A dicing blade includes: a first blade portion and a second blade portion at least partially surrounding the first blade portion, wherein the first blade portion includes: a first bonding layer; first diamond particles disposed in the first bonding layer and having a first density in the first bonding layer; and first metal particles disposed in the first bonding layer, and wherein the second blade portion includes: a second bonding layer at least partially surrounding the first bonding layer; and second diamond particles disposed in the second bonding layer and having a second density in the second bonding layer, wherein the second density is higher than the first density.

A power tool includes a housing, a motor located within the housing, a drive assembly located within the housing and connected to an output of the motor, at least one cutting wheel coupled to the drive assembly, and at least one switch configured to control activation of the motor for directional rotation of the drive assembly in either a forward rotational direction or a reverse rotational direction. The drive assembly is configured to operate in the reverse rotational direction during dry cutting. The drive assembly is configured to operate in the forward rotational direction during wet cutting.

A power tool includes a housing, a motor located within the housing, a drive assembly located within the housing and connected to an output of the motor, at least one cutting wheel coupled to the drive assembly, and at least one switch configured to control activation of the motor for directional rotation of the drive assembly in either a forward rotational direction or a reverse rotational direction. The drive assembly is configured to operate in the reverse rotational direction during dry cutting. The drive assembly is configured to operate in the forward rotational direction during wet cutting.

Various embodiments disclosed relate to an abrasive article (10). The abrasive article (10 includes a backing (12) defining a major surface. The abrasive article (10) includes an abrasive layer including a plurality of tetrahedral abrasive particles (16) attached to the backing (12). The tetrahedral abrasive particles (16) include four faces joined by six edges terminating at four vertices (40, 42, 44, 46). Each one of the four faces contacts three of the four faces, and a major portion of the tetrahedral abrasive particles (16) have at least one of the vertices (40, 42, 44, 46) oriented in substantially a same direction.

A tool, such as blades and drill bits to be used with cutting devices for cutting through solid material and simultaneously sanding the solid material. The tool includes a body having an attachment point for the cutting devices. Teeth are disposed along a length of a periphery of the body for cutting the solid and abrasives disposed over an exposed outer surface of the body for sanding new surfaces in the solid material created upon cutting by the cutting devices.

A tool, such as blades and drill bits to be used with cutting devices for cutting through solid material and simultaneously sanding the solid material. The tool includes a body having an attachment point for the cutting devices. Teeth are disposed along a length of a periphery of the body for cutting the solid and abrasives disposed over an exposed outer surface of the body for sanding new surfaces in the solid material created upon cutting by the cutting devices.

A bonded abrasive wheel comprises magnetizable abrasive particles retained in an organic binder. The bonded abrasive wheel has a central portion adjacent to a central hub, an outer circumference and a rotational axis extending through the central hub. The magnetizable abrasive particles adjacent to the central hub are aligned at an average angle of less than 35 degrees with respect to the rotational axis, and the magnetizable abrasive particles adjacent to the outer circumference of the bonded abrasive wheel are aligned at an average angle that is from 35 and 90 degrees, inclusive, with respect to the rotational axis. Methods of making a bonded abrasive wheel are also disclosed.

A bonded abrasive wheel comprises magnetizable abrasive particles retained in an organic binder. The bonded abrasive wheel has a central portion adjacent to a central hub, an outer circumference and a rotational axis extending through the central hub. The magnetizable abrasive particles adjacent to the central hub are aligned at an average angle of less than 35 degrees with respect to the rotational axis, and the magnetizable abrasive particles adjacent to the outer circumference of the bonded abrasive wheel are aligned at an average angle that is from 35 and 90 degrees, inclusive, with respect to the rotational axis. Methods of making a bonded abrasive wheel are also disclosed.

A method of processing a workpiece with a disk-shaped blade containing abrasive grains includes the steps of placing an auxiliary plate made of a material having a modulus of elasticity higher than a material of which a front surface side of the workpiece is made, on the front surface side of the workpiece, causing the blade rotated to cut into the front surface side of the workpiece to cut the workpiece as well as the auxiliary plate, and removing the auxiliary plate from the workpiece that has been cut by the blade.

A grinding wheel includes a support body which has a circumferential surface and a central coupling region for attaching the grinding wheel to a rotary drive for rotating the grinding wheel about a rotational axis running through the central coupling region. The grinding wheel also includes a grinding layer which is applied onto the circumferential surface of the support body. The support body includes a first part and a second part connected to the first part. The first part has the circumferential surface, and the second part has the coupling region and consists essentially of a vibration-damping material.