Calendering – pressing PTFE-coated fabric between heated mirror rollers at 360-380°C – dramatically alters surface morphology, release properties, impermeability, and mechanical performance. It reduces roughness from Ra 0.5-1.0 μm to <0.05 μm, seals pinholes, improves wear resistance, but decreases tear strength and flexibility. Essential for release liners and electrical insulation.

Fiberglass weave pattern – plain, twill, or satin – significantly affects PTFE high-temperature fabric properties. Satin weave offers highest tear strength (2-3x plain) and flexibility, ideal for dynamic bending. Plain weave provides best dimensional stability and peel adhesion, suited for static applications. Twill balances all properties for general use.

Coating uniformity of PTFE high-temperature fabric is determined by four factors: coating formulation (particle size 0.15-0.35 μm, viscosity, solid content), coating & sintering process (blade coating preferred for uniformity), substrate quality (weave pattern, pre-treatment), and production environment (20-25°C, <60% RH). Dip + blade combined process balances penetration and surface smoothness.

PTFE high-temperature fabric offers exceptional chemical resistance, withstanding strong acids, alkalis, organic solvents, and corrosive gases. This article details its resistant substances, limitations (molten alkali metals, strong fluorinating agents), and key factors like temperature, concentration, and mechanical stress.

As a professional manufacturer of PTFE high-temperature fabrics, Jiangsu Aokai New Materials gives you professional insights. The core purpose of fiberglass surface treatment is to build a molecular bridge between inorganic fiberglass and organic PTFE, so as to fundamentally solve their inherent inc