Although these process aids do not directly benefit preform manufacturers, who produce the initial plastic preforms, the advantages are realized at the bottle blower stage, where the preforms are heated and blown into their final bottle shapes. Reduce energy to the blowing lamps allowing preforms to heat faster b. Increased Throughput: To achieve desired bottle quality, many blow molders will slow the blow speed, giving the preform optimal time to heat before blowing.

Although these process aids do not directly benefit preform manufacturers, who produce the initial plastic preforms, the advantages are realized at the bottle blower stage, where the preforms are heated and blown into their final bottle shapes. Reduce energy to the blowing lamps allowing preforms to heat faster b. Increased Throughput: To achieve desired bottle quality, many blow molders will slow the blow speed, giving the preform optimal time to heat before blowing.

Plastics do not readily conduct electricity, or heat and cool the way metals do. While conventional plastics retain heat, plastics containing thermally conductive fillers distribute heat and carry it away from the heat source. Aramid is heat- and wear-resistant, and it’s lighter but stronger than carbon fiber.

Plastics do not readily conduct electricity, or heat and cool the way metals do. While conventional plastics retain heat, plastics containing thermally conductive fillers distribute heat and carry it away from the heat source. Aramid is heat- and wear-resistant, and it’s lighter but stronger than carbon fiber.

Plastics do not readily conduct electricity, or heat and cool the way metals do. While conventional plastics retain heat, plastics containing thermally conductive fillers distribute heat and carry it away from the heat source. Aramid is heat- and wear-resistant, and it’s lighter but stronger than carbon fiber.

Plastics do not readily conduct electricity, or heat and cool the way metals do. While conventional plastics retain heat, plastics containing thermally conductive fillers distribute heat and carry it away from the heat source. Aramid is heat- and wear-resistant, and it’s lighter but stronger than carbon fiber.

Plastics do not readily conduct electricity, or heat and cool the way metals do. While conventional plastics retain heat, plastics containing thermally conductive fillers distribute heat and carry it away from the heat source. Aramid is heat- and wear-resistant, and it’s lighter but stronger than carbon fiber.

Plastics do not readily conduct electricity, or heat and cool the way metals do. While conventional plastics retain heat, plastics containing thermally conductive fillers distribute heat and carry it away from the heat source. Aramid is heat- and wear-resistant, and it’s lighter but stronger than carbon fiber.

Plastics do not readily conduct electricity, or heat and cool the way metals do. While conventional plastics retain heat, plastics containing thermally conductive fillers distribute heat and carry it away from the heat source. Aramid is heat- and wear-resistant, and it’s lighter but stronger than carbon fiber.

Advanced PC, PPS and LCP formulations to help customers to build 3D circuits on molded part surfaces; supporting high design flexibilty, multi-function integration, size miniaturization and weight reduction, even in high heat processes such as SMT Heat stabilized, impact modified polyphthalamide (PPA) formulations with mechanical integrity, high-temperature performance, and low moisture absorption Learn about the high-heat and low moisture absorption performance of polyphthalamide (PPA) formulations