Barrier technologies that preserve the shelf-life and quality of food, beverages, medicine and other perishable goods through high-performance materials that require less plastic Light-weighting solutions that replace heavier traditional materials like metal, glass and wood, which can improve fuel efficiency in all modes of transportation

Barrier technologies that preserve the shelf-life and quality of food, beverages, medicine and other perishable goods through high-performance materials that require less plastic Light-weighting solutions that replace heavier traditional materials like metal, glass and wood, which can improve fuel efficiency in all modes of transportation

Barrier technologies that preserve the shelf-life and quality of food, beverages, medicine and other perishable goods through high-performance materials that require less plastic Light-weighting solutions that replace heavier traditional materials like metal, glass and wood, which can improve fuel efficiency in all modes of transportation

Barrier technologies that preserve the shelf-life and quality of food, beverages, medicine and other perishable goods through high-performance materials that require less plastic Light-weighting solutions that replace heavier traditional materials like metal, glass and wood, which can improve fuel efficiency in all modes of transportation

Barrier technologies that preserve the shelf-life and quality of food, beverages, medicine and other perishable goods through high-performance materials that require less plastic Light-weighting solutions that replace heavier traditional materials like metal, glass and wood, which can improve fuel efficiency in all modes of transportation

Barrier technologies that preserve the shelf-life and quality of food, beverages, medicine and other perishable goods through high-performance materials that require less plastic Light-weighting solutions that replace heavier traditional materials like metal, glass and wood, which can improve fuel efficiency in all modes of transportation

Barrier technologies that preserve the shelf-life and quality of food, beverages, medicine and other perishable goods through high-performance materials that require less plastic Light-weighting solutions that replace heavier traditional materials like metal, glass and wood, which can improve fuel efficiency in all modes of transportation

It’s one of these shapes that influences what kind of enhancement the particle can bring.   Thermally conductive plastic parts may be anisotropic—meaning they conduct heat better in one direction (in the plane of the conductive filler, either axial or transverse) than in the perpendicular directions (through the plane of the filler). The design of the part, the characteristics of the filler (e.g. particle size and aspect ratio), and molding conditions can affect the balance of in-plane and through-plane conductivity.

It’s one of these shapes that influences what kind of enhancement the particle can bring.   Thermally conductive plastic parts may be anisotropic—meaning they conduct heat better in one direction (in the plane of the conductive filler, either axial or transverse) than in the perpendicular directions (through the plane of the filler). The design of the part, the characteristics of the filler (e.g. particle size and aspect ratio), and molding conditions can affect the balance of in-plane and through-plane conductivity.

It’s one of these shapes that influences what kind of enhancement the particle can bring.   Thermally conductive plastic parts may be anisotropic—meaning they conduct heat better in one direction (in the plane of the conductive filler, either axial or transverse) than in the perpendicular directions (through the plane of the filler). The design of the part, the characteristics of the filler (e.g. particle size and aspect ratio), and molding conditions can affect the balance of in-plane and through-plane conductivity.