Metal Polymer Connections: Laser-Induced Surface Enlargement Increases Joint Strength

Dominic Woitun; Michael Roderus; Thilo Bein; Elmar Kroner

doi:10.4028/www.scientific.net/KEM.809.190

Paper Titles

Evaluation of Ceramic Matrix Composite Edge and Surface Damage
p.161

Custom-Made Reinforcement Structures Made of Inorganic Fibers Challenges, Chances and Technical Approaches
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Influence of Initial Fibre Length and Content Used in the Injection Moulding of CFRP on the Properties of C/C and C/C-SiC Composites
p.171

One-Sided Resistance Spot Welding of Plastic-Metal Hybrid Joints - Characterization of the Joining Zone
p.183

Metal Polymer Connections: Laser-Induced Surface Enlargement Increases Joint Strength
p.190

Influence of Process Parameters, Surface Topography and Corrosion Condition on the Fatigue Behavior of Steel/Aluminum Hybrid Joints Produced by Magnetic Pulse Welding
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Sintered Connection - A Steel/CFRP Connection Module
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Thermoplastic Multi-Material Nonwovens from Recycled Carbon Fibres Using Wet-Laying Technology
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Influence of Welding Temperature and Weathering on Inductive Welded Hybrid Joints Made of Steel and TP-FRPC
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HomeKey Engineering MaterialsKey Engineering Materials Vol. 809Metal Polymer Connections: Laser-Induced Surface...

Metal Polymer Connections: Laser-Induced Surface Enlargement Increases Joint Strength

Abstract:

The trend towards hybrid materials consisting of metals and polymers is strongly driven by requirements such as weight reduction and improved functionality. A crucial step towards new hybrid materials is the advancement of joining technology. While metals and polymers are currently often joined using adhesives, this technology has major drawbacks such as long process cycle time, low robustness with regard to changes of the material composition, and are almost impossible to recycle, a point which is becoming increasingly important. A promising joining method is thermal direct joining of metals and thermoplastic polymers due to its fast cycle time, its robustness of the process and the absence of duroplastic adhesives. Direct joining requires surface treatment of the metallic joining partner prior to the thermal joining process to achieve a sufficiently high contact strength. It is known that laser-induced topologies on the metal surface are beneficial with regard to contact strength of the joints. Designing a joint based on laser structured metals requires a fundamental understanding of the interface interactions. The present paper focuses on the influence of surface enlargement on the joint strength. Laser pretreatment was utilized to generate surface structures with specific surface enlargement on the metallic joining partner. The pretreated metallic parts were subsequently joined with a thermoplastic polymer by injection molding. The joint strength was investigated in single lap shear tests. The key finding is that the contact strength increases almost linearly with the surface area within the tested parameter range, while the structure geometry parameters have only a minor influence. This may help as a design guideline for future adhesive-free hybrid material joining technologies.

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Periodical:

Key Engineering Materials (Volume 809)

Pages:

190-196

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.809.190

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Online since:

June 2019

Authors:

Dominic Woitun*, Michael Roderus, Thilo Bein, Elmar Kroner

Keywords:

Adhesion, Hybrid Joining, In-Mold Assembly, Laser Material Processing, Lightweight, Metal Polymer Connection, Metal Polymer Joints, Micro Structuring

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