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Item # PC02-2004.CA
Item # PC02-2004.CA, Tribolube-2N, 4-Oz. Cartridge
List Price $112.35
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Conforming to MIL-PRF-83261B requirements, the outstanding qualities of Tribolube-2N is its wide operating temperature range, extreme pressure and antiwear characteristics, non-migratory nature, low foreign and/or opaque particle content, high resistance to microwave energy, and its compatibility with plastic and elastomeric seals. Shelf life exceeds 10 years.
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Type of Lubricant
High Performance Synthetic Grease
-100 to 450
Unworked Penetration @ 77 ºF
Worked Penetration @ 60 Strokes
Worked Stability @ 100000 Strokes
Evaporation 22 hrs @ 400 ºF
Weld Point @ Load
Evaporation 22 hrs @ 450 ºF
Oil Separation 30 hrs @ 400 ºF
Oil Separation 30 hrs @ 450 ºF
Water Washout- 1 hr @ 105 ºF
Bomb Oxidation- 100 hrs @ 250 ºF
Dirt Count- 10 - 34 microns
Dirt Count- over 35 microns
Coef. of Friction @ 1200 rpm. 90 ºF. 15 kg load
Load Wear Index
Last Non-Seizure @ Load/Wear Scar
Last Seizure @ Load/Wear Scar
Steel-on-Steel Wear @ 1200 rpm. 40 kg. 167 ºF. 2 hrs. 52100 steel
Steel-on-Steel Wear @ 1200 rpm. 40 kg. 167 ºF. 1 hrs. 52100 steel
Steel-on-Steel Wear @ 1200 rpm. 40 kg. 450 ºF. 2 hrs. M-50 steel
High Temperature Performance @ 450 ºF. 20000 rpm. 5 lbs
High Temperature Performance @ 450 ºF. 10000 rpm. 5 lbs
High Temperature Performance @ 400 ºF. 10000 rpm. 5 lbs
Low Temperature Torque
@-100 ºF. Starting
Low Temperature Torque
@-100 ºF. Running
Low Temperature Torque
@-65 ºF. Starting
Low Temperature Torque
@-65 ºF. Running
Rubber Swell Buna "N"- 168 hrs @ 158 ºF
Rubber Swell Buna "N"- 72 hrs @ 275 ºF
Rubber Swell Viton "B"- 168 hrs @ 158 ºF
Rubber Swell Viton "B"- 168 hrs @ 300 ºF
Rubber Swell Fluorosilicone- 168 hrs @ 158 ºF
Rubber Swell Fluorosilicone- 72 hrs @ 300 ºF
Rubber Swell Neoprene- 168 hrs @ 158 ºF
Rubber Swell Neoprene- 72 hrs @ 300 ºF
Aircraft actuators, gears, gimbal rings, oscillation bearings, antifriction and plain spherical bearings. It is especially suitable for use in applications using miniature bearings. Blower motors, motor generators, plastic clutches and gears, servo motors, microwave ovens, speedometer cables, motorcycle and automotive distributors, typewriters, business machines, etc. Other applications include sub-fractional horsepower gear motors, camera drive systems, microswitch assemblies, reduction gears, and scientific instruments.
Worked Penetration @60 Strokes - 270-350
Worked Stability @ 1,00,000 Strokes - 375 max.
Dropping Point - 450 ºF
Evaporation 22 hrs @ 450 ºF - 15 % max.
Oil Separation 30 hrs @ 45 ºF - 25.0 % max.
Water Washout 1 hr @ 105 ºF - 20.0 % max.
Load Wear Index - 90 min.
Steel-on-Steel Wear 1,200 rpm, 40 kg, 167 ºF, 2 hrs, 52100 Steel - 1.30 mm max.
Steel-on-Steel Wear 1,200 rpm, 40 kg, 450 ºF, 2 hrs, M-50 Steel - 1.30 mm max.
High Temperature Performance 450 ºF, 20,000 rpm, 5 lbs. - 500 hrs min.
High Temperature Performance 450 ºF, 10,000 rpm, 5 lbs. - 500 hrs min.
Low Temperature Torque @ -100 ºF, Starting - 5,000 gm-cm max.
Low Temperature Torque @ -100 ºF, Running - 1,000 gm-cm max.
Function of Lubricating Greases
A good quality lubricant reduces friction and wear, dissipates heat, keeps out dirt, and prevents rust formation. It must provide good "boundary layer" lubrication, and be thin enough to get between moving parts, and once there, it must be thick enough to separate them with a slippery oil film. This oil film must be strong enough to provide full-film "hydrodynamic" lubrication between moving parts such as bearings, screw actuators, etc. It must also act as a kind of floating seal, filling in the microscopic imperfections in moving surfaces with a thin film of lubricant.
If it is too thin, under shock or extreme loads it will not separate moving surfaces. If it is too thick, it cannot squeeze between the moving parts to provide proper lubrication. If either extreme exists, friction and wear occurs; accumulating wear debris escalates wear until failure occurs.
Heat is generated between moving parts in machines, even though they are lubricated. Some greases can reduce the operating temperatures of bearings , gears, or other moving parts by having better EP and anti-wear properties thereby reducing the metal to metal contact and the associated heat. Grease lubricants also work as a seal, keeping out dirt and other foreign matter, thus preventing damage to the bearing and contact surfaces. The effect of rust or corrosion on unprotected metal can readily be understood. A lubricating film on moving parts protects them from this damage by preventing contact with air, moisture or other corrosive agents thereby increasing useful life.
Properties of Synthetic Lubricating Greases
In general, a grease is an oil that has been thickened by a solid or semisolid dispersion, commonly a clay or a soap, in a petroleum or synthetic lubricating fluid, plus the desired additives used to enhance grease performance properties.
Composition of Lubricating Greases
Petroleum or Synthetic
55% - 96%
Soap or Non-Soap
4% - 45%
0% - 20%
All of the grease components affect the physical and chemical properties. Standardized testing must be used to provide useful information about the properties of grease lubricants. Such information can then be used to compare and select a grease for a specific application. Some of these tests are described in following sections.
Purpose of Synthetic Lubricants
Demands placed upon lubricants have become increasing severe with advances in industrial machinery and equipment design. Higher operating temperatures, speeds and gear and bearing loads are stressing the capabilities of conventional petroleum-based lubricants. The OEM's have increased demands for "sealed for life" applications. Such applications require synthetic lubricants.
Synthetic lubricants were developed to meet demanding requirements which exceed the operational limits of conventional petroleum based lubricants. Because they are man-made , synthetics can be better tailored to their role as a lubricant by meeting predetermined physical and chemical properties. Formulated from pure hydrocarbons, synthetics do not contain the impure components that adversely affect the physical and chemical stability of petroleum based lubricants.
Synthetic oil and grease lubricants have been solving demanding lubrication problems by replacing petroleum lubricants in applications that exceed their environmental, operational, or service life limitations. In such applications, synthetics pay for themselves many times over in reduced component failure, repair costs, warranty costs, down time, and increased service life.
Synthetic vs Petroleum Lubricants Performance Both oil and grease lubricants made from synthetic based fluids have a much wider operating temperature range and are more thermally and oxidatively stable than lubricants made from petroleum-based fluids. Low Temperature Performance
At very low temperatures, most petroleum-based oil and grease lubricants thicken and are usually limited to temperatures no lower than -20 ºF unless high temperature performance is sacrificed. In contrast, synthetic oil and grease lubricants have good low temperature viscosity and fluidity characteristics down to as low as -140 ºF, and are still capable of operating at temperatures as high as 600 ºF.
High Temperature Performance
Lubricants are susceptible to failure at high temperature, especially in thin films after long term exposure. Recent research in boundary lubrication confirms the primary role of high temperature in lubricant degradation. Increasing temperature rather than increasing shear load has been found to induce most lubricant failures. Petroleum-based oil and grease lubricants have an upper temperature limit of about 250 ºF to 300 ºF. Above these temperatures they become fluid and volatile. If grease lubricated machinery is operated above that temperature limit, the lubricant breaks down and may melt or form hard carbon deposits. Some synthetic grease lubricants can operate up to about 600 ºF without melting.
Oxidation is the primary breakdown mode of most lubricants, leading to the formation of sludge and other corrosive compounds. When lubricants are exposed to air, oxygen, or other strong oxidizing chemicals, petroleum- based lubricants deteriorate and break down easily, especially at high temperatures. Many chemicals can attack petroleum-based lubricants resulting in gummy deposits. Lubricant failure may result in corrosion of parts, deterioration of seals, stuck or worn bearings, and product contamination. This results in frequent equipment down time for relubrication, replacement of parts, cleaning, and maintenance. The thermal and oxidative stability of synthetics often makes them the only alternative for very cold, extremely hot, sealed for life applications, or harsh operating environments.
Dust, dirt, and other debris can create additional problems for petroleum-based lubricants. These lubricants tend to attract contaminates because they are naturally occurring compounds which have unreacted molecular end groups. These end groups produce electrical charges at the surface, so when a charged dust or dirt particle comes near, they are attracted to the surface of the lubricant. The dust particles can be abrasive and damage parts and machinery. It is this characteristic of petroleum-based lubricants that create problems in dusty and dirty applications such as paper and textile mills, printing plants, and metal-forming operations. This situation leads to frequent machine down time for cleaning and relubrication. Because synthetics are man-made , they are fully reacted chemicals and do not have the unreacted end groups which attract dust and dirt. Wear of moving parts can thus be reduced in dusty environments.
Load and Wear Performance
Synthetics lubricants can provide increased wear protection over petroleum-based lubricants due to better viscosity-temperature properties. Tribolube Synthetic Lubricating Oils and Greases are specially formulated to function in applications or environmental conditions where standard "general purpose" lubricants will not perform or will perform only marginally. Tribolube lubricants outperform conventional lubricants under conditions such as hard vacuums, low and high operating temperatures, oxidizing environments, high rotating speeds, extremely high load conditions, applications where little wear can be tolerated, high radiation levels, extremely corrosive environments, and where long life is mandated.
What are the Pay Offs?
The failure of petroleum lubricants to give adequate performance is making greases and oils formulated from synthetic hydrocarbon fluids increasingly attractive. Reduced maintenance costs for manpower and replacement parts, and reduced downtime with associated production loss, make synthetic lubricants cost effective in most applications. The demand for lubricant stability over increasingly wider ranges of operating conditions exceeding the capability of petroleum lubricants is making synthetics mandatory in many OEM applications. The failure of petroleum lubricants to give adequate performance is making greases and oils formulated from synthetic hydrocarbon fluids increasingly attractive. Reduced maintenance costs for manpower and replacement parts, and reduced downtime with associated production loss, make synthetic lubricants cost effective in most applications. The demand for lubricant stability over increasingly wider ranges of operating conditions exceeding the capability of petroleum lubricants is making synthetics mandatory in many OEM applications.
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