Some fillers make plastics electrically and thermally conductive, and others add thermal conductivity without electrical conductivity. The thermal conductivity of conductive plastics is not as high as that of metal, but conductive plastics can be just as effective as metals in thermal management, transferring heat by conduction (which depends on the material) and convection (which depends on the design of the system and the flow of air or liquid around the polymer part). These oxides have high thermal and electrical conductivity (although hematite can conduct more heat), can block radiation, and can dampen sound.

Some fillers make plastics electrically and thermally conductive, and others add thermal conductivity without electrical conductivity. The thermal conductivity of conductive plastics is not as high as that of metal, but conductive plastics can be just as effective as metals in thermal management, transferring heat by conduction (which depends on the material) and convection (which depends on the design of the system and the flow of air or liquid around the polymer part). These oxides have high thermal and electrical conductivity (although hematite can conduct more heat), can block radiation, and can dampen sound.

Some fillers make plastics electrically and thermally conductive, and others add thermal conductivity without electrical conductivity. The thermal conductivity of conductive plastics is not as high as that of metal, but conductive plastics can be just as effective as metals in thermal management, transferring heat by conduction (which depends on the material) and convection (which depends on the design of the system and the flow of air or liquid around the polymer part). These oxides have high thermal and electrical conductivity (although hematite can conduct more heat), can block radiation, and can dampen sound.

Some fillers make plastics electrically and thermally conductive, and others add thermal conductivity without electrical conductivity. The thermal conductivity of conductive plastics is not as high as that of metal, but conductive plastics can be just as effective as metals in thermal management, transferring heat by conduction (which depends on the material) and convection (which depends on the design of the system and the flow of air or liquid around the polymer part). These oxides have high thermal and electrical conductivity (although hematite can conduct more heat), can block radiation, and can dampen sound.

Some fillers make plastics electrically and thermally conductive, and others add thermal conductivity without electrical conductivity. The thermal conductivity of conductive plastics is not as high as that of metal, but conductive plastics can be just as effective as metals in thermal management, transferring heat by conduction (which depends on the material) and convection (which depends on the design of the system and the flow of air or liquid around the polymer part). These oxides have high thermal and electrical conductivity (although hematite can conduct more heat), can block radiation, and can dampen sound.

Some fillers make plastics electrically and thermally conductive, and others add thermal conductivity without electrical conductivity. The thermal conductivity of conductive plastics is not as high as that of metal, but conductive plastics can be just as effective as metals in thermal management, transferring heat by conduction (which depends on the material) and convection (which depends on the design of the system and the flow of air or liquid around the polymer part). These oxides have high thermal and electrical conductivity (although hematite can conduct more heat), can block radiation, and can dampen sound.

Some fillers make plastics electrically and thermally conductive, and others add thermal conductivity without electrical conductivity. The thermal conductivity of conductive plastics is not as high as that of metal, but conductive plastics can be just as effective as metals in thermal management, transferring heat by conduction (which depends on the material) and convection (which depends on the design of the system and the flow of air or liquid around the polymer part). These oxides have high thermal and electrical conductivity (although hematite can conduct more heat), can block radiation, and can dampen sound.

Electrical Conductivity for Silicone Thermally Conductive Dispersions: Silcosperse™ TC Enhanced thermal conductivity for silicone materials.

Maxxam™ NHFR Non-Halogen Flame Retardant Polyolefin Formulation provided a non-halogenated solution for manufacturer while increasing the thermal conductivity High-Temperature Cables for Oil & Gas Industry Therma-Tech™ provided lighter weight solutions with required thermal conductivity for automotive light heat sinks

Maxxam™ NHFR Non-Halogen Flame Retardant Polyolefin Formulation provided a non-halogenated solution for manufacturer while increasing the thermal conductivity High-Temperature Cables for Oil & Gas Industry Therma-Tech™ provided lighter weight solutions with required thermal conductivity for automotive light heat sinks