Cesa™ Fiber Additives Soft Touch Effect for Synthetic Fibers and Nonwovens PRODUCT BULLETIN Copyright © 2022, Avient Corporation. The Cesa™ Fiber Additives portfolio includes soft touch concentrates that are incorporated during the spin-dyeing process. They are suitable for PP, PET, PA and PLA fibers.

Long fiber composites, in particular, are well-suited for replacing metal, offering exceptional strength-to-weight ratio and the ease of injection molding, which can expand design options and streamline processing steps.   Advanced computer-aided engineering (CAE) software, when complemented by in-depth design and material knowledge, facilitates precise prediction of the behavior of fiber-reinforced polymer materials. For more technical details on the structural performance of reinforced polymers using CAE, automotive design engineers may access material data and models for Avient’s fiber-reinforced solutions using Hexagon’s Digimat-MX Tool.

Long fiber composites, in particular, are well-suited for replacing metal, offering exceptional strength-to-weight ratio and the ease of injection molding, which can expand design options and streamline processing steps.   Advanced computer-aided engineering (CAE) software, when complemented by in-depth design and material knowledge, facilitates precise prediction of the behavior of fiber-reinforced polymer materials. For more technical details on the structural performance of reinforced polymers using CAE, automotive design engineers may access material data and models for Avient’s fiber-reinforced solutions using Hexagon’s Digimat-MX Tool.

Cesa™ Fiber Additives for Heat Preservation TECHNICAL BULLETIN Avient’s new generation of heat-preservation additive formulations for fiber and textile applications are developed to help brands more easily meet demands for lightweight and comfortable winter clothing, sportswear and bedding. Fabrics made with Cesa™ Fiber Additives for heat preservation can absorb more heat than untreated textile when exposed to simulated sunlight with the wavelength from 320 to 1100nm. TEMPERATURE DISTRIBUTION DIAGRAM • Test Method: FTTS-FA-010-2007 4.2 • Equipment: Thermovision • Heat Source: 500W Halogen Lamp • Heat Distance: 100 cm Surface temperature before exposure: 20.22°C Surface temperature after 10 min exposure: 33.85°C Temperature change: +13.6°C Added Cesa Fiber Additives for heat preservation TEST METHOD STANDARD REQUEST TEST RESULT GB/T30127 Far infrared radiation properties Far infrared emissivity ≥0.88 (5-14um) (Test temperature: 34°C) 0.9 Far infrared radiation temperature rise ≥ 1.4°C 9°C GB/T 18319-2019 Thermal retention with accumulated by infrared ray Maximum temperature rise ≥ 6°C 8.9°C Mean temperature rise ≥ 4.4°C (20 minutes) 5.6°C FTTS-FA-010 Infrared radiation properties & thermal retention temperature rise Average emissivity ≥ 0.8 (2-22um) (Test temperature: 25°C) 0.8 Specified heating ΔT ≥ 0.5°C (relative to the standard) +5.34°C (ΔT) GB/T 11048-2008 Method A Thermal transmittance Unit: clo Naked body: 0 Underwear: 0.04 T-shirt: 0.09 Thick sweater: 0.35 Winter coat: 0.7 All the data above are the reference value 0.625 Human Physiological Experiment Blood flow volume +12.9% Blood flow velocity +13.6% Blood oxygenation(%SpO2) +1.7% www.avient.com Copyright © 2023, Avient Corporation.

Product Carbon Footprint To date we have completed over 1,000 product carbon footprint calculations. Product Carbon Footprint Calculations

To create a softer surface, many textile manufacturers are brushing fibers. No ink is applied to the fabric, but this step lays down fibers and creates a smoother surface, eliminating the need for an extra print stroke.

Some of the changes that will come into force as a result include the expansion of the deposit system to all non-returnable plastic beverage bottles, with non-carbonated fruit juice packaging joining carbonated drinks packaging in the scheme. SmartHeat RHC also allows for a reduction in energy during the bottle blowing process, helping to reduce carbon emissions.

Some of the changes that will come into force as a result include the expansion of the deposit system to all non-returnable plastic beverage bottles, with non-carbonated fruit juice packaging joining carbonated drinks packaging in the scheme. SmartHeat RHC also allows for a reduction in energy during the bottle blowing process, helping to reduce carbon emissions.

This reduction in energy consumption can not only cut costs, but it can also lower the carbon footprint of the manufacturing process. Reduced Carbon Footprint: Using recycle-enabling process aids can lower the energy consumption of the bottle-blowing process, thereby reducing the carbon footprint of the entire packaging lifecycle.

This reduction in energy consumption can not only cut costs, but it can also lower the carbon footprint of the manufacturing process. Reduced Carbon Footprint: Using recycle-enabling process aids can lower the energy consumption of the bottle-blowing process, thereby reducing the carbon footprint of the entire packaging lifecycle.