PBT–anodized aluminum alloy direct joining: Characteristic injection speed dependence of injected polymer replicated into nanostructures

Roughened metal pieces and polymer can be joined via typical injection molding. We formed nanopores on the aluminum alloy surface by anodization and joined the alloy with polybutylene terephthalate. Tensile tests indicated the anodized metal and polymer joined with a shear strength of over 20 MPa. S...

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Bibliographic Details
Published in:Polymer testing 2019-05, Vol.75, p.127-132
Main Authors: Kadoya, Shotaro, Kimura, Fuminobu, Kajihara, Yusuke
Format: Article
Language:English
Subjects:
Anodization
Direct joining
Injection molding
Polymer replication
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Summary:Roughened metal pieces and polymer can be joined via typical injection molding. We formed nanopores on the aluminum alloy surface by anodization and joined the alloy with polybutylene terephthalate. Tensile tests indicated the anodized metal and polymer joined with a shear strength of over 20 MPa. STEM-EDS analysis showed the polymer was replicated into the nanopores. We revealed the injection speed and joint strength have a negative correlation, which may result from the breaking of the nanopores. Additionally, measurement results for the polymer temperature indicated the local thermal decomposition could weaken the joint, especially in nanostructures. The joint strength dependence on the injection speed in anodic pores was similar to that of the NMT method. However, the characteristic correlation between the pack pressure and joint strength at high injection speeds has not been found for other surface treatments. These results provide insight into the behavior of injected polymers in nanostructures. •PBT and anodized aluminum alloy, on which nano pores formed, were joined by injection molded direct joining method.•STEM-EDS analysis indicated that polymer infiltrated into nano pores and the aspect ratio of infiltrating polymer was approximately one.•The joint shear strength decreased when the injection speed increased.•The cavity pressure had negative effect on joint strength at high injection speeds.•Measured results of polymer temperature and fracture surfaces implied that thermal local decomposition of polymer could cause low joint strength.
ISSN:0142-9418
1873-2348
DOI:10.1016/j.polymertesting.2019.02.006