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ASTM
D 1418 Designation: FKM
ASTM
D 2000, SAE J200 Type / Class: HK
STANDARD
COLORS: Black, Brown, Green
TRADE NAMES:
• DAI-EL® (Daikin Industries)
• Dyneon®, previously Fluorel® (Dyneon)
• Tecnoflon® (Solvay Solexis)
• Viton® (DuPont Dow Elastomers)
RELATIVE
COST: High
GENERAL
TEMPERATURE RANGE: -15° to +400° F
Also
referred to as fluoroelastomers, fluorocarbon compounds are thermoset elastomers containing
fluorine (see Figure 38).
Fluorocarbons make excellent general purpose O-rings
due to their exceptional resistance to chemicals,
oil, and temperature extremes (-15° to +400° F).
Specialty compounds can further extend the low temperature
limit down to about -22° F for dynamic
seals and about -40° F in static applications.
Fluorocarbons
usually have good compression
set resistance, low gas permeability,
and resistance to ozone and
sunlight. Over the last five decades, this remarkable
combination of properties has prompted the use
of FKM seals in a variety of demanding sectors.
Though they were initially formulated for use in
aerospace applications, FKM compounds are now widely
used in the automotive, appliance, fluid power,
and chemical processing industries.
Three
main factors contribute to the remarkable heat (see Table
8) and fluids resistance
of fluorocarbon compounds. First, there are extremely
strong bonds between
the carbon atoms comprising
the polymer backbone
and the attached (pendant) fluorine atoms. Under
most circumstances, these bonds cannot be broken,
and thus the polymer is not prone to undergo chain
scission (division of the macromolecular chains
into smaller, weaker, more susceptible segments).
Second,
fluorocarbons feature a high fluorine-to-hydrogen
ratio. In other words, fluorine (rather than hydrogen)
atoms fulfill the majority of the available bonds
along the material’s carbon backbone. Polymers
with a high level of fluorination have proven to
be extremely stable. A stable compound is less
inclined to react to, or be broken down by, its
environment.
Third,
the carbon backbone is fully saturated.
That is, it contains only single bonds between
the carbon atoms. It does not contain any of the covalent double
bonds present in unsaturated compounds.
Since double bonds are the focus for chemical attack,
the saturated structure of fluorocarbons renders
them impervious to harmful agents (such as oxygen,
ozone, and UV light)
that typically degrade unsaturated
materials.
FKM
PERFORMS WELL IN:
• Acids
• Aircraft engine
applications
• Gasoline (& alcohol
blends)
• Hard vacuum applications
• Low outgassing applications
• Petroleum products
• Silicone fluids & greases
• Solvents
FKM
DOES NOT PERFORM WELL IN:
• Amines
• Hot chlorosulfonic
acid
• Hot hydrofluoric
acid
• Hydrocarbons (nitro)
• Ketones
• Low molecular
weight esters & ethers
• Fireproof hydraulic
fluids (e.g. Skydrol®)
Depending
on the specific needs of your application, there
are a number of different fluorocarbon formulations
available for use. Though they may share some common
characteristics, these different types are distinguished
by their processing and end-use properties. Perhaps
the most well-known fluorocarbon manufacturer is
DuPont Dow Elastomers, to the point that the trade
name for their compound, Viton®, is often used
as if it were a generic term for FKM. In the interests
of simplicity, the following descriptions of some
of the most common FKM formulations will make use
of the DuPont “type” names.
The
original commercial fluorocarbon, Viton
A, is the general-purpose type and
is still the most widely used. Viton A is a copolymer of
vinyldiene fluoride (VF2)
and hexafluoropropylene (HFP). Generally composed
of 66% fluorine, Viton A compounds offer excellent
resistance against many automotive and aviation
fuels, as well as both aliphatic and aromatic
hydrocarbon process fluids and chemicals. Viton
A compounds are also resistant to engine lubricating
oils, aqueous fluids, steam, and mineral acids.
Viton
B fluorocarbons are terpolymers combining
tetrafluoroethylene (TFE) with VF2 and
HFP. Depending on the exact formulation, the
TFE partially replaces either the VF2 (which
raises the fluorine level to approximately
68%) or the HFP (keeping the fluorine level
steady at 66%). Viton B compounds offer better
fluids resistance than the Viton A copolymers.
Viton
GF fluorocarbons are tetrapolymers composed
of TFE, VF2, HFP, and
small amounts of a cure site monomer.
Presence of the cure site monomer allows peroxide curing of
the compound, which is normally 70% fluorine.
As the most fluid resistant of the various
FKM types, Viton GF compounds offer improved
resistance to water, steam, and acids.
Viton
GFLT fluorocarbons are similar
to Viton GF, except that perfluoromethylvinyl
ether (PMVE) is used in place of HFP. The “LT” in
Viton GFLT stands for “low temperature.” The
combination of VF2,
PMVE, TFE, and a cure site monomer is designed
to retain both the superior chemical resistance
and high heat
resistance of the G-series fluorocarbons.
In addition, Viton GFLT compounds (typically
67% fluorine) offer the lowest swell and
the best low temperature properties of the
types discussed here (see Table
9). Viton GFLT can seal in a
static application down to approximately -40° F.
A brittle
point of -50° F can be achieved through
careful compounding.
MATERIAL
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