A thinner cutting edge and thicker top edge give these blades a T‐shape profile that moves chips away from the cut and reduces friction for fast cutting.

Combine a holder and carbide insert to perform cutoff and grooving tasks on a lathe.

Fit these holders directly into a lathe tool post or appropriately sized holder without the need for a tool block.

Fit these holders directly into a lathe tool post or appropriately sized holder without the need for a tool block.

The rounded nose on these inserts contours the outside of the workpiece and cuts grooves with rounded edges.

Heat resistant and shaped for turning stainless steel specifically, these inserts will last longer than inserts for multiple materials.

Made of an abrasion-resistant carbide designed for turning cast iron, these inserts will last longer than inserts for multiple materials.

Cut aluminum, copper, brass, and other non-ferrous materials with these premium inserts.

Secure carbide inserts inside these holders for stable turning.

Replace clamps, screws, seats, and slotted pins in carbide insert holders.

Pair these holders with a threading insert or a grooving insert to make cuts on the outside of a workpiece.

Pair these holders with a threading insert or a grooving insert to make cuts on the inside of a hollow workpiece.

Pair one of these inserts with a compatible boring carbide insert holder with coolant hole.

Contour the interior wall of a hollow workpiece when you pair a holder with a compatible insert.

Made of solid carbide, these saws are harder, stronger, and more wear resistant than high-speed steel for the longest life and best finish on hard material. Use them for cutoff, slitting, and slotting applications.

With peripheral and side teeth, these saws remove chips for a consistent cutting width.

Also known as Type 27, raised-hub, and depressed-center cutoff wheels, these wheels outperform Type 1 wheels when making flush cuts in aluminum, iron, stainless steel, and steel.

Made of premium grade abrasives, these wheels are strong and thick for making notches in aluminum, iron, stainless steel, and steel.

Also known as Type 27, raised-hub, and depressed-center cutoff wheels, these wheels outperform Type 1 wheels when making flush cuts.

Also known as Type 27, raised-hub, and depressed-center cutoff wheels, these wheels outperform Type 1 wheels when making flush cuts.

Made of a combination of ceramic alumina and zirconia alumina, these wheels last up to ten times longer than standard cutoff wheels when cutting hard metal such as Inconel, Hastelloy, and tool steel.

Also known as Type 27, raised-hub, and depressed-center cutoff wheels, these wheels outperform Type 1 wheels when making flush cuts.

Two layers of fiberglass mesh reinforcement give these wheels at least three times the life of standard cutoff wheels when cutting metal such as aluminum, iron, stainless steel, and steel.

Run these high-density aluminum oxide wheels at higher speeds than standard cutoff wheels to make quick cuts in aluminum, iron, stainless steel, and steel.

For quick cuts in stainless steel, run these high-density zirconia alumina wheels at a higher rpm than standard cutoff wheels.

An extra-fine layer of fiberglass mesh reinforcement allows these wheels to make smoother cuts than standard bench-grinder cutoff wheels when cutting metal such as aluminum, iron, stainless steel, and steel.

Make fast, burr-free cuts in stainless steel with these premium aluminum oxide wheels.

Use these clog-resistant wheels to make quick cuts in soft metal such as aluminum, brass, and copper.

Use these wheels to cut through metal such as iron and steel. They are reinforced with a layer of fiberglass mesh.

Designed to cut sheet metal.

Two layers of fiberglass mesh reinforcement give these fast-cutting, zirconia alumina wheels at least three times the life of standard cutoff wheels when aluminum, iron, stainless steel, and steel.

These wheels have a zirconia alumina abrasive for cutting ductile cast iron.

These wheels are designed to cut stainless steel. They are reinforced with a layer fiberglass mesh.

Made of diamond abrasive, these wheels cut ceramics, tile, and other abrasive materials.

A ceramic alumina abrasive cuts through stainless steel.

Make cuts in hard, brittle materials such as firebrick, stone, and concrete.

Prevent clogging when cutting soft metal—these blades have plenty of space between the carbide-tipped teeth to allow chips to escape.

Teeth are carbide tipped and designed to push chips away from the blade to prevent clogging and produce smooth cuts in aluminum sheets, tubing, and T-slotted framing.

The edge of the blade is segmented to cut faster than a continuous edge.

A continuous edge on these blades produces smooth cuts.

Produce smooth cuts in plastic materials including polycarbonate, polyurethane, PVC, and acrylic with the carbide-tipped teeth on these blades.

Cut wood, plywood, and particleboard.

Also known as rip blades, these steel blades have large, forward-angled, carbide-tipped teeth for making fast cuts.

Also known as dado-head blades, these are for cutting grooves in all types of wood.

Use these blades for occasional cutting.

A continuous edge on these blades produces smooth cuts.

A continuous edge on these blades produces smooth cuts. It's coated in diamond grit to cut hard, abrasive materials such as masonry, stone, asphalt, and concrete.

Also known as dado-head blades, these are for cutting grooves in all types of wood.

Use these blades for occasional cutting.

A blend of tungsten carbide and diamond grits on the continuous edge of these blades cuts hard, nonmetallic materials including composites and graphite.

Use these blades with water or coolant to produce smoother cuts in tile than dry-cutting blades. They're also for use on glass.

Produce smooth cuts in plastic materials including polycarbonate, polyurethane, PVC, and acrylic with the carbide-tipped teeth on this blade.

Diamond grit bonded to a segmented edge cuts through hard metal such as cast iron.

Cut stainless steel sheets, pipe, tubing, and grating with teeth made of impact-resistant carbide.

Use these titanium carbonitride (TiCN) coated blades on stainless steel.

These blades have a continuous edge with diamond grit to cut through ceramics.

A tungsten carbide grit edge cuts through abrasive materials such as composites and fiberglass.

These blades have a higher concentration of diamonds than other dry-cutting blades, so they last up to three times longer.