Use these springs in noncorrosive environments.

Made of stainless steel, these springs are more corrosion resistant than steel compression springs.

These springs meet MS24585 and come with a traceable lot number and material test report.

Made of stainless steel, these springs are more corrosion resistant than steel compression springs.

If you're designing something unique or can't find the exact size spring you need, we'll get it for you.

These springs handle higher loads than standard fastener-mount compression springs. Secure by inserting a fastener through the hole at the base.

Flanges on the ends of these springs provide a flat mounting surface.

Protect dies from damage caused by spring failure. Cages enclose springs to retain fragments if they break.

These stainless steel anchor studs offer excellent corrosion resistance.

These stainless steel anchor studs offer excellent corrosion resistance.

The wide flange provides better load distribution than standard external push rings and can be used to cover oversized holes. Also known as thread cutting nuts.

Also known as flat-style speed nuts, these have a large surface to distribute loads better than standard and flanged external push rings.

Also known as X-washers, place these rings into the groove and squeeze tight with pliers to form a 360° closure.

Also known as E-style rings.

These rings are reinforced to withstand faster rotation than other side‐mount retaining rings. Also known as reinforced E‐style rings.

Slide these rings into a groove near the end of the shaft and the tab locks them in place.

These rings meet military specification MS 16624.

No groove is required for these rings—their thick profile helps them grip the shaft.

For a smooth profile and better clearance than standard external retaining rings, the lugs on these rings point inward.

Also known as constant-section rings, these rings have open ends and a profile that does not taper like other external retaining rings. Use them with linear bearings on support rail shafts.

Thicker than standard spiral rings, these rings withstand greater forces.

Squeeze these rings to place them in the groove inside a bore or housing.

With teeth along the inside, these retaining rings hold chamfered shafts inside the housing of your equipment.

The curved design of these rings works like a spring, taking up play for a tight hold.

Slide these rings into place by hand with a single twist for applications with high thrust loads.

The spring holds the washer and toggle against opposite sides of the wall, so everything's in position before you begin tightening. Once tightened, the spring adds vibration resistance.

Drill holes with the point on these hangers.

You can use these versatile hangers in a threaded hole (as you would a screw), or secure them with a nut (as you would a bolt).

Pull ring ends together with retaining ring pliers and place into the bore of a shaft or housing.

These assortments include pliers to install external and internal rings.

Pull these rings open with retaining ring pliers, pass over the end of a shaft, and release to spring into a groove.

A flange distributes the load over a large area and reduces stress where the nut meets the material surface.

With flexible teeth that slide smoothly over threads of any pitch, these push nuts can be used alone for light-duty applications or as a jam nut.

Loop these rings onto tags.

The pin on these retainers is permanently connected to the ring, so they're less likely to dislodge when used with an impact wrench compared to two-piece retaining rings.