Given its extremely high crystallin

Given its extremely high crystallinity and the associated high melting point, its melt viscosity, and
its low melt flow rates, PTFE cannot be processed by conventional fabrication techniques used for
polymers. Instead, unusual techniques have been developed for shaping polytetrafluoroethylene. Molding
PTFE powders are processed by the two-staged press and sinter methods used in powder metallurgy.
Granular PTFE is first pressed into the desired shape at room temperature and pressure (in the range
2000 to 10,000 psi). The resulting preform is then sintered at a temperature above the crystalline melting
point (360 to 380°C) to obtain a dense, strong, homogeneous product. Better melt processing is achieved
by reducing the crystallinity of PTFE through incorporation of a small concentration of a comonomer
such as hexafluoropropylene. The resulting copolymer retains most of the desirable properties of polytetrafluoroethylene but has a reduced melt viscosity that permits processing by traditional techniques.
Polytetrafluoroethylene is used primarily in applications that require extreme toughness, outstanding
chemical and heat resistance, good electrical properties, low friction, or a combination of these properties.
Principal applications or PTFE are as components or linings for chemical process equipment, hightemperature cable insulation, molded electrical components, tape, and nonstick coatings. Chemical
process equipment applications include linings for pipe, pipe fittings, valves, pumps, gaskets, and reaction
vessels. PTFE is used as insulation for wire and cable, motors, generators, transformers, coils and
capacitors, high-frequency electronic uses, and molded electrical components such as insulators and tube
sockets. Nonstick low friction uses include home cookware, tools, and food-processing equipment.
In addition to polytetrafluoroethylene, several other partially fluorinated polymers are available
commercially. These include poly(chlorotrifluoroethylene), which is also available as a copolymer with
ethylene or vinylidene fluoride, poly(vinyl fluoride), and poly(vinylidene fluoride). Poly(chlorotrifluoroethylene) is a chemically inert and thermally stable polymer, soluble in a number of solvents above
100°C, tough at temperatures as low as –100°C while retaining its useful properties at temperatures as
high as 150°C. Its melt viscosity, though relatively high, is sufficiently low to permit the use of
conventional molding and extrusion processing methods. It is used for electrical insulators, gaskets and
seals, and pump parts.
Poly(vinyl fluoride) is a highly crystalline polymer available commercially as a tough, flexible film
sold under the trade name Tedlar by DuPont. It has excellent chemical resistance like other fluoropolymers, excellent outdoor weatherability, and good thermal stability, abrasion, and stain resistance. It
maintains useful properties between –180°C to 150°C. It is used as protective coatings for materials like
plywood, vinyl, hardboard, metals, and reinforced polyesters. These laminated materials find applications
in aircraft interior panels, in wall covering, and in the building industry.
Poly(vinylidene chloride) is a crystalline polymer (mp 170°C), with significantly greater strength and
creep and wear resistance than PTFE. Poly(vinylidene chloride), which is also available as a copolymer
with hexafluoroethylene, has very good weatherability and chemical and solvent resistance. It is used
primarily in coatings; as a gasket material; in wire and cable insulation; in piping, tanks, pumps and
other chemical process equipment; and in extrusion of vinyl siding for houses.