Each ColorMatrix™ FlexCart™ model is highly flexible, and offers high-level dosing accuracy and controllability for all injection molding and extrusion applications. ColorMatrix™ FlexCart™ Priming and Extrusion Learn about priming and extrusion for the FlexCart™

PVDF Wire & Cable Extrusion PVDF Filament Extrusion Extrusion Sheet & Strap

PVDF Wire & Cable Extrusion PVDF Filament Extrusion Extrusion Sheet & Strap

Learn more about our solid solution, Cesa™ Non-PFAS Process Aid for Extrusion, and our Colorant Chromatics™ Evoluscend™ Non-PFAS High-Temperature Mold Release Additive. Non-PFAS Process Aid for Extrusion Improved productivity and process stability for film or sheet extrusion.

Avient expands the launch of its new Cesa™ Non-PFAS Process Aid for polyolefin extrusion and film formulations to Asia, enabling processability, productivity, and stability comparable to traditional fluoropolymer-based processing aids. This new solution is formulated without fluoropolymers, which may be classifiable as per- and polyfluorinated substances (PFAS), for use in polyolefin extrusion and film applications without compromising performance or efficiency.   Avient’s Cesa Non-PFAS Process Aid for Extrusion is currently manufactured in Greater China, Thailand and the United States.

Most fluoropolymers, other than PTFE and polyvinyl fluoride (PVF), can be melt processed using conventional thermoplastic extrusion or molding techniques. The high-speed manufacture of thin-wall wire jacketing would require a distinctly different formulation compared to the extrusion of a large cross-section stock shape such as a rod. In contrast, rod extrusion would require very stable pigments due to the longer residence time in the extruder.  

Most fluoropolymers, other than PTFE and polyvinyl fluoride (PVF), can be melt processed using conventional thermoplastic extrusion or molding techniques. The high-speed manufacture of thin-wall wire jacketing would require a distinctly different formulation compared to the extrusion of a large cross-section stock shape such as a rod. In contrast, rod extrusion would require very stable pigments due to the longer residence time in the extruder.  

Most fluoropolymers, other than PTFE and polyvinyl fluoride (PVF), can be melt processed using conventional thermoplastic extrusion or molding techniques. The high-speed manufacture of thin-wall wire jacketing would require a distinctly different formulation compared to the extrusion of a large cross-section stock shape such as a rod. In contrast, rod extrusion would require very stable pigments due to the longer residence time in the extruder.  

Most fluoropolymers, other than PTFE and polyvinyl fluoride (PVF), can be melt processed using conventional thermoplastic extrusion or molding techniques. The high-speed manufacture of thin-wall wire jacketing would require a distinctly different formulation compared to the extrusion of a large cross-section stock shape such as a rod. In contrast, rod extrusion would require very stable pigments due to the longer residence time in the extruder.  

Most fluoropolymers, other than PTFE and polyvinyl fluoride (PVF), can be melt processed using conventional thermoplastic extrusion or molding techniques. The high-speed manufacture of thin-wall wire jacketing would require a distinctly different formulation compared to the extrusion of a large cross-section stock shape such as a rod. In contrast, rod extrusion would require very stable pigments due to the longer residence time in the extruder.