Advanced Composites Explained Universal Polyamide Overmold Thermoplastic Elastomer - White Paper OnForce™ LFT Long-Fiber Reinforced Thermoplastic Composites - Product Bulletin

Polystrand™ Continuous Fiber Tapes & Laminates Continuous Fiber Reinforced Thermoplastic Composites Benefits of Long Fiber Reinforced Thermoplastic Composites

Fiber Reinforced Polymer Pultrusion: Composite Fiber Rods Short, long and continuous fiber composites available in pellet or semi-finished forms

Long Fiber Technology You’re not alone with our composite expertise on your team.   We apply the technology and performance benefits of long fiber reinforced thermoplastic composites to make your products better – giving you an unbeatable marketplace advantage. 

Composite springs (also referred to as flat springs, flippers, energizers, slats, and exciters) from Avient Advanced Composites are engineered with proprietary vinyl ester or epoxy resins and unidirectional glass or carbon fiber reinforcement technologies. Avient’s reinforced composite technologies use carbon, glass and aramid fibers with custom formulated thermoset or thermoplastic resins in continuous forming processes Continuous fiber-reinforced composites in standard and custom shapes & sizes

They realized they might be able to shave off even more weight and improve performance by replacing the aluminum braces with a continuous-fiber composite if they could find a material with an exceptional strength-to-weight ratio, high flexural stiffness, good torsional rigidity, and superior fatigue strength. To meet the underbody brace requirements, Avient’s Glasforms™ technologies were recommended to produce continuous fiber-reinforced braces. The automated pultrusion process fabricates continuous glass or carbon fiber-reinforced, constant cross-section profiles with consistent, uniform properties. 

They realized they might be able to shave off even more weight and improve performance by replacing the aluminum braces with a continuous-fiber composite if they could find a material with an exceptional strength-to-weight ratio, high flexural stiffness, good torsional rigidity, and superior fatigue strength. To meet the underbody brace requirements, Avient’s Glasforms™ technologies were recommended to produce continuous fiber-reinforced braces. The automated pultrusion process fabricates continuous glass or carbon fiber-reinforced, constant cross-section profiles with consistent, uniform properties. 

They realized they might be able to shave off even more weight and improve performance by replacing the aluminum braces with a continuous-fiber composite if they could find a material with an exceptional strength-to-weight ratio, high flexural stiffness, good torsional rigidity, and superior fatigue strength. To meet the underbody brace requirements, Avient’s Glasforms™ technologies were recommended to produce continuous fiber-reinforced braces. The automated pultrusion process fabricates continuous glass or carbon fiber-reinforced, constant cross-section profiles with consistent, uniform properties. 

They realized they might be able to shave off even more weight and improve performance by replacing the aluminum braces with a continuous-fiber composite if they could find a material with an exceptional strength-to-weight ratio, high flexural stiffness, good torsional rigidity, and superior fatigue strength. To meet the underbody brace requirements, Avient’s Glasforms™ technologies were recommended to produce continuous fiber-reinforced braces. The automated pultrusion process fabricates continuous glass or carbon fiber-reinforced, constant cross-section profiles with consistent, uniform properties. 

They realized they might be able to shave off even more weight and improve performance by replacing the aluminum braces with a continuous-fiber composite if they could find a material with an exceptional strength-to-weight ratio, high flexural stiffness, good torsional rigidity, and superior fatigue strength. To meet the underbody brace requirements, Avient’s Glasforms™ technologies were recommended to produce continuous fiber-reinforced braces. The automated pultrusion process fabricates continuous glass or carbon fiber-reinforced, constant cross-section profiles with consistent, uniform properties.