Spring Type Spring Type |
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 | Compression |
System of Measurement System of Measurement |
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Length Length | Show |
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Length Length | Hide |
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Material Material |
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End Type End Type |
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 |  |
| Closed and Ground | Plain |
Rate Rate |
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DFARS (Defense Acquisition Regulations Supplement) DFARS (Defense AcquisitionRegulations Supplement) |
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Finish Finish |
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Shaft Type Shaft Type |
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 | Slotted |
For Hole Diameter For Hole Diameter |
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Breaking Strength Breaking Strength |
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Minimum Hardness Minimum Hardness |
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Wall Thickness Wall Thickness |
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Corrosion-Resistant Compression Springs
These springs are more corrosion resistant than standard compression springs. They're also easier to compress than standard compression springs. As you squeeze a compression spring, it pushes back to return to its original length. Rate is the amount of force required for every inch of compression or, for metric springs, millimeter of compression. The higher the rate, the harder it is to compress the spring.
302 stainless steel springs have good corrosion resistance.
316 stainless steel springs have excellent corrosion resistance.
Springs with closed and ground ends sit flat, so they won’t buckle.
For technical drawings and 3-D models, click on a part number.
| OD, mm | ID, mm | Wire Dia., mm | Compressed Lg. @ Max. Load, mm | Max. Load , lbs. | Rate, lbs./mm | Material | End Type | Specifications Met | Pkg. Qty. | Pkg. | |
85 mm Lg. | |||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|
| 11.6 | 8.4 | 1.6 | 37.9 | 31.77 | 0.68 | 302 Stainless Steel | Closed and Ground | DIN 2095 | 5 | 00000000 | 000000 |
| 11.6 | 8.4 | 1.6 | 62.98 | 15.11 | 0.68 | Passivated 316 Stainless Steel | Closed and Ground | __ | 1 | 00000000 | 0000 |
| 55 | 45 | 5 | 30.9 | 146.98 | 2.72 | 302 Stainless Steel | Closed and Ground | DIN 2095 | 1 | 00000000 | 00000 |
Slotted Spring Pins
Also known as roll, tension, split, and expansion pins, these pins have a slot along one side that you squeeze closed to install them into unthreaded holes. Once installed, they expand slightly, creating outward tension that holds them tight against the hole wall. These pins absorb shock and vibration in your system, and keep parts from loosening. They are often used as hinge pins, or to hold springs and power transmission components in place.
Install these pins into a hole slightly smaller than the pin diameter. They have at least one chamfered end, which means the end is angled to make insertion easier.
Breaking strength is measured as double shear, which is the amount of force required to break a pin into three pieces.
Some metric pins with the same diameter come in two different wall thicknesses. Thinner walls are more flexible, easier to install, and won’t weigh down your assembly as much as thicker pins. Layer a pin with a thin wall inside a pin with a thicker wall to increase the breaking strength. Make sure the slots are opposite one another for maximum strength.
Steel pins are strong and wear resistant.
Pins that meet specifications for ISO 8752 (formerly DIN 1481) or ISO 13337 (formerly DIN 7346) adhere to international standards for pin dimensions.
For technical drawings and 3-D models, click on a part number.
| Lg., mm | For Hole Dia., mm | Wall Thick., mm | Min. Hardness | Breaking Strength, lbs. | Specifications Met | Pkg. Qty. | Pkg. | |
21 mm Dia. | ||||||||
|---|---|---|---|---|---|---|---|---|
| 85 | 21 | 2 | Rockwell C42 | 37,700 | DIN 7346, ISO 13337 | 1 | 000000000 | 000000 |