For the design of new manufacturing methods for mechanical metamaterials in compact motion systems, a new bonding technique has been developed. The manufacturing technique requires thermoformed PEEK films to be bonded together. Literature review has shown that laser welding, and
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For the design of new manufacturing methods for mechanical metamaterials in compact motion systems, a new bonding technique has been developed. The manufacturing technique requires thermoformed PEEK films to be bonded together. Literature review has shown that laser welding, and specifically laser transmission welding, is a valuable method for this manufacturing technique, particularly for bonding materials that are tens of microns thick, such as thermoformed and PEEK films. This research demonstrates how to define a viable process and how to optimize laser parameters to achieve maximum joint strength and identifies factors that can diminish the quality of the bond, thereby affecting optimal speed.
Further investigation of the PEEK and absorptive coating spectral curves has revealed that absorption coating is effective in increasing the absorbance used in this research. Welding with an infrared laser around one µm wavelength can rapidly produce strong welds, where the tensile strength of the welds exceeds that of the material. A fluence of around 20 to 30 mJ/mm^2 results in optimal weld peel strengths.
The optimal parameters for 125 µm lap welding include a speed between 10 and 15 millimeters per second and a defocussing distance between 4 and 7 millimeters. The thickness of the welded films range from 25 to 125 microns. It has also been observed that thicknesses of 25 and 50 micrometers can produce welds with 125 thick thermoformed PEEK films, allowing for 2.5D film welding capabilities.