New Die Concept for Self-Pierce Riveting Materials with Limited Ductility

Welf Guntram Drossel; Mathias Jäckel

doi:10.4028/www.scientific.net/KEM.611-612.1452

Paper Titles

Friction Stir Lap Welding of Aluminium Alloys
p.1421

Influence of the Process Temperature on the Properties of Friction Stir Welded Blanks Made of Mild Steel and Aluminum
p.1429

Unerring Planning of Clinching Processes through the Use of Mathematical Methods
p.1437

Friction Stir Welding of Aluminum Metal Matrix Composite Containers for Electric Components
p.1445

New Die Concept for Self-Pierce Riveting Materials with Limited Ductility
p.1452

Galvanic Corrosion Related to Steel/Aluminum Dissimilar Joining Tailored Blank
p.1460

A New Process Chain for Joining Sheet Metal to Fibre Composite Sheets
p.1468

Ti 6Al-4V FSW Weldability: Mechanical Characterization and Fatigue Life Analysis
p.1476

Effect of Cold Plasma Treatment on Surface Roughness and Bonding Strength of Polymeric Substrates
p.1484

HomeKey Engineering MaterialsKey Engineering Materials Vols. 611-612New Die Concept for Self-Pierce Riveting Materials...

New Die Concept for Self-Pierce Riveting Materials with Limited Ductility

Abstract:

Lightweight materials, such as aluminum die castings, are used more and more for automotive applications. Due to the limited weldability, joining these materials by self-pierce riveting has been established. The challenge in this regard is that these materials, especially new high strength aluminum die castings, have a limited ductility, while the joining processes locally induce large plastic deformations. Consequently, joining by forming of these materials can be accompanied by cracks, which develop during the forming operation. This paper shows the experimental and numerical investigation of a new die concept for self-pierce riveting materials with limited ductility. At the new tool concept the riveting die is separated and a movable die element is used. This element allows that the parts are superimposed with compressive stresses during the self-pierce riveting process. In the paper it can be shown, that in contrast to the conventional process crack-free joints can be generated by using the new tool concept. Determination of the joining parameters and the die design was supported by simulative investigations. Additionally, the new and the conventional self-pierce riveting process are compared on the basis of results from the experimental investigations.

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Periodical:

Key Engineering Materials (Volumes 611-612)

Pages:

1452-1459

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.611-612.1452

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Online since:

May 2014

Authors:

Welf Guntram Drossel, Mathias Jäckel*

Keywords:

Lightweight Materials, Mechanical Joining, Self-Pierce Riveting

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* - Corresponding Author

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