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ASTM
D 1418 Designation: FEP
ASTM
D 2000, SAE J200 Type / Class: None
STANDARD
COLOR: White
TRADE
NAMES:
• Algoflon® (Ausimont USA, Ltd.)
• Polyflon® (Daikin Industries, Ltd.)
• Teflon® (DuPont)
RELATIVE
COST: High
GENERAL
TEMPERATURE RANGE: -300° to +500° F
Polytetrafluoroethylene
(PTFE) is a completely fluorinated polymer produced
when the monomer tetrafluoroethylene
(TFE) undergoes free radical vinyl polymerization.
As a monomer, TFE is made up of a pair of double-bonded carbon atoms,
both of which have two fluorine atoms covalently
bonded to them. Thus the name: “tetra” means
there are four atoms bonded to
the carbons, “fluoro” means those bonded
atoms are fluorine, and “ethylene” means
the carbons are joined by a double bond as in the
classic ethylene structure. (Ethylene has hydrogen
atoms attached to the carbons, as in Figure
50, but TFE has fluorine in place of
the hydrogen, as in Figure 51.)
When TFE polymerizes into PTFE, the carbon-to-carbon
double bond becomes a single bond and a long chain
of carbon atoms is formed, as in Figure
52. This chain is the polymer’s
backbone.
With
a ratio of four fluorine atoms to every two carbon
atoms, the backbone is essentially shielded from
contact. It’s almost impossible for any other
chemical to gain access to the carbon atoms. Even
if an agent could gain access, the carbon-to-fluorine
bonds have high bond disassociation energy, so
they’re almost unbreakable. This makes PTFE
the most chemically resistant thermoplastic polymer
available. PTFE is inert to
almost all chemicals and solvents,
allowing PTFE parts to function well in acids, alcohols,
alkalis, esters, ketones, and hydrocarbons.
There are only a few substances harmful to PTFE,
notably fluorine, chlorine trifluoride, and molten
alkali metal solutions at high pressures.
PTFE
is also very slippery. By its very nature, the
fluorine in PTFE repels everything. As part of
a molecule,
fluorine is decidedly “anti-social.” Anything
getting close is repelled, and repelled molecules
can’t stick to the PTFE surface. This makes
PTFE perfect for applications requiring a low coefficient
of friction. The only thing slicker than PTFE is
ice! Because they are essentially self-lubricating,
PTFE parts are ideal for applications in which
external lubricants (such as oils and greases)
can’t be used.
PTFE
can withstand a wide range of temperatures (-300° to
500° F, -184° to 260° C). Because it’s
non-flammable and doesn’t dissipate heat,
PTFE is often used as a thermal insulator (as in
welding equipment). At the other extreme, PTFE
is widely used in very cold environments (such
as space). Other important properties include resistance
to both weathering and water absorption.
PTFE can also act as an electrical insulator.
Because
of its chemical inertness, PTFE cannot be cross-linked
like an elastomer.
Therefore it has no memory and
is subject to creep (also
known as cold
flow). Creep is the increasing deformation of
a material under a constant compressive load.
This can be both good and bad. A little bit of
creep allows PTFE seals to conform to mating
surfaces better than most other plastic seals.
Too much creep, however, and the seal is compromised.
Compounding fillers are
used to control unwanted creep, as well as to improve
wear, friction,
and other properties.
Keep
in mind that PTFE fillers don’t act like
elastomer fillers, which become chemically bonded
to the elastomer. With polytetrafluoroethylene,
the high shear
modulus fillers are encapsulated and
bound by the low shear modulus PTFE. Because it
does not possess a good elastic memory at or below
normal temperatures, PTFE may need to be heated
to facilitate installation. PTFE has poor cut resistance,
so extra care must be taken not to damage seals
during installation.
PTFE
FILLERS
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| 1. |
Glass is
the most common filler for PTFE. Widely used
in hydraulic piston rings, glass gives good
wear resistance, low creep, and good compressive
strength. Glass also has excellent chemical compatibility.
The major disadvantage is that glass-filled
PTFE compounds are abrasive to
mating surfaces, especially in rotary applications. |
| 2. |
Molybdenum
disulfide (MoS2) improves
wear resistance and further lowers the
coefficient of friction. “Moly” is
typically combined with other fillers (such
as glass and bronze). |
| 3. |
Carbon (powder
or fiber) imparts excellent compression (low
deformation under load) and wear resistance,
good thermal conductivity (heat dissipation),
and low permeability.
Carbon-filled PTFE compounds are
not as abrasive as glass-filled compounds,
but they are still more abrasive than polymer-filled
compounds. Carbon-filled compounds have excellent
wear and friction properties when combined
with graphite. Carbon fiber lends better creep
resistance than carbon powder, but fiber is
more expensive. |
| 4. |
Graphite is
a crystal modification
of high purity carbon. Its flaky structure
gives great lubricity and decreased wear. Graphite
is often combined with other fillers (especially
carbon and glass). |
| 5. |
Bronze (a
copper-tin alloy) lends excellent wear resistance
and thermal conductivity. Bronze-filled materials
have higher friction than other filled PTFE
compounds, but that can be improved by adding
moly or graphite. Bearing and piston ring applications
often use compounds containing 55% bronze -
5% moly. Bronze-filled compounds have poorer
chemical resistance than other PTFE compounds. |
| 6. |
Stainless
steel supplies
high wear resistance and load bearing capability,
along with better chemical resistance than
bronze-filled PTFE. Stainless steel is
especially good in steam service. |
| 7. |
Wollastonite
(calcium silicate) is a
mineral filler giving properties similar
to glass (minus the abrasiveness). The FDA has
approved it for food service. |
| 8. |
PPS
(polyphenylene sulfide, trade name Ryton®) was
the first polymeric material used to improve
PTFE’s wear and abrasion properties.
PPS-filled compounds also exhibit excellent
deformation and extrusion resistance,
making them good for use in back-up
rings. |
| 9. |
Ekonol® is
a thermally stable aromatic polyester.
When blended with PTFE, it produces a composite
material with excellent high
temperature and wear resistance. Ekonol® will
not wear mating metal surfaces, making it good
for rotary applications. Ekonol®-filled
materials are also good for food service. |
| 10. |
Polyimide is
another polymeric filler offering superior
wear and abrasion
resistance. Polyimide-filled PTFE compounds
have about the lowest friction properties of
all filled PTFE materials, so they’re
great in non-lubricated (dry) applications.
They will not abrade mating surfaces (even
soft materials like brass, stainless steel,
aluminum, and plastic). Polyimide is one of
the most expensive PTFE fillers, however. |
| |
Other
fillers include calcium fluoride (CaF2),
which is specifically used in hydrofluoric
acid (HF) service, and alumina (Al2O3),
which can improve the mechanical properties
of compounds destined for high voltage applications.
Alumina-filled compounds are very abrasive. |
MATERIAL
PROFILES MAIN PAGE
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“The
inability of other materials to stick to PTFE makes
it perfect for applications requiring a low coefficient
of friction.”
Figures 50-52
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