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Position components in assemblies, as well as separate or connect parts with these standoffs.
The magnetic end of these standoffs makes it easy to temporarily mount or reposition components on magnetic surfaces.
A nickel-chrome plating gives these standoffs a mirror-like finish.
Also known as captive standoffs, a recess under the hex clinches the panel for a strong hold that won't push, pull, or twist out. When mounted, the hex sits flush with the surface and the closed end creates a neat, finished appearance.
A recess under the hex clinches a panel for a strong hold that won't push, pull, or twist out. When mounted with a lever press, the hex sits flush with the surface and the open end creates a through hole.
Use these barrels with a screw you already have or pair with a different type of screw to create a custom fastener. They're zinc plated to resist corrosion in wet environments.
Designed with a shoulder for the strength to handle side and shear loads.
Shorter than shoulder screws for use in thin material.
These include a barrel and a screw.
Add length to a binding barrel.
An unthreaded barrel allows quick assembly with a press or a hammer.
Create strong joints in wood and wood composite.
Sealed with PVC foam under the head to prevent leaks and keep contaminants out.
Without a head to get in the way, these screws fit in tight spaces where standard shoulder screws cannot. Either thread them in a countersunk hole for a flush mount, or install them with the shoulder sticking out to use them as pins or dowels for aligning and locating components.
Comparable to Grade 8 steel, these screws are the strongest precision shoulder screws we offer.
Comparable in strength to Grade 8 steel. These screws have inch thread sizes.
Comparable to Class 12.9 steel.
With threads the same diameter as the shoulder, these inch-sized screws can handle heavy loads. They’re comparable to Grade 8 steel.
The metric-sized threads on these screws are the same diameter as the shoulder. Comparable in strength to Class 12.9 steel.
These shoulder screws come with a traceable lot number and material test report. Similar in strength to Grade 8 steel.
Use these screws in thin materials; they have a shorter threaded portion than our standard shoulder screws. They’re comparable in strength to Grade 8 steel.
With a reduced head size and an unthreaded shoulder, use these screws as a shaft or dowel pin for small rotating parts in low-clearance applications.
The head height of these screws is about two-thirds the head height of a standard shoulder screw. Use them in low-clearance applications such as inside machines.
These metric screws have a head height that's about two-thirds the head height of a standard shoulder screw. Use them in low-clearance applications such as inside machines.
A locking element on the threads adds friction to resist loosening. Comparable to Grade 8 steel, these alloy steel shoulder screws are the strongest we offer.
Available in metric sizes, these screws have a locking element on the threads that adds friction to resist loosening. Comparable to Grade 8 steel, they are the strongest screws we offer.
These have a head height about one-third the head height of a standard shoulder screw.
A zinc plating provides mild corrosion resistance.
Also known as wheel and axle bolts, these metric screws have an unthreaded shoulder that acts as a shaft, so material attached to the threaded end can rotate.
Screw the threaded end of these metric studs into a tapped hole and use the unthreaded end as a pivot point, hinge, shaft, or locator pin.
Stick these studs to nearly any surface for a strong bond and a watertight seal.
These steel studs are zinc plated to resist corrosion in wet environments.
These studs are also known as hanger bolts—use them to hang, mount, and fasten parts to wood structures.
Add a stud to thin material when you only have access to one side.
Weld these studs to uncoated steel surfaces.
Pass these studs through a hole and weld them in place.
Also known as dowel screws, use these to join two pieces of wood.
The shoulder’s diameter is slightly smaller than listed, so these studs fit most machinery and equipment.
In addition to joining male- and female-threaded parts, these adapters can increase or decrease metric thread sizes and change the thread pitch.
Change thread sizes or types, such as fine to coarse threads, on parts without changing gender.
Change inch threads to metric with these adapters, or swap metric threads for inch. An external hex lets you tighten or loosen them with a wrench.
Often called sleeve nuts, these thread adapters fasten parts with right-hand threads to parts with left-hand threads.
Increase or decrease metric thread size from one male-threaded part to another. Commonly used to connect two differently sized threaded rods, they have a hex-shaped body, so you can tighten them with a standard wrench.
Connect two differently sized male-threaded parts, such as threaded rods, and tighten with a standard wrench.
Adapt threaded rods from inch to metric. These adapters connect two male-threaded fasteners, so you can change the gender of a mating part or increase or decrease its thread size. The hex-shaped body fits into the head of a standard wrench.
Twist these adapters onto female metric threads to change pitch or switch thread sizes.
One side inch, one side metric, and a hex in the middle—these handy fasteners connect two female-threaded parts, such as coupling nuts, adapting from inch threads to metric. Tighten with a standard wrench.
Need to join two female-threaded parts, such as coupling nuts, with dissimilar inch thread sizes? Attach them to these adapters and tighten the exterior hex nut for a secure connection.
Use these metal dowel pins as pivots, hinges, shafts, jigs, and fixtures to locate or hold parts.
Slip these pins in and out during maintenance or prototyping—they’re undersized to make alignment easier.
Oversized to fit worn and enlarged holes, these pins work well as repair and replacement parts.
To remove these pins, thread a screw or tool into the tapped hole, then pull them out.
The flat side of these pins relieves trapped air, making them easier to insert in and remove from blind holes. To remove, thread a screw or tool into the tapped hole, then pull the pin out.
A spiral groove cut into these pins relieves trapped air but stays in 360° contact with the hole for a secure fit that's easy to insert in and remove from blind holes. To remove, thread a screw or tool into the tapped hole, then pull the pin out.
These pins are commonly used as anchors for tension springs. The grooved half locks pins in position, and spring ends fit in to the notch. Also known as type G pins.
These pins make good hinges or pivots. The grooved half locks pins in position, while the smooth half can act as a pivot. Also known as type H pins.
Grooves hold these pins in place, and a round head gives them a finished appearance.
Quarter-groove pins are well suited for hinges or pivots. The grooved end locks pins in position, while the smooth portion can act as a pivot. Also known as type C pins.
Center-groove pins are often used in place of clevis pins or to create T-handles. The grooved center locks pins in position, while the smooth ends act as a pivot. Also known as type E pins.
Grooves run the full length of these pins for a firm hold that won't spin. Use them in place of standard dowel, spring, and taper pins to fasten parts. Also known as type A pins.
Use these as pivot or hinge pins. The knurled half locks pins in position, while the smooth half acts as a pivot.
The full length of these pins is knurled for a tight grip that won't spin.
Center-knurled pins are often used in place of clevis pins or to create T-handles. The knurled center locks pins in position, while the smooth ends act as a pivot.
Pass wires and other components through these hollow pins.
Barbs bite into plastics and soft metals such as aluminum for a strong hold, and a round head gives a finished appearance.
Use these pins to fasten components made of soft materials such as plastic or aluminum. Opposing barbs bite into each piece, pulling them together for a tight, secure fit.
Dowel pins are commonly used as pivots, hinges, shafts, jigs, and fixtures to locate or hold parts. They're slightly oversized for a tight fit.
Shoulder screws have a cylindrical shoulder under the head that allows parts to rotate around or slide along its length. They have a standard shoulder with an undersized tolerance to fit most machinery and equipment.
Restrict and grant access to an area—these bollards act as a strong physical barrier and have a hinge to fold flat against the ground in either direction.
These bollards flex slightly when bumped by a vehicle to prevent dents and dings.
Combine rails, posts, and gates to make a custom guardrail system.
Start with two bases and then stack rails to the desired height.
These are the same guardrails you see along roadways.
During light collisions, these guardrails tilt to absorb impact and minimize damage to a vehicle.
These guardrails sit low to the ground to protect racks and equipment without restricting access.
Modular mix-and-match components allow flexible railing configurations.
Combine bases, rails, gates, and toeboards to create a barrier customized to your needs. Base is weighted to allow installation without drilling holes.
Weighted bases allow you to install these railings without drilling holes.
No assembly required with these one-piece railings.
Connect rails and posts with included slip-on fittings to quickly assemble a railing.
Rails are drilled with consistently spaced holes for multiple mounting options that do not require machining. Use this steel bolt-together framing to build guards, tables, and racks.
Create posts of varying lengths.
To provide corrosion resistance in wet environments, this framing is galvanized.
Support beams and joists.
Give open-ended standoffs a finished look and protect them from dirt and debris.
Weld these caps and targets to the ends of posts to create stackable shelving and racking systems.
Secure and hold up fencing with these posts.
Stand panels up to create enclosures without sinking posts into the ground.
Support trench walls when installing pipes, cables, and other buried equipment.
Drive these stakes into the ground and then slide a foam or corrugated plastic sign over the top.
Internal threads allow you to mount these shafts onto threaded studs and fasteners, no shaft supports needed.
Mount these externally threaded shafts into tapped holes rather than using a shaft support, or attach a hex nut, shaft collar, or other threaded accessory.
Combine these general purpose shafts with a linear bearing and shaft support to create a basic linear motion system.
Lighter than solid shafts, hollow shafts reduce your total system weight and allow you to run various media such as electrical wiring, compressed air tubing, coolants, or lubricants through the center.
Keep a material certificate on hand for compliance and quality assurance needs. Certificates include a traceable lot number and material test report. These hollow shafts reduce system weight and allow you to run various media such as electrical wiring, compressed air tubing, coolants, or lubricants through the center.
With 2" of each end softened, it's easier to machine a custom end for mounting. The rest of the shaft is case-hardened, which increases hardness and wear resistance on the surface of the shaft while allowing the center to remain soft for absorbing stresses caused by shifting loads.
For your compliance and quality assurance needs, these shafts come with a material certificate with a traceable lot number.
For a snug fit with a linear bearing in high-precision applications, these shafts are turned, ground, and polished to tight diameter and straightness tolerances.
Replace worn shafts in two-piece support-rail shaft systems, or mate with a support rail to create your own. The tapped mounting holes match those on our Support Rails.
These shafts include a support rail for a stable setup that eliminates bending and prevents linear bearings from rotating.
Thread these shafts into a tapped hole to support idler sprockets and pulleys in tensioning applications. They have a retaining-ring groove, retaining ring, and spacers to position your component and hold it in place.
Mount the flange to a machine or wall to support idler sprockets and pulleys in tensioning applications. They include washers and a nut to position your component and hold it in place.
Attach threaded accessories, such as mixer propellers and fan blades, to the end of these shafts.
Connect these internally threaded shafts directly to threaded components, or use a fastener to secure.
Combine with a machine key to transmit torque to gears, sprockets, and other power transmission components.
These shafts have keyways only on the ends, leaving a plain shaft in the center. Use the keyways with machine keys to transmit torque to gears, sprockets, and other keyed components. Use the middle of the shaft with bearings and other round-bore components.
In addition to diameter tolerances that are twice as tight as standard keyed shafts, these shafts include a traceable lot number and test report. Use them with machine keys to transmit torque to gears, sprockets, and other power transmission components.
Good for hydraulic systems, machine tools, and other high-torque applications, these shafts have teeth that transmit high rotational loads.
Combine these general purpose drive shafts with gears, sprockets, and bearings to transmit rotary motion.
Eight times straighter than standard rotary shafts, these tight-tolerance shafts minimize vibrations and reduce wear to bearings and other components. They also have diameter tolerances that are twice as tight as standard rotary shafts.
Connect these internally threaded shafts directly to threaded components, or use a fastener to secure. They have a flat surface area that allows set screws to dig into the shaft for securely mounting gears, sprockets, and bearings.
A flat surface area allows set screws to dig into the shaft for securely mounting gears, sprockets, and bearings.
A shoulder near the end of the shaft provides a stop for gears, sprockets, and bearings.
Raise your enclosure to access switches, gauges, screens, and other parts at a comfortable working height.
Replace battery terminal hardware.
Screw the shank into a threaded hole for quick installation and removal.
Maintain consistent alignment in mating parts by installing a pin in one part and a liner in the other.
The shoulder provides a consistent height reference point and keeps the pin from being pressed through the fixture.
Install these pins in a plate or table and mate with holes in a workpiece for precise alignment.
Encase these pins while molding plastic or composite parts. Once set, the knurls resist movement, letting you align the workpiece with precision on a plate or table.
A slightly undersized shank makes these pins easy to install and replace. Also known as slip-fit and lock-screw locating pins, they are held in place by a separate lock screw.
The head on these pins slides side-to-side in one direction. Use one of these pins and one standard round-head pin to prevent jamming when loading and unloading workpieces with inconsistent hole spacing.
Precisely align and lock together your mold halves, so they stay in place during high-pressure injection molding.
Place a cutoff blade into one of these holders to keep it in place in the lathe.
Add safety and convenience to your wall and tank ladders. Posts extend above the ladder top and lock in place to guide you and provide stability.
Replace a table leg or make a table with your own tabletop.
Use these legs to make or repair a folding table.