Much of today’s bonded dry film lubricant coating technology has been developed over the past fifty years. The dominant dry film lubricant (DFL) materials attracting research studies and industrial applications have been molybdenum disulfide (MoS2), PTFE, and Graphite.

A bonded dry film lubricant is defined as a dry lubricant dispersed in a continuous matrix of a binder and/or attached to a surface by an adhesive material (or bond).

Dry film lubricants contain special pigments that reduce friction and wear by preventing surface-to-surface contact between mating parts (i.e., a shaft and its bearings). Performance properties vary depending on the specific lubricating pigment used. Some offer excellent lubrication and corrosion protection, while others operate at high temperatures. Some are formulated for use in extreme environments and can withstand nuclear radiation.

Dry film lubrication provides a thin film (.0003"-.0005") of resin with suitable lubricity pigments, such as molydisulfide, PTFE, or graphite. They provide a tough, durable boundary of solid film lubricant. DFLs have very low sheer strengths, low coefficients of friction (.02-.08), and withstand loads up to 250,000 psi. They are sprayed, dipped, or tumbled and then thermally cured to permanently bond the coating to a variety of different surfaces and substrates. Substrate material can influence the performance of bonded film lubricant coatings.

Surface chemistry, texture, form, and mechanical properties of the base materials have interacting roles with bonded film. Specific coatings have been developed with surface preparations and pretreatments for many base materials including: rubber, plastic, glass, wood, zinc, aluminum, titanium, chromium, nickel, copper, brass, stainless and other steels.