Bump-off molding results in an undercut that “bumps” in two directions and ejects from the mold without using a sliding structure. The parting line (mold lip) goes away allowing for a burr-less mold. Previously, PPS had limited use in bump-off molding of engineering parts due to its fragility.
Polyplastics found that materials with high bending fracture strain in high-temperature environments (150°C for PPS) are suited for bump-offs in terms of both damage and deformation. The company also observed that improvements in fracture strain in high-temperature environments are possible by reducing filler, adding elastomer, and utilizing high-molecular-weight PPS.
Polyplastics has shown that linear PPS exhibits greater fracture strain than cross-linked PPS and is more conducive to bump-off molding. Polyplastics’ Durafide PPS appears to be suited for bump-offs from the standpoint of toughness in high-temperature environments. Among Durafide PPS materials, high-molecular-weight 1130A1 (GF30%) and 1140A1 (GF40%) appear to be useful for bump-offs.
Polyplastics believes that Durafide PPS boosts the reliability of products, and that bump-offs reduce the deburring process and facilitate greater design freedom. Durafide PPS also delivers high heat resistance with a continuous service temperature of 200°C to 240°C. It also offers greater chemical resistance versus fluoropolymers and greater dimensional stability and reduced hydrolysis and water absorption compared to nylon 66.
Industries: Automotive and Road Transportation