Mevopur™ Healthcare Functional Additives Laser Welding Additives for Medical Devices Laser welding has become a technology of choice to join plastic parts of complex medical devices. It is the responsibility of the medical device manufacturer and the person placing the medical device on the market to ensure compliance of the medical device with all applicable laws and regulations, including the suitability of all raw materials and components used for its manufacture.

PRODUCT BULLETIN Non-PFAS Polymer Process Aids for Extrusion in Polyolefins Cesa™ and Hiformer™ Non-PFAS Process Aids are formulated without the use of fluorochemicals. They can be used in the extrusion of polyethylene or polypropylene to reduce the friction between the molten polymer and metal, enabling the polymers to be extruded without melt fracture. KEY CHARACTERISTICS • Reduces melt fracture leading to fast time to clear • Reduces die buildup • Improves process efficiency • Retains ability to seal and print • Available in both solid and liquid • Offers low concentration efficiency • Reduces power requirements • Does not interact with other additives APPLICATIONS • Blown film • Profile extrusion • Tubing and pipe extrusion • Wire and cable applications • Extruded sheet • Applications in both virgin resin and PCR Copyright © 2024, Avient Corporation.

However, for synthetic fibers manufactured by an extrusion process, such as polyester, polyamide, and polypropylene, there is another technology that uses no water and less energy than classic bath-dyeing: spin-dyeing. The colorant is in the form of concentrate pellets added to the polymer pellets during the extrusion and melting process.

However, for synthetic fibers manufactured by an extrusion process, such as polyester, polyamide, and polypropylene, there is another technology that uses no water and less energy than classic bath-dyeing: spin-dyeing. The colorant is in the form of concentrate pellets added to the polymer pellets during the extrusion and melting process.

However, for synthetic fibers manufactured by an extrusion process, such as polyester, polyamide, and polypropylene, there is another technology that uses no water and less energy than classic bath-dyeing: spin-dyeing. The colorant is in the form of concentrate pellets added to the polymer pellets during the extrusion and melting process.

However, for synthetic fibers manufactured by an extrusion process, such as polyester, polyamide, and polypropylene, there is another technology that uses no water and less energy than classic bath-dyeing: spin-dyeing. The colorant is in the form of concentrate pellets added to the polymer pellets during the extrusion and melting process.

However, for synthetic fibers manufactured by an extrusion process, such as polyester, polyamide, and polypropylene, there is another technology that uses no water and less energy than classic bath-dyeing: spin-dyeing. The colorant is in the form of concentrate pellets added to the polymer pellets during the extrusion and melting process.

However, for synthetic fibers manufactured by an extrusion process, such as polyester, polyamide, and polypropylene, there is another technology that uses no water and less energy than classic bath-dyeing: spin-dyeing. The colorant is in the form of concentrate pellets added to the polymer pellets during the extrusion and melting process.

However, for synthetic fibers manufactured by an extrusion process, such as polyester, polyamide, and polypropylene, there is another technology that uses no water and less energy than classic bath-dyeing: spin-dyeing. The colorant is in the form of concentrate pellets added to the polymer pellets during the extrusion and melting process.

However, for synthetic fibers manufactured by an extrusion process, such as polyester, polyamide, and polypropylene, there is another technology that uses no water and less energy than classic bath-dyeing: spin-dyeing. The colorant is in the form of concentrate pellets added to the polymer pellets during the extrusion and melting process.