|
|
METALON PRODUCT
FEATURES :
* Low co-efficient of friction
* With built-in lubricants, there
is no need for elaborate lubrication systems.
Water can also be
used to lubricate METALON bearings.
* High impact and abrasion resistance
* METALON
bearings can absorb punishing, random high shock loads. With its memory,
the bearing returns to its original
shape and size,
without cracking, deforming, or deteriorating.
* Long life, low wear
* METALON
materials are tough and have excellent wear resistance characteristics
in any environment: salt,
fresh or dirty water.
* Corrosion Resistant:
* Bearings made of METALONs,
a homogenous, non-metallic material, resist most types of corrosion at
the bearing surface
and between the bearing and the housing.
* High-pressure capability
* Machineable
* METALONs
are very versatile materials. You can turn, drill, tap, shape, jig
saw, mill all grades.
* Outperforms traditional bearing
materials
* METALONs
are tough, non-metallic, synthetic, polymer alloy, which provides exceptional
abrasion resistance. Combining
this with qualities
of flexibility and high load-carrying ability, they can withstand a great
amount of abuse in adverse
operating environments
often found in sleeve bearing applications. In fact, under many severe
conditions.
METALON
Industrial bush bearings out-perform bronze, Babbitt, Teflon, phenolic
and a host of other non-metallic
materials in providing
longer trouble-free operation.
IMPACT STRENGTH
Because of its exceptionally
high impact strength. METALONs possesses unusual
ability to absorb shock loads. They performs extremely well under vibration
and misalignment conditions.
SHAFT OR
MATING SURFACE WEAR
Since METALON
tends not to carry abrasives, shaft wear may be reduced when compared to
other bearing materials. In making an evaluation, however, shaft wear should
be related to length of service. If, for example, an METALON
- OILLON
bearing outwears extruded nylon by 2:1, a fair comparison of shaft wear
would be with the total wear down produced by two nylon bearings. In comparative
test, METALON - OILLON has caused less shaft
wear than the other METALON grades.
RESISTANCE
TO OIL, WATER, SOLVENTS, AND CHEMICALS
METALONs
possesses excellent corrosion resistance and resistance to oil, water and
chemicals. It is not affected by lubricants normally used with sleeve bearings.
METALON
absorbs approximately 0.6% water by volume under atmospheric conditions
and at a temperature of 23oC. This expansion is gradual and
may take up to 4,000 hours to complete, under static conditions. Under
dynamic conditions, absorption can occur much faster. The majority of the
expansion occurs, however, within the first 1,000 hours. If the pressure
or temperature is increased, not only does the volumetric swell percentage
increase, but also the rate of absorption. In tests using water at 60oC,
the volumetric swell increased to between 1.9% and 2.1% within 100 hours.
In practical tests, when hot water is not present, the average bore closure
effect of water absorption was 0.022 times the wall thickness. A conservative
indication of METLON's behavior in a wide
range of chemical environments is available in a “ Chemical Compatibility
Chart . In critical situations, testing of METALON
before putting bearings in actual operating equipment is recommended, by
immersion for 30-60 days, measuring sample
dimensions before and after immersion,
and also checking hardness. Any significant variance from the METALON
standard would indicate possible compatibility problems.
HYDROLYSIS
When METALON
is
subjected to immersion in hot water, i.e. above 60oC the material,
begins to deteriorate chemically. This deterioration or breakdown is called
hydrolysis. The surface of the material softens initially, and eventually
cracks and breaks appear throughout the material. METALON
is not recommended for use in hot water above 60oC
THERMAL
EXPANSION/CONTRACTION
METALON
has a higher coefficient of thermal expansion/contraction than metallic
bearing materials, although not as high as many “ plastics . This factor
offers a significant advantage when fitting bearings, as freezing causes
contraction and therefore makes fitting with interference fit very easy.
When bearings are subjected to higher temperatures, allowance must be made
for the reduced running clearance caused by thermal expansion. When METALON
bearings will operate in a cold environment, an appropriate amount of extra
interference must be provided to offset thermal contraction.
MALLEABILITY
Unlike plastics and metals. METALON
is not a malleable material. It resists the “ pounding out of shape which
frequently occurs when metal or plastic bearings are subjected to impact.
As wear clearance develops in conventional bearings, the increased potential
for “ hammering can cause rapid failure. It should be note that greater
clearances in METALON bearings as a design
consideration, will not result in this type of failure.
WATER FLOW
:
On full rotational bush bearings
where high PV's dictate that a forced water-cooling system is required,
the recommended minimum flow of @ 0.15 liters per millimeter of shaft diameter.
TEMPERATURE
:
METALON
stays flexible at temperatures down to 60o C. METALON
is not recommended for hot water or steam applications due to potential
Hydrolysis problems. Water over 60oC should be avoided unless
exposure times are short. An upper limit on environmental operating temperature
of 120oC is suggested and although test conducted in laboratory
where METALON bearings have successfully performed
at higher temperatures, physical properties of the material are reduced,
where operating temperatures in excess of 120oC are expected,
do not hesitate to consult us.
SELECTION
PROCESS :
In any bearing application, the
primary consideration is to ensure that the frictional heat developed in
the sliding action is either absorbed and dissipated by the surrounding
mechanism or that it is conducted away by a lubricant or coolant. There
must be a balance in the system where temperature equilibrium is reached,
and this must be below the temperature limit of the material. If not, bearing
failure will result. The secondary consideration is the type of environment
that the bearing is running in, e.g. very abrasive
or clean, as this will affect material selection.
For high pressure applications
where the frictional heat generated is not a factor due to either oscillating
motion or very slow speeds, the bearing needs to be designed
with a very high shape factor
NOTE: Frictional heat generated
in high-pressure applications must be dissipated at the same rate to
avoid seizure.
METALON-6 is recommended for
use where there is external lubrication available. It is
not recommended for dry running because of its high dry coefficient of friction.
This would apply to sliding applications where frictional
heat is retained. METALON
- OILON
is the most popular
grade and has a good balance of abrasive resistance and co-efficient
of friction. It is used for a variety of industrial and Pharmaceutical
applications and is stocked or
available in Rods, Sheets & Tubes
METALON - OILON has the best dry
running capability, abrasion resistance too It is the most
unique grade of METALON - OILON, and is becoming increasingly popular.
It is used in high-pressure thin walled bearings, and for highly loaded
rudder bearing applications where there is a risk of adhesive wear.
POLYACETAL & is used in the food industry in
non-food contact areas where
no grease is permitted. For food contact applications, a special FDA grade
is available. ERTALYTE is to be used. In the
manufacture of METALON Compact
bearings supported by a metallic sleeve to give rigidity to the
softer liner. These Composite bearings are available
as per customer's requirement.
DESIGN GUIDE SHAPE FACTOR
This term is used in connection
with elastomer engineering. It is influenced by wall thickness
and he bearing L/D ratio. Since an average
METALON - OILON bearing has an
L/D ratio of 1.25:1, and a wall thickness proportional to shaft
diameter, a typical shape factor of 8 can be used. Increasing the shape
factor can increase the load bearing capability of the bearing. The
METALON - OILON bush bearings are based on use of a high shape factor.
COMPRESSION-STRESS STRAIN
When a load is applied to
METALON,
it acts like a spring and moves in accordance with the force exerted
on it. This is generally referred to as “ compression , but in the case
of an elastomer such as
METALON the
material does not undergo a change
in volume, but rather a change in shape. The extent to which such
a change in shape can be acceptable in a bearing application depends
on the type of movement involved. We define
the maximum acceptable amount of deformation for full rotation
as 1.25% of the wall thickness. For oscillating movement this limit
can be extended to 4.0%.
PRESSURE-VELOCITY-TIME
In order to determine the feasibility
of using an
METALON bearing in a specific application, the factors
of pressure, velocity and time should be considered. The basic concern
with most non-metallic including
METALON is the risk of heat build-up,
and the ability of the assembly to dissipate of this heat. The
pressure on a bearing is the load applied divided by the loaded area. By
convention, the loaded area is calculated as the bearing length
multiplied by the shaft diameter. This is not entirely accurate, but
it is convenient. Velocity when applied to a
bearing configuration refers
to peripheral velocity (and not rpm) in either feet per minute or meters
per second. It is impossible to separate pressure and velocity
when dealing with a bearing application because both are potential sources
of frictional heat. They must be considered together. Our studies
have indicated that it is not possible
to publish absolute dry PV (pressure-velocity)
figures for the
METALON grades. We must consider the
specific combination of pressure and velocity and relate this to the
time factor (duty cycle) as this too influences the probability of
heat accumulation. If the assembly operates over a short duty cycle,
it has time to cool down between operations and therefore may
be able to accept higher pressure and velocity figures than a similar
assembly running continuously. Obviously lubrication has a major influence on
PV-T
limits, and therefore grooves are provided for dry, grease lubricated, oil
bath and water bath conditions. He PV-T graphs were developed using a
bath of oil or water. If the system can be designed to incorporate a
forced flow of lubricant instead of a bath, much of the frictional heat will
be dissipated by the flow of lubricant. Once the bearing is operating
under hydrodynamic conditions, no additional frictional heat is
develop as the speed is increased, other than a slight increase in frictional
drag of the lubricant. This increase is so low that it does not affect
the bearing operation. Velocity can be increased significantly (compared
to a bath-type system) as long as there is sufficient flow of cool
lubricant to dissipate the frictional heat generated.
| Back To Top |
| HOME | PRODUCTS | PROPERTIES | APPLICATION NOTES | ENQUIRY FORM |