Home // Reduce Carbon Footprint by Replacing Traditional Materials Each year humans put more carbon dioxide into the atmosphere than natural processes can remove, amplifying Earth’s natural greenhouse effect. The new materials also offer sustainability benefits over the product lifecycle through carbon footprint reductions compared to competitive materials—PK base resin production emits up to 61 percent less carbon dioxide (CO2) than nylon and POM.

Home // Reduce Carbon Footprint by Replacing Traditional Materials Each year humans put more carbon dioxide into the atmosphere than natural processes can remove, amplifying Earth’s natural greenhouse effect. The new materials also offer sustainability benefits over the product lifecycle through carbon footprint reductions compared to competitive materials—PK base resin production emits up to 61 percent less carbon dioxide (CO2) than nylon and POM.

Home // Reduce Carbon Footprint by Replacing Traditional Materials Each year humans put more carbon dioxide into the atmosphere than natural processes can remove, amplifying Earth’s natural greenhouse effect. The new materials also offer sustainability benefits over the product lifecycle through carbon footprint reductions compared to competitive materials—PK base resin production emits up to 61 percent less carbon dioxide (CO2) than nylon and POM.

In solvolysis, the chain length of matrix polymers is reduced toward monomers while removing the matrix from the fibers so that both the fibers and matrix chemical products can be recovered. This not only reduces waste but also lowers greenhouse gas emissions and offers opportunities for carbon capture. Conducting a comprehensive carbon footprint analysis is essential to making informed choices

In solvolysis, the chain length of matrix polymers is reduced toward monomers while removing the matrix from the fibers so that both the fibers and matrix chemical products can be recovered. This not only reduces waste but also lowers greenhouse gas emissions and offers opportunities for carbon capture. Conducting a comprehensive carbon footprint analysis is essential to making informed choices

In solvolysis, the chain length of matrix polymers is reduced toward monomers while removing the matrix from the fibers so that both the fibers and matrix chemical products can be recovered. This not only reduces waste but also lowers greenhouse gas emissions and offers opportunities for carbon capture. Conducting a comprehensive carbon footprint analysis is essential to making informed choices

Continuous fiber reinforced thermoset composites combine high molecular weight resins with glass or carbon fibers. Fiber Volume Fiber volume is the ratio of fiber to resin in a composite structure.

To modify and expand on the structural performance of the base resin, these materials are formulated with a range of reinforcing additives, including short glass or carbon fibers, minerals or glass beads. Fishing Rod Handle Edgetek™ Glass-Filled Thermoplastics provided toughness and stiffness to fishing rod handle

FL.Datasheet Fiberglass.indd FIBER OPTICAL CABLES Key Features • Good tensile strength & modulus • Excellent thermal properties • Good chemical resistance • Good flame resistance • Good electrical insulation Disadvantages • Low strength to weight ratio • Brittle filaments • Poor abrasion resistance FIBER-LINE® PROCESS FOR FIBERGLASS • Coating • Pultrusion • Extrusion • Precision Winding FIBER-LINE® FIBERGLASS PRODUCTS • Strength Members • Industrial Fabric Yarn • FRP Pultruded Rod • Strength Members • Industrial Fabric Yarn Manufacturer Various Suppliers. History The mass production of glass fibers first began in the 1930’s. LOCATIONS Headquarters, R&D, Manufacturing FIBER-LINE® LLC 3050 Campus Drive Hatfield, PA 19440 +1 215.997.9181 fiber@fiber-line.com Manufacturing Operations FIBER-LINE® LLC 280 Performance Drive SE Hickory, NC 28602 +1 828.326.8700 fiber@fiber-line.com EMEA & Asia Pacific Operations FIBER-LINE® INTERNATIONAL B.V.

Continuous Fiber Reinforced Thermoplastics    Long Fiber Thermoplastics (LFTs)   Case Study Automotive Connector Rod Case Study Collaboration with Hexagon and its Digimat Platform to more accurately predict part performance for fiber-reinforced thermoplastics.