PX-C-241H FLESH SOFT HOT MELT Geon(TM) DB5143 PMS Yellow C PX19325-C Clear (DB4540)

Flow Lines: near gate points, compromise appearance and aesthetics   Our dedicated packaging team of engineers, field specialists, designers and color technologists are here to engage at any point in the packaging development lifecycle, to:  

When choosing an ink, consider the following five points of performance: 5 Points of Performance

It is always recommended to test the container at multiple points in the wall section (at least at the thickest and thinnest locations) to fully assess the UV barrier capability. Base your additive concentration on the thinnest point in the wall section to ensure adequate protection across the entire container.

High viscosity is usually associated with high melt strength. Extrusion, blown film production or blow molding requires high melt strength. Melt Index Testing

High viscosity is usually associated with high melt strength. Extrusion, blown film production or blow molding requires high melt strength. Melt Index Testing

During the extrusion process, Cesa™ Process Additives coat the inner surface of the die, reducing the friction between the melt and the metal and allowing polymers to extrude more easily. By lowering the friction and reducing melt-fracture and die buildup, CESA Process Additives enable difficult-to-process materials such as narrowmolecular-weight LLDPE and LLDPE-rich blends to run on existing extrusion lines. Reduces the friction between the melt and the metal in the die

This process starts with tows of continuous fiber which are pulled from creels through a proprietary impregnation die where the fiber becomes melt impregnated with thermoplastic polymer.  A compounding extruder connected to the impregnation die functions as a melt pump feeding molten thermoplastic polymer into the process.  The melt impregnated fiber exits the die as continuous composite strands which are cooled using water and/or air until solidified.

N95 masks, for example, rely on multi-layer construction, with a middle layer made from melt-blown non-woven material. This masterbatch was necessary for the manufacture of melt-blown non-woven polypropylene used to make the protective face masks with long-lasting filtration properties. By introducing additives with charge storage properties, “charge traps” were created to capture the electret charge being applied to melt-blown non-woven material.

N95 masks, for example, rely on multi-layer construction, with a middle layer made from melt-blown non-woven material. This masterbatch was necessary for the manufacture of melt-blown non-woven polypropylene used to make the protective face masks with long-lasting filtration properties. By introducing additives with charge storage properties, “charge traps” were created to capture the electret charge being applied to melt-blown non-woven material.