A diamond blade includes a base and a thin film metallic glass. The base includes a plurality of diamond particles, and the plurality of diamond particles protrude from a surface of the base. The thin film metallic glass is formed on the surface of the base, and the plurality of diamond particles are exposed on the thin film metallic glass.

A diamond blade includes a base and a thin film metallic glass. The base includes a plurality of diamond particles, and the plurality of diamond particles protrude from a surface of the base. The thin film metallic glass is formed on the surface of the base, and the plurality of diamond particles are exposed on the thin film metallic glass.

A surface-coated cutting tool includes a base material and a coating covering the base material. The base material includes a rake face and a flank face. The coating includes a TiCN layer. The TiCN layer has a (422) orientation in a region d1 in the rake face. The TiCN layer has a (311) orientation in a region d2 in the flank face.

A blender blade formed of titanium or titanium alloy is described herein. The blender blade comprises a central portion and one or more blade wings extending therefrom. Each blade wing comprises a leading edge, wherein the leading edge is work hardened to cause the leading edge to have a first hardness which is harder than a second hardness of the central portion. The central portion is in an annealed condition. The first hardness is in a range of about 40-50 HRC, the second hardness is in a range of about 20-30 HRC. Subsequent to work hardening, the leading edge can undergo nitriding and/or layer deposition.

A blender blade formed of titanium or titanium alloy is described herein. The blender blade comprises a central portion and one or more blade wings extending therefrom. Each blade wing comprises a leading edge, wherein the leading edge is work hardened to cause the leading edge to have a first hardness which is harder than a second hardness of the central portion. The central portion is in an annealed condition. The first hardness is in a range of about 40-50 HRC, the second hardness is in a range of about 20-30 HRC. Subsequent to work hardening, the leading edge can undergo nitriding and/or layer deposition.

The invention relates to an insert brazed on a body of cutting tools (101), consisting of: a metal substrate (11), in the form of plates, having a surface for attachment to the tool body; a high-temperature, brazing, alloy layer (12); an intermediate layer; and a ceramic plate (14). The brazing alloy layer connects the metal substrate (11) of the ceramic plate (14) via the metal layer (13). A low-temperature brazing layer (1) connects the insert (1, 1) to the body of the tool (101).

The invention relates to an insert brazed on a body of cutting tools (101), consisting of: a metal substrate (11), in the form of plates, having a surface for attachment to the tool body; a high-temperature, brazing, alloy layer (12); an intermediate layer; and a ceramic plate (14). The brazing alloy layer connects the metal substrate (11) of the ceramic plate (14) via the metal layer (13). A low-temperature brazing layer (1) connects the insert (1, 1) to the body of the tool (101).

There is provided a tool blade comprising a backing strip, binding material forming a binder layer, with discrete regions of binder layer formed as teeth along an edge of the backing strip, and abrasive particles bound to the backing strip by the binder layer, wherein each tooth is formed with a ductile region bonded to the backing strip, a crown and an intermediate region of thermal material disposed between the ductile region and the crown so as to absorb thermal expansion and contraction. The binding material powder is heated by laser beam to form a binder layer which binds the abrasive particles to the backing strip. The laser beam is used to form discrete regions of binder layer as teeth. The binding material is typically braze material.

There is provided a tool blade comprising a backing strip, binding material forming a binder layer, with discrete regions of binder layer formed as teeth along an edge of the backing strip, and abrasive particles bound to the backing strip by the binder layer, wherein each tooth is formed with a ductile region bonded to the backing strip, a crown and an intermediate region of thermal material disposed between the ductile region and the crown so as to absorb thermal expansion and contraction. The binding material powder is heated by laser beam to form a binder layer which binds the abrasive particles to the backing strip. The laser beam is used to form discrete regions of binder layer as teeth. The binding material is typically braze material.

A surface-coated cutting tool includes a base material and a coating covering the base material. The base material includes a rake face and a flank face. The coating includes a TiCN layer. The TiCN layer has a (311) orientation in a region d1 in the rake face. The TiCN layer has a (422) orientation in a region d2 in the flank face.