Experimental Study of Laser Direct Joining of Metal and Carbon Fiber Reinforced Nylon

Chuang Huang; Xiao Wang; Yan Wei Wu; Dong Dong Meng; Hui Xia Liu

doi:10.4028/www.scientific.net/KEM.620.42

Paper Titles

Experimental Research on Laser Transmission Micro-Joining Based on the Mask
p.17

Molten Depth Modeling of Laser Transmission Welding Based on Temperature Distribution of Moving Point Heat Source
p.23

Numerical Investigation on Laser-Assisted Flow Forming Process
p.29

Impact Analysis of the Force Environment on the KDP Crystal Harmonic Loss Considering the Frame Surface Topography
p.35

Experimental Study of Laser Direct Joining of Metal and Carbon Fiber Reinforced Nylon
p.42

Study of Form Control Algorithm in Atmospheric Pressure Plasma Processing
p.49

Influence of Cracking Damage on Deflection Basin Test Data of FWD
p.55

Molecular Dynamics Simulation of Surface Effect on Tensile Deformation of Single Crystalline Copper
p.61

Mechanical Properties Comparison of Different La Content in AZ91
p.67

HomeKey Engineering MaterialsKey Engineering Materials Vol. 620Experimental Study of Laser Direct Joining of...

Experimental Study of Laser Direct Joining of Metal and Carbon Fiber Reinforced Nylon

Abstract:

This paper presents an experimental study to evaluate the feasibility, characteristics and mechanism of laser direct joining between metal and carbon fiber reinforced plastic (PA66CF20). This study presents a method to improve the joint strength of the metal-polymer hybrid joint. The investigation study effects of process parameters (laser power and travelling speed) on the quality of joining joint. Macroscopic morphology of joint and PA66CF20 melting region closed to the interface were observed in this study. XPS analysis shows that Ti-C and Ti-O chemical bonding were produced between titanium alloy and plastic. Cross-sectional photo showed the melted polymer flowed into micro-cavity of metal surface caused by roughness of metal and thus formed mechanical bonding. Finally, the titanium alloy surface was structured in four different surface textures using a pulsed laser. Then the metal was joined with the plastic. The result shows that the joint strength of metal after laser-structured joining with plastic had been improved greatly.

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Periodical:

Key Engineering Materials (Volume 620)

Pages:

42-48

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.620.42

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Online since:

August 2014

Authors:

Chuang Huang, Xiao Wang, Yan Wei Wu, Dong Dong Meng, Hui Xia Liu

Keywords:

CFRP, Joining Mechanism, Laser Direct Joining, Laser Structuring, Metal

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