A wheel grinding device consists of a lower lifting rotary system, spoke grinding units, a center hole grinding system and an upper lifting and clamping rotary system. The wheel grinding device not only can be used for grinding the center hole of a wheel of any size via brush units of the center hole grinding system, but also can be used for grinding the back of wheel spokes of different sizes and shapes via the actions of brush belts of the spoke grinding units.

A device for processing a surface of a work piece. A motor is configured to produce a rotary force. A driving pulley is operatively coupled to the motor such that the rotary force produced by the motor causes rotation of the driving pulley. A belt is operatively coupled to the driving pulley such that rotation of the driving pulley causes rotation of the belt. A second pulley is also operatively coupled to the belt such that rotation of the belt causes rotation of the second pulley. Bristles are coupled to the belt and extend away from the belt. The rotary force produced by the motor causes the plurality of bristles to move relative to the motor. The surface of the work piece is processed when the bristles contacts the surface while the bristles are moving.

A substrate processing apparatus includes: a holding part for holding a substrate; a rotating part for rotating the holding part to rotate the substrate together with the holding part; a liquid supply part for supplying a cleaning liquid to a main surface of the substrate; a polishing head for polishing the main surface; a moving part for scanning the polishing head in a radial direction of the substrate while pressing the polishing head against the main surface; and a controller for controlling the rotating part, the liquid supply part, and the moving part. The controller sets a division line that divides the main surface into plural areas in the radial direction, and controls the liquid supply part to supply the cleaning liquid for each area and controls the moving part to scan the polishing head for each area while a subsequent supply of the cleaning liquid is stopped.

A portable tool for simultaneously shaving, scraping or cleaning the outer circumference of pipe has a drill shaft that connects the tool to a power source. The drill shaft has a gear wheel attached to an inner end. This drift shaft engages a circular ban to form a gear assembly that will enable the ban to rotate when power is applied to the drill shaft. Connected to the inner wall of the circular ban is a plurality of bristles that will engage the surface of a pipe. After a pipe is inserted into the tool and power applied to the tool the drill shaft and circular ban will begin to rotate. As the ban rotates, the bristles will move over the surface of the pipe thereby performing the cleaning activity on the pipe's outer surface. During the cleaning process, the user can move the pipe linearly through the tool and clean the entire length of the pipe.

A method of abrading the surface of a workpiece is disclosed. The method includes providing a workpiece, an abrading apparatus with a backing pad configured to receive an abrading plate, an abrading plate attachable to the backing pad and a slurry including abrasive grains; attaching the abrading plate to the backing pad; providing the slurry including abrasive grains between the abrading plate and the surface of the workpiece; and operating the abrading apparatus to abrade the surface of the workpiece. Therein, the abrading plate includes a workpiece-facing layer, which workpiece-facing layer faces the surface of the workpiece and includes a metal or a polymer, and the abrasive grains have a hardness on the Mohs scale of greater than 5.

A handheld texturing tool to apply or reapply joint compound in deficient areas of a larger textured surface so that a new texture can be rendered to the deficient areas without disturbing the larger textured surface.

A handheld texturing tool to apply or reapply joint compound in deficient areas of a larger textured surface so that a new texture can be rendered to the deficient areas without disturbing the larger textured surface.

One embodiment of the present invention provides an Fe-based amorphous alloy ribbon for an Fe-based nanocrystalline alloy, the Fe-based amorphous alloy ribbon being a cooled body of a molten metal that has been applied to a surface of a chill roll, wherein the Fe-based amorphous alloy ribbon includes a recess having a depth of 1 m or more in a 0.647 mm0.647 mm region located in a central part, in the ribbon width direction, of a ribbon surface, which is a cooled surface, in which a maximum area of the recess having a depth of 1 m or more is 3000 m.sup.2 or less; and a method of manufacturing the same.

A method for polishing a workpiece in the production of an optical element, in particular for microlithography, wherein a relative movement takes place between a polishing tool (300) and a workpiece surface (110, 120, 210) being machined. A polishing tool surface (215, 315) of the polishing tool (300) is formed by a viscoelastic polishing medium (303), wherein the polishing tool surface has an average diameter which is less than 50% of the average diameter of the workpiece surface being machined. The polishing tool surface during polishing is guided by an overrun distance beyond at least one edge (110a, 110b, 120a, 120b, 210a, 210b) delimiting the workpiece surface being machined, wherein the average diameter of the polishing tool surface is at least twice the overrun distance.

A method for polishing a workpiece in the production of an optical element, in particular for microlithography, wherein a relative movement takes place between a polishing tool (300) and a workpiece surface (110, 120, 210) being machined. A polishing tool surface (215, 315) of the polishing tool (300) is formed by a viscoelastic polishing medium (303), wherein the polishing tool surface has an average diameter which is less than 50% of the average diameter of the workpiece surface being machined. The polishing tool surface during polishing is guided by an overrun distance beyond at least one edge (110a, 110b, 120a, 120b, 210a, 210b) delimiting the workpiece surface being machined, wherein the average diameter of the polishing tool surface is at least twice the overrun distance.