Influence of processing parameters on joint shear performance in laser direct joining of CFRTP and aluminum alloy

Influence of processing parameters on joint shear performance in laser direct joining of CFRTP and aluminum alloy

[Display omitted] •A process optimization method for laser direct joining is proposed.•The melting depth and peak temperatures are the constraints for process optimization.•The method can reduce the adverse impact of thermal defects and obtain better joints. Laser direct joining of a carbon fiber re...

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Bibliographic Details
Published in:Materials & design Vol. 209; p. 109996
Main Authors: Wang, Qi, Jia, Zhen-yuan, Zhang, Bo-yu, Gao, Dun-lin, Ma, Yu, Liu, Jing-yuan
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-11-2021
Elsevier
Subjects:
CFRTP/alloy stacks
Laser direct joining
Local peak temperature
Melting depth
Process optimization
CFRTP/alloy stacks
Process optimization
Local peak temperature
Laser direct joining
Melting depth
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Summary:[Display omitted] •A process optimization method for laser direct joining is proposed.•The melting depth and peak temperatures are the constraints for process optimization.•The method can reduce the adverse impact of thermal defects and obtain better joints. Laser direct joining of a carbon fiber reinforced thermoplastic (CFRTP) and an alloy is prone to thermal defects, thereby reducing the joint performance. This can be avoided by reasonably controlling the joining temperature. To this end, a process optimization method characterized by taking full control of the melting depth and local peak temperature is proposed for representative CFRTP/Al and CFRTP/polymer/Al stacks. For the first time, a temperature simulation model considering the heat transfer during the laser direct joining of heterogeneous CFRTP/alloy stacks is established; the average calculation error of the model is <10%. Based on the simulation results, regression models of the melting depth and local peak temperature are established. Subsequently, constraints are determined by defect distribution observation and joint fracture surface analysis; thus, the optimized ranges of the process parameters are obtained. Finally, through laser direct joining experiments, the improvement in the joint performance is demonstrated and analyzed. The results suggest an enhancement in the strength of the aforementioned stacks under the optimized process, thus proving the rationality of the proposed method by controlling the melting depth and local peak temperature, particularly for CFRTP/polymer/Al stacks with strength close to 30 MPa.
ISSN:0264-1275
1873-4197
DOI:10.1016/j.matdes.2021.109996