU - Nürnberger, Florian

N1 - Funding Information: This research was funded by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation)—Project-ID 394563137—SFB 1368.

PY - 2023/7

Y1 - 2023/7

N2 - In the present study, a novel approach is presented to achieve oxygen partial pressures corresponding to extremely high vacuum (XHV) to foster cold roll bonding. Cold roll bonding of Al/Al and Cu/Cu as well as the heterogeneous combination Al/Cu were investigated with a focus on the minimum degree of deformation required to form a solid bond. By applying XHV-adequate conditions, the minimum degree of deformation for the formation of a solid bond could be reduced by up to 35%. Furthermore, it was evident that the adhesion behaviour changed during bond formation in XHV-adequate conditions.

AB - In the present study, a novel approach is presented to achieve oxygen partial pressures corresponding to extremely high vacuum (XHV) to foster cold roll bonding. Cold roll bonding of Al/Al and Cu/Cu as well as the heterogeneous combination Al/Cu were investigated with a focus on the minimum degree of deformation required to form a solid bond. By applying XHV-adequate conditions, the minimum degree of deformation for the formation of a solid bond could be reduced by up to 35%. Furthermore, it was evident that the adhesion behaviour changed during bond formation in XHV-adequate conditions.

KW - Aluminum

KW - Cold roll bonding

KW - Copper

KW - Rolling

KW - Silane

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AN - SCOPUS:85146431269

VL - 36

SP - 9

EP - 12

JO - Manufacturing Letters

JF - Manufacturing Letters

SN - 2213-8463

ER -

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