Title: Influence of Surface Treatment on the Interfacial and Mechanical Performance of Metal-Insert Overmolded Composites

Authors: Subhabrata Saha, Segun Isaac Talabi, Nadim Hmeidat, Ryan Ogle, Brittany Rodriguez, David Nuttall, Jesse Murphy, Marco Martinez, Vipin Kumar, Ahmed Hassen

DOI:

Abstract: Structural composites with metal inserts are gaining increasing interest enabling light weight design for energy efficiency, provide insulation, corrosion protection without compromising mechanical integrity. Such over molded metal-polymer composites show strong potential in many automotive and aerospace component parts, e.g., car bumper, chassis, door, brackets, fasteners, etc. Despite several advantages, metal-polymer dissimilar interface remains a weak spot in structural design, requiring further investigation to improve interfacial interlocking. The current work focuses on enhancing the metal-polymer adhesion between stainless steel inserts and polymer matrices (e.g. acrylonitrile butadiene styrene resin (ABS), and polyamide 66 (PA66)) through surface treatment via chemical etching and mechanical roughening. In the chemical etching process, metal substrates were treated with aqua regia solution for different time intervals to evaluate surface roughness measured by water contact angle and morphology analysis. For mechanical roughening approach, metal inserts were subjected to blasting for surface abrasion. Treated samples were also functionalized with aminosilane coupling agent which showed successful grafting on the surface measured by water contact angle. Metal inserts with micro level surface roughness through etching exhibited significant 26% improvement in adhesion strength compared to untreated inserts for ABS; whereas, the effect of silane treatment on the interfacial strength was found to be more effective for PA66.

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Conference: SAMPE 2026

Publication Date: 2026/04/27

SKU: 121

Pages: 17

Price: $34.00