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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.
Internal threads allow you to mount these shafts onto threaded studs and fasteners, no shaft supports needed.
Combine these general purpose shafts with a linear bearing and shaft support to create a basic linear motion system.
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.
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.
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.
Position shafts an inch or two off the ground to maintain bearing and part clearance. Support rails provide stability over the entire length of shaft, allowing virtually unlimited travel lengths and eliminating bending under moderate to heavy loads.
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.
At approximately one-third the height of standard versions, these rails provide linear shaft support in applications with low vertical clearance. They provide stability over the entire length of shaft, allow virtually unlimited travel lengths, and eliminate bending under moderate to heavy loads.
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.
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.
Attach threaded accessories, such as mixer propellers and fan blades, to the end of these shafts.
A shoulder near the end of the shaft provides a stop for gears, sprockets, and bearings.
The diameter of these shafts is slightly smaller than listed, so precision ball bearings (ABEC-3 and above) slide on without any tools.
Combine with a machine key to transmit torque to gears, sprockets, and other power transmission components.
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.
Clip retaining rings into the grooves to separate and position gears, sprockets, and bearings.
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.
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.
A flat surface area allows set screws to dig into the shaft for securely mounting gears, sprockets, and bearings.
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.
Good for hydraulic systems, machine tools, and other high-torque applications, these shafts have teeth that transmit high rotational loads.
These general purpose gas springs assist in opening lids, covers, windows, conveyors, and seats—similar to a hatchback opening on a car.
Mechanical operation means these springs have no seals to fail or gas to leak.
Stainless steel construction provides corrosion resistance for use in damp environments.
A temperature-resistant seal allows these gas springs to withstand heat up to 392°F.
With no gas to leak out and a corrosion-resistant 316 stainless steel construction, these mechanical springs are built for long-term, maintenance-free use in wet environments.
These gas springs have threaded ends so you can use them with any combination of end fittings, studs, and mounting brackets.
Made from stainless steel for excellent corrosion resistance in damp environments.
Often used to open lids, covers, windows, conveyors, and seats, these gas springs function similar to a hatchback opening on a car. They have an eyelet end fitting on each end.
Ensure you have the correct force for your application. These gas springs have a bleed valve so you can release gas to permanently reduce the force to meet your requirements.
Made from stainless steel for excellent corrosion resistance in damp environments. These gas springs have a bleed valve so you can release gas to permanently reduce the force to meet your requirements.
Protect material and equipment underneath heavy loads—these gas springs lock automatically when fully extended, ensuring they can't be closed until it's safe to do so.
Pair one of these gas springs with a release control to stop and release the gas spring anywhere along the stroke with the push of a button or lever.
Release gas from these springs until they supply the exact force you need—made of corrosion-resistant 316 stainless steel, they’re commonly used in wet environments.
Automatically locking when fully extended and made of 316 stainless steel to resist corrosion, these gas springs protect material and equipment underneath heavy loads in damp environments.
Often used to replace coil springs in metal stamping and die-spring applications, these gas springs match the diameter and stroke length of coil die springs but offer much more force.
Color coded by force to help you choose the correct replacement, these gas springs generate high force.
Attach eyelet end fittings to these brackets to mount gas springs.
These brackets secure eyelet end fittings from both sides to provide a strong hold on gas springs that get bumped or jostled. Mount on any panel, lid, or door.
Pair with ball socket end fittings to mount your gas spring in almost any position.
Drill mounting holes where you need them—these brackets are made from aluminum, so they’re easy to machine.
Made with thicker stainless steel than standard ball stud mounting brackets, these brackets work well in high-force applications exposed to damp conditions.
Since they’re at least twice as thick as standard ball stud mounting brackets, these brackets are best for high-force applications.
Pair these 90° angle offset-arm brackets with ball socket end fittings to mount your gas spring in almost any position.
Stainless steel that’s twice as thick as standard 90° angle ball stud mounting brackets makes these brackets good for high-force applications exposed to damp conditions.
About twice as thick as standard 90° angle ball stud mounting brackets, these brackets are suitable for high-force applications.
Made of easy-to-machine aluminum, these brackets come without mounting holes, so you can drill holes where you need them.
Pair these 30° angle brackets with ball socket end fittings to mount your gas spring in almost any position.
Pair these 90° angle brackets with ball socket end fittings to mount your gas spring in almost any position.
Made from stainless steel, these brackets resist corrosion in damp environments.
Attach ball socket end fittings to these studs to mount gas springs.
Install these ball studs into thin material—they’re riveted, so you only need access to one side.
Also known as tension and traction gas springs, these work in the opposite direction of other gas springs. Similar to a screen door closing, they're used to assist in closing covers, hoods, and doors.
Commonly used on hood and trunk lids, these simple, three-piece rods telescope from 18 1/2" to 46 3/4" to prop lids open at a variety of angles.
Springs provide lifting assistance to raise and hold lids open—slightly lift the lid to get it started and the support will do the rest. Manually shut the lids and the supports will hold them in the closed position.
No separate hinges are required, these supports act as a hinge and lid support all in one. Springs provide lifting assistance to raise and hold lids open—slightly lift the lid to get it started and the support will do the rest. Manually shut the lids and the supports will hold them in the closed position.
Manually control these standard free-moving lid supports through their full range of motion. Raise or lower the lid until the hold-open mechanism on the support is engaged; slightly lift it again to release the hold and close the lid.
Keep environments free of contaminants—with plastic bushings, there's no metal-to-metal contact that can release particles as these supports open and close. Manually control these free-moving lid supports through their full range of motion. Raise the lid until the hold-open mechanism on the support is engaged; slightly lift it again to release the hold and close the lid.
Also known as hatch springs, these supports are commonly used on hatches and other top-opening lids. Raise the lid to extend the spring, which props the lid open—an internal cable keeps the spring from overextending. Press the center of the spring to release the hold and close the lid.
Hold heavy lids open with these supports.
Requiring less space to mount and operate, these supports are often used on small cabinets and enclosures. They gradually slow your lid's motion to prevent it from slamming open. To open lids, lower them and the support will slowly and softly do the rest. Manually shut the lids and the supports will hold them in the closed position.
Gradually slow your lid's motion to prevent it from slamming open. To open lids, lower them and the support will slowly and softly do the rest. Manually shut the lids and the supports will hold them in the closed position.
Providing constant resistance through the full range of motion, these supports hold lids open at any angle up to 70° or 90°.
To eliminate slamming and smashed fingers, these supports automatically pull lids shut when they approach the closed position. Raise the lid until the hold-open mechanism on the support is engaged; slightly lift it again to release the hold and close the lid.
Drive and secure these threaded rods on both ends with the included nuts. They’re Grade B7, so their tensile strength is about one and half times higher than low-strength steel rods.
The tensile strength of these metric Grade B7 rods is about one and a half times higher than low-strength steel rods.
Made of Grade B7 steel, the tensile strength of these threaded rods is one and a half times higher than low-strength steel threaded rods. They also meet the pressure and temperature requirements of ASTM A193 and are often used to secure pressure tanks, valves, and flanges.
Grade B7, these threaded rods have a tensile strength about one and a half times stronger than low-strength steel rods. They meet the pressure and temperature requirements of ASTM A193 and are often used to secure pressure tanks, valves, and flanges.
Tighten these threaded rods by turning them to the left; once fastened, they resist loosening from counterclockwise motion. Made from Grade B7 steel, their tensile strength is one and a half times higher than low-strength steel rods.
An economical alternative to Grade B7 and Grade B16 threaded rods, these metric Class 8.8 rods are suitable for fastening most machinery and equipment.
Grade B16 threaded rods maintain their strength at higher temperatures than Grade B7 threaded rods. They meet the pressure and temperature requirements of ASTM A193 and are often used to secure pressure tanks, valves, and flanges.
18-8 stainless steel threaded rods have good chemical resistance.
Available in metric sizes, these 18-8 stainless steel threaded rods have good chemical resistance.
Tighten these threaded rods by turning them to the left; once fastened, they resist loosening from counterclockwise motion.
Stronger and more wear resistant than 18-8 stainless steel, these threaded rods are mildly chemical resistant. They meet the pressure and temperature requirements of ASTM A193 and are often used to secure pressure tanks, valves, and flanges.
Grade B8 threaded rods meet the pressure and temperature requirements of ASTM A193 and are often used to secure pressure tanks, valves, and flanges. They have good chemical resistance.
Grade B8M threaded rods meet the pressure and temperature requirements of ASTM A193 and are often used to secure pressure tanks, valves, and flanges.
These metric 316 stainless steel threaded rods are more corrosion resistant than 18-8 and 410 stainless steel threaded rods and have excellent resistance to chemicals and salt water.
More corrosion resistant than 18-8 and 410 stainless steel threaded rods, these 316 stainless steel rods have excellent resistance to chemicals and salt water.
These hardened 316 stainless steel threaded rods are 40% stronger than standard Grade B8M threaded rods. They meet the pressure and temperature requirements of ASTM A193 and are often used to secure pressure tanks, valves, and flanges.
Comparable to Grade 8 steel, these threaded rods have a tensile strength of 150,000 psi, making them about 25% stronger than medium-strength steel rods.
These metric threaded rods are about half the strength of medium-strength steel threaded rods for light duty hanging, mounting, and fastening.
About half the strength of medium-strength steel threaded rods, use these metric fine-thread rods for light duty hanging, mounting, and fastening.
About half the strength of medium-strength steel threaded rods, use these for light duty hanging, mounting, and fastening.
Class 12.9 rods are about 20% stronger than Class 10.9 threaded rods and are for use in heavy machinery.
These Class 10.9 steel threaded rods are about 25% stronger than medium-strength steel rods.
Tighten these threaded rods by turning them to the left; once fastened, they resist loosening from counterclockwise motion. About half the strength of medium-strength steel threaded rods, use them for light duty hanging, mounting, and fastening.
These metric threaded rods tighten when turned to the left; once fastened, they resist loosening from counterclockwise motion. About half the strength of medium-strength steel threaded rods, use them for light duty hanging, mounting, and fastening.
The most corrosion resistant stainless steel threaded rods we offer, these Alloy 20 stainless steel threaded rods contain nickel to withstand exposure to sulfuric, phosphoric, and nitric acids.
One-third the weight of steel, aluminum threaded rods resist corrosion in wet environments.
Unlike metal rods, these threaded rods will not warp at extreme temperatures, making them ideal for heat treating and furnace fixtures.
These acetal threaded rods won't absorb moisture like nylon and fiberglass rods, so they're good for use in wet environments. They resist alcohol, gasoline, and solvents.
Ideal for environments that require frequent cleaning, such as food and pharmaceutical manufacturing, these rods have a removable cover that protects their threads from dirt and grime.
Made from nylon 6/6, these threaded rods resist oil, grease, and solvents. They’re nonconductive, making them good for use around sensitive electrical components.
Fiberglass threaded rods are stronger than nylon threaded rods. They resist acids, solvents, salt water, and oil.
PVC threaded rods resist acids, alkalies, salt solutions, and alcohol.
Commonly used in valves, pumps, and shafts, these 400 nickel threaded rods resist salt water and caustic chemicals.
These metric threaded rods are made from nylon 6/6 and resist oil, grease, and solvents. They’re nonconductive, making them good for use around sensitive electrical components.
These metric brass threaded rods are corrosion resistant in wet environments, electrically conductive, and nonmagnetic.
More corrosion resistant than 400 nickel threaded rods, these C276 nickel rods are often used in marine environments and chemical-processing plants.
Brass threaded rods are corrosion resistant in wet environments, electrically conductive, and nonmagnetic.
Bronze threaded rods are stronger and more resistant to salt water than brass rods.
PTFE threaded rods withstand temperatures up to 250° F and resist oil, grease, detergents, and most mineral acids. They're the lowest friction plastic threaded rods we offer, so they thread on smoothly.
Titanium threaded rods have a high strength-to-weight ratio and are resistant to acids and salt water.
Unlike metal rods, these metric threaded rods will not warp at extreme temperatures, making them ideal for heat treating and furnace fixtures.
A hex drive on one end allows these rods to be turned with a hex key for ease of installation.
Also known as tap-end, fixture, and setup studs, these studs have Class 5 friction-fit threads on one end to resist loosening and Class 2A standard threads on the other end for attaching a nut.
Also known as setup studs, these studs withstand sideways forces better than fully threaded studs because they have an unthreaded middle that is stronger than the treaded ends.
The shoulder’s diameter is slightly smaller than listed, so these studs fit most machinery and equipment.
Also known as tap-end, fixture, and setup studs, these studs have Class SK6 friction-fit threads on one end to resist loosening and Class 6g standard threads on the other end for attaching a nut.
Known as setup studs, these studs withstand sideways forces better than fully threaded studs because they have a strong unthreaded middle.
Screw these studs into a tapped hole and use them as a pivot point, hinge, shaft, or locator pin.
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.
A hollow center allows these studs to be used as an axle, a vent, or a passageway for wiring.
Also known as dowel screws, use these to join two pieces of wood.
Connect and separate threaded rods, studs, and other components. These hollow rods have internal threads on both ends, so you can make connections and still pass wiring and other objects through the center of the rod.
Weld these studs to uncoated steel surfaces.
These studs have good chemical resistance. Weld them to stainless steel surfaces.
Pass these studs through a hole and weld them in place.
These studs are also known as hanger bolts—use them to hang, mount, and fasten parts to wood structures.
Turn these studs with a hex key for ease of installation.
These metric 316 stainless steel studs have excellent resistance to chemicals and salt water. Also known as hanger bolts, use them to hang, mount, and fasten parts to wood structures.
18-8 stainless steel studs have good chemical resistance and may be mildly magnetic. Also known as hanger bolts, use them to hang, mount, and fasten parts to wood structures.
Use the hole at the end of these rods to attach sensors and accessories without clamps.
The pivoting joint on these rods makes angle-mounting easy.
Use brackets and connectors to create vertical and horizontal support arms.
These rods have a bracket on the base so they're ready to mount.
A clamp on one end grips conveyor guides or rods.
Graduated in 1/8" increments, these rods make it easy to align multiple brackets during installation.
Support beams and joists.
Reduce noise caused by HVAC systems. These sturdy rubber supports isolate vibration caused by heat pumps and air conditioning units, resulting in a quieter facility. When used on roofs, they also keep components above puddled water, which can cause damage.
These U-shaped supports allows access to pipe and conduit after installation.
For a secure hold on pipe and conduit suspended above the ground, these supports have a cushioned clamp provides a 360° grip while reducing vibration.
Support lines that expand and contract. The roller on these supports compensates for movement in your line from changing temperatures.
Bolt directly to a pipe flange to suspend a run of pipe above the ground.
Adjust supports to the exact height you need to route pipe, conduit, and tubing through strut-mount routing clamps and hangers.
Attach these supports onto metal stud knockouts to route cable, conduit, and tubing through metal studs.
Mount these brackets between two studs to support copper tubing for sink faucets and other water supply fixtures.
Build a custom clamping system for holding lightweight objects such as beakers and laboratory equipment.
Support trench walls when installing pipes, cables, and other buried equipment.
Hang damp towels to air-dry.
Secure shower curtain rods to walls.
Hang shower curtains from these rods.
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.
Convert output drives from female to male.
Bend and wrap the legs around almost anything while keeping a level mounting surface.
These jacks are often used to position small shop and laboratory equipment.
Hang clothes on these rods.