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Lecture

Weldable Metallic Joining Elements in Fibre Reinforced Thermoplastics

Thursday (09.11.2017)
15:00 - 15:20
Part of:


Structural components made of fibre reinforced plastics (FRP) exhibit a high lightweight potential due to the high strength and low density. For serial applications like in the automotive sector, thermoplastic matrices are highly demanded, because already existing forming technologies enable economical processing and short clock cycles. Many concept cars of OEMs show the strategy to substitute single metallic components or subassemblies by FRPs in areas with the highest lightweight- and cost potential. The advantage of this multi material design (MMD) is to use the locally optimized materials with the required properties and low costs. A vital challenge of the MMD is the requirement of suitable technologies for joining different types of materials like metal and FRP with regard to the performance and large-scale production. Conventional joining techniques like rivets, FDS-screws, adhesives or ultrasonic joining may harm the FRP component or require a high manufacturing effort and quality assurance. Furthermore, modifications of the installed state of the art spot welding production lines are necessary.

The aim of the project is to avoid such investments in new production lines by using spot welding as joining technology between FRP and metals. Therefore, the FRP need to be enabled for spot welding by application of so called welding patches. These welding patches consist of a metal component and a FRP component, which are combined and consolidated during the thermoforming. This article describes the mechanical design, numerical simulation of spot weldable organic sheets – components equipped with so called welding patches – and the production process.

 

Speaker:
Arne Kunze
Leibniz Institute for Materials Engineering - IWT
Additional Authors:
  • Dr. Axel von Hehl
    IWT - Stiftung Institut für Werkstofftechnik
  • Prof. Hans-Werner Zoch
    IWT - Stiftung Institut für Werkstofftechnik