Practically any material that can withstand the sintering temperature of PTFE can be used as filler in PTFE. Characteristics such as particle shape and size, and the chemical composition of the filler greatly affect the properties of the compound. All fillers used in PTFE compounds have been carefully selected and were in several cases specially developed to give the best balance of properties. The following paragraphs discuss the main features of the most commonly used fillers.

GLASS FILLER IN PTFE:

Glass fibre is the most widely used filler in PTFE. It improves the creep resistance of PTFE, both at low and high temperature. It is chemically stable (except to strong alkalis and hydrofluoric acid - HF).It has little effect on the electrical properties of PTFE, and improves its wear and friction behavior. A not uncommon problem with glass-filled PTFE is discoloration of the finished parts, in particular on the inside of large billets. The glass used in PTFE compounds has been treated by a proprietary process to reduce this discoloration.

CARBON FILLER IN PTFE:

Amorphous carbon is one of the most inert fillers used in PTFE, except in oxidizing environments where glass performs better. Carbon adds to the creep resistance, increases the hardness and raises the thermal conductivity of PTFE. Carbon filled compounds have excellent wear properties, in particular when combined with graphite. The combination of the above properties makes carbon/graphite compounds the preferred material for non-lubricated piston rings. The use of softer carbon has the additional advantage that it lowers tool wear during machining, thus allowing machining to very close tolerances. Carbon-containing compounds have some electrical conductivity and are therefore antistatic.

CARBON FIBRE IN PTFE:

Addition of carbon fibre PTFE changes its physical properties in the same way as glass fibre does: Lower deformation under load, higher compressive and flex modulus and increased hardness. In general, less carbon fibre than glass fibre is needed to achieve the same effect. Carbon fibre is chemically inert and can be used in strong alkali and in HF, where glass-filled compounds fail. Compounds of PTFE with carbon fibre have the advantage of higher thermal conductivity and lower thermal expansion coefficients than glass-filled ones with the same filler percentages, and they are lighter. They wear less in contact with most metals, and are also less abrasive on the mating surface. The wear in water is particularly low. This makes carbon-fibre-filled PTFE an excellent bearing material, especially when lubricated with water. It is widely used in the automotive industry for bearings and seal rings, for example in water pumps and in shock absorbers.

GRAPHITE FILLER IN PTFE:

Graphite is a crystalline modification of high purity carbon & commonly used filler in PTFE. Graphite-filled PTFE has one of lowest coefficients of friction. It has excellent wear properties, in particular against soft metals, displays high load-carrying capability in high-speed contact applications and is chemically inert. It is often used in combination with other fillers.

Source:	synthetic
Purity:	> 99% C
Irregular shaped:
Particle size:	< 75 µm
Density:	2.26

BRONZE FILLER IN PTFE:

Bronze is an alloy of copper and tin. Addition of high percentages of bronze filler in PTFE results in a compound having high thermal conductivity and better creep resistance than most other compounds. Bronze-filled PTFE is often used for components in hydraulic systems, but is not suited for electrical applications and is attacked by certain chemicals. Bronze has a tendency to oxidize: bronze-filled compounds should therefore be used fresh and containers should always be kept closed. Some discoloration of the finished part during the sintering cycle is normal and has no impact on its quality.

Cu / Sn:	9 / l
Low in phosphorus:
Particle size:	< 60 µm
Particle shape:	Spherical (1146-N) Irregular (2146-N)
Density:	8.95

MOLYBDENUM DISULPHIDE (MoS₂) FILLER IN PTFE

Addition of Molybdenum Disulphide – MoS₂ filler in PTFE leads to improved hardness & stiffness & reduces friction. It has little effect on its electrical properties. It is quite unreactive chemically and dissolves only in strongly oxidising acids. It is normally used in low percentages and together with other fillers. Compounds containing molybdenum disulphide need special attention during preforming and sintering.