A Response Surface Methodology Approach to Improve Adhesive Bonding of Pulsed Laser Treated CFRP Composites

In this work, a response surface-designed experiment approach was used to determine the optimal settings of laser treatment as a method of surface preparation for CFRP prior to bonding. A nanosecond pulsed Ytterbium-doped-fiber laser source was used in combination with a scanning system. A Face-centered Central Composite Design was used to model the tensile shear strength (TSS) of adhesive bonded joints and investigate the effects of varying three parameters, namely, power, pitch, and lateral overlap. The analysis was carried out considering different focal distances. For each set of joints, shear strength values were modeled using Response Surface Methodology (RSM) to identify the set-up parameters that gave the best performance, determining any equivalent conditions from a statistical point of view. The regression models also allow the prediction of the behavior of the joints for not experimentally tested parameter settings, within the operating domain of investigation. This aspect is particularly important in consideration of the process optimization of the manufacturing cycle since it allows the maximization of joint efficiency by limiting the energy consumption for treatment.

Automated summary

This study used a response surface-designed experiment approach to determine the optimal settings of laser treatment for surface preparation of CFRP prior to bonding. The effects of power, pitch, and lateral overlap on the tensile shear strength of adhesive bonded joints were investigated using a nanosecond pulsed Ytterbium-doped-fiber laser source and a scanning system. The results were modeled using Response Surface Methodology (RSM) to identify the best performance parameters and predict the behavior of joints for untested parameter settings.