MOP-C
Cleanroom / Vacuum / Heat Resistant Coupling – Oldham-Type (PEEK) – Clamping Type
Dimension Drawing
Dimensions/Specifications/CAD
Part Number | A | L | W | E | F | G | M | Wrench Torque (N・m) |
---|---|---|---|---|---|---|---|---|
MOP-20C | 20 | 7 | 22.1 | 10 | 3.5 | 6.5 | M2.5 | 1 |
MOP-25C | 25 | 8 | 27.2 | 14 | 4 | 9 | M3 | 1.5 |
MOP-32C | 32 | 10 | 33.3 | 18 | 5 | 11 | M4 | 2.5 |
Part Number | Max. Bore Diameter (mm) | Rated Torque* (N・m) | Max. Torque* (N・m) | Max. Rotational (min-1) | Static Torsional Stiffness (N・m/rad) | Max. Lateral Misalignment (mm) | Max. Angular Misalignment (°) | Mass** (g) |
---|---|---|---|---|---|---|---|---|
MOP-20C | 8 | 0.7 | 1.4 | 31000 | 93 | 1.3 | 2 | 13 |
MOP-25C | 10 | 1.2 | 2.4 | 25000 | 140 | 1.5 | 2 | 24 |
MOP-32C | 14 | 2.8 | 5.6 | 19000 | 350 | 2 | 2 | 48 |
* Correction of rated torque and max. torque due to load fluctuation is not required.
** These are values with max. bore diameter.
Part Number | Stock Bores D1-D2 | ||||||
---|---|---|---|---|---|---|---|
5 | 6 | 8 | 10 | 11 | 12 | 14 | |
MOP-20C | ● | ● | ● | – | – | – | – |
MOP-25C | – | – | ● | ● | – | – | – |
MOP-32C | – | – | – | ● | ● | ● | ● |
All products are provided with hex socket head cap screw.
Recommended dimensional allowances of applicable shaft diameter are h6 and h7.
In case of mounting on D-cut shaft, be careful about the position of the D-cut surface of the shaft.
Material/Finish
MOP-C | |
---|---|
Hub | A2017 |
Spacer | PEEK (Polyether ether ketone) |
Hex Socket Head Cap Screw | SUSXM7 |
PEEK’s color may vary depending on the lot or other matters.
Structure
clamping type
Characteristics
- Property
MOHS Low Particle △ Vacuum-supported ◎ Less Outgas ○ Heat-resistance ◎ Chemical-proof ○ Allowable Misalignment ◎ Electrical Insulation ◎ Cleanroom Specification ◎ Allowable Operating Temperature -20℃ to 200℃ ◎: Excellent ○: Very good
△: Abrasion powder may be produced - This is an oldham-type flexible coupling.
- Clean washing and clean packaging are completed. It can be used in an environment or cleanroom where heat resistance and chemical resistance are required, such as FPD manufacturing device.
- VESPEL SPC5000 is adopted in the spacer.
This is superior in heat resistance and chemical resistance, and the amount of outgas at high temperature is ultralow. - Slippage of hubs and a spacer allows eccentricity and angular misalignment to be accepted.
- The load on the shaft generated by misalignment is small and the burden on the shaft is reduced.
Application
FPD manufacturing device/Semiconductor manufacturing device
PEEK’s chemical resistance
Chemical name | PEEK |
---|---|
10% hydrochloric acid | ○ |
10% sulfuric acid | ○ |
50% sulfuric acid | × |
10% nitric acid | ○ |
50% nitric acid | × |
50% hydrofluoric acid | × |
10% phosphoric acid | ○ |
Formic acid | △ |
10% acetic acid | ○ |
Citric acid | ○ |
Chromic acid | ○ |
Boric acid | ○ |
Methyl alcohol | ○ |
Glycol | ○ |
Ammonia | ○ |
10% sodium hydroxide | ○ |
10% potassium hydroxide | ○ |
Calcium hydroxide | ○ |
Hydrogen sulfide (gas) | ○ |
Sulfur dioxide | ○ |
Ammonium nitrate | ○ |
Sodium nitrate | ○ |
Calcium carbonate | ○ |
Calcium chloride | ○ |
Magnesium chloride | ○ |
Magnesium sulfate | ○ |
Zinc sulfate | ○ |
Hydrogen peroxide | ○ |
○: Available △: Fair pending on condition
×: Not available
This is test data with a specimen used at room temperature (23°C).
The chemical resistance varies depending on the usage conditions. Be sure to perform a test under the same usage conditions as in actual usage in advance.
PEEK’s physical properties
Property | Test Method | unit | PEEK |
---|---|---|---|
Tensile Strength | D638 | N/mm2 | 97 |
Tensile elongation | D638 | % | 65 |
Bending Strength | D790 | N/mm2 | 156 |
Bending elastic modulus | D790 | GPa | 4.1 |
Izod impact value (with notch) | D256 | J/m | 94 |
Rockwell hardness | D785 | R / M Scale | M99 |
Deflection Temperature Under Load (1.82MPa) | D648 | ℃ | 152 |
Combustibility | UL94 | – | V-0 |
Dielectric Constant (106 Hz) | D150 | – | 3.3 |
Dielectric loss tangent (106 Hz) | D150 | – | 0.003 |
Volume resistivity (x1014) | D257 | Ω・m | 4.9 |
Insulation Breakdown Strength | D149 | MV/m | 17 |
Arc resistance | D495 | sec | 23 |
Specific gravity | D792 | – | 1.3 |
Water absorption (in 23°C water x 24 h) | D570 | % | 0.5 |
Content by percentage of glass fiber | – | % | 0 |
Analysis of outgas
Component | Content | |
---|---|---|
Inorganic gas | Hydrogen | 500 or less |
Carbon monoxide | 500 or less | |
Carbon dioxide | 500 or less | |
Organic gas | Methane | 5 or less |
Ethane | 5 or less | |
Ethylene | 5 or less | |
Propane | 5 or less | |
Acetylene | 5 or less | |
i-butane | 5 or less | |
n-butane | 5 or less | |
Propylene | 5 or less |
Both inorganic gas and organic gas are not more than the lower limit of determined amount and are not detected.
- Measurement Methods
Inorganic gas —- Gas chromatography (TCD)
Organic gas —- Gas chromatography (FID) - Measurement Conditions
Heating temperature —- 100℃
Spacer’s projection structure
Spacer’s projection structure allows large angular to be effortlessly accepted. It reduces burden on the shaft.
In the Oldham-type coupling whose spacer has no projection, the spacer and hubs interfere with each other near outside diameter, so that the max. angular misalignment is small (1° – 1.5°) and that the bending moment arises on the shaft.
NBK’s oldham type coupling allows the angular misalignment to be easily accepted since the projection serves as support. Bending moment does not arise. Therefore, the max. angular misalignment is large (2°) and the burden on the shaft is reduced.
Change in static torsional stiffness due to temperature
This is a value under the condition where the static torsional stiffness at 20°C is 100%.
The change of MOHS in torsional stiffness due to temperature is small and the change in responsiveness is extremely small. However, if the unit is used at higher temperature, be careful about misalignment due to elongation or deflection of the shaft associated with thermal expansion.
Eccentric Reaction Force
These are initial slippage load values of hubs and a spacer.
After running-in operation, the slippage load becomes small, the load on the shaft due to misalignment becomes lowered, and the burden on the shaft bearing is reduced.