Vespel is the trademark of a range of durable high-performance polyimide-based plastics manufactured by DuPont. The one shown in the structure on the right was the first to be commercialized.
Characteristics and applications
Vespel is mostly used in aerospace, semiconductor, and transportation technology. It combines heat resistance, lubricity, dimensional stability, chemical resistance, and creep resistance, and can be used in hostile and extreme environmental conditions. Unlike most plastics, it does not produce significant outgassing even at high temperatures, which makes it useful for lightweight heat shields and crucible support. It also performs well in vacuum applications, down to extremely low cryogenic temperatures. However, Vespel tends to absorb a small amount of water, resulting in longer pump time while placed in a vacuum. Although there are polymers surpassing polyimide in each of these properties, the combination of them is the main advantage of Vespel.
Vespel can be processed by direct forming and isostatic molding. For prototype quantities, basic shapes are typically used for cost efficiency since tooling is quite expensive for DF parts. For large scaleCNC production, DF parts are often used to reduce per part costs, at the expense of material properties which are inferior to those of isostatically produced basic shapes.
Types
For different applications, special formulations are blended/compounded. Shapes are produced by three standard processes: 1) compression molding ; 2) isostatic molding ; and 3) direct forming. Direct-formed parts have lower performance characteristics than parts that have been machined from compression-molded or isostatic shapes. Isostatic shapes have isotropic physical properties, whereas direct formed and compression molded shapes exhibit anisotropic physical properties. Some examples of standard polyimide compounds are: ;SP-1 virgin polyimide: provides operating temperatures from cryogenic to 300 °C, high plasma resistance, as well as a UL rating for minimal electrical and thermal conductivity. This is the unfilled base polyimide resin. It also provides high physical strength and maximal elongation, and the best electrical and thermal insulation values. Example: Vespel SP-1. ;15% graphite by weight - SP-21: added to the base resin for increased wear resistance and reduced friction in applications such as plain bearings, thrust washers, seal rings, slide blocks and other wear applications. This compound has the best mechanical properties of the graphite-filled grades, but lower than the virgin grade. Example: Vespel SP-21. ;40% graphite by weight - SP-22: for enhanced wear resistance, lower friction, improved dimensional stability, and stability against oxidation. Example: Vespel SP-22. ;10% PTFE and 15% graphite by weight - SP-211: added to the base resin for the lowest coefficient of friction over a wide range of operating conditions. It also has excellent wear resistance up to 149 °C. Typical applications include sliding or linear bearings as well as many wear and friction uses listed above. Example: Vespel SP-211. ;15% moly-filled - SP-3: for wear and friction resistance in vacuum and other moisture-free environments where graphite actually becomes abrasive. Typical applications include seals, plain bearings, gears, and other wear surfaces in outer space, ultra-high vacuum or dry gas applications. Example: Vespel SP-3.