An attachment for a mobile handling device is configured for processing walls or ceilings. The attachment comprises a mounting unit that is arranged to be supported at a mounting interface of the handling device, a processing head that is arranged to be equipped with at least one tool for material-removing processing or smoothing processing, and a compensation arrangement that is arranged between the mounting unit and the processing head and that defines a longitudinal axis. The mounting unit provides at least two pivot positions for the attachment that are offset from one another. The processing head is movable relative to the mounting unit in a longitudinal direction along the longitudinal axis. The compensation arrangement is configured to provide a defined contact pressure force for the processing head in a defined operating range along the longitudinal axis towards the surface to be processed.

A power tool includes a motor housing, a motor, a handle coupled to the housing, and a vibration damping assembly. The motor is positioned in the motor housing and configured to rotatably drive an output shaft. The vibration damping assembly is positioned between the motor housing and the handle. The vibration damping assembly includes a first coupling portion defined by the motor housing, a second coupling portion defined by the handle, and an elastomeric damper captured between the first coupling portion and the second coupling portion. The first coupling portion includes a boss having a flange and a first groove. The second coupling portion defines an opening and includes first and second ribs extending into the opening and spaced apart along a longitudinal axis of the handle. The first and second ribs define a second groove therebetween. The damper occupies the first and second grooves.

A coating removal apparatus includes multiple pairs of rotatable brushes spaced apart from each other in a first direction. Each pair of brushes may include two opposing brushes that are configured to rotate about a common axis and move towards and away from each other in a second direction transverse to the first direction. When a coated panel is positioned between the two opposing brushes, first portions of the brushes may separably engage with and rotate on opposite surfaces of the coated panel. The apparatus may also include one or more liquid tanks configured to contain a liquid. When the tanks contain the liquid and when the coated panel is positioned between the two opposing brushes, second portions of the two brushes may at least contact the liquid in the liquid tanks.

In one embodiment, a polishing head includes an elastic film configured to form pressure rooms to which a pressure fluid is fed, and configured to press a substrate onto a polishing surface with a fluid pressure of the pressure fluid. The head further includes a first magnetic generator provided above a partition wall that separates the pressure rooms. The head further includes a second magnetic generator configured to form at least a portion of the partition wall or provided below the partition wall.

A cutting apparatus includes a chuck table for holding a workpiece thereon, a cutting unit for cutting the workpiece held on the chuck table with a cutting blade secured in place on a distal-end portion of a spindle by a mount flange mounted on the distal-end portion of the spindle, an indexing feed unit for moving the cutting unit in indexing feed directions parallel to axial directions of the spindle, a processing feed unit for moving the chuck table in processing feed directions perpendicular to the indexing feed directions, and an end face correction unit for correcting an end face of the mount flange that supports the cutting blade in contact therewith. The processing feed unit includes a table moving base that supports the chuck table thereon and an actuating mechanism for moving the table moving base. The end face correction unit is fixedly mounted on the table moving base.

A grinding wheel is mounted at a distal end of a spindle and grinds a wafer held on a holding table. The grinding wheel includes: an annular base having a mounting surface to be mounted on the distal end of the spindle; and a plurality of segment grindstones that are fixedly attached annularly to a surface opposite to the mounting surface of the annular base and that are equidistantly spaced apart from each other. The annular base has a plurality of slits formed therein. Each of the slits represents a gap that is formed between two adjacent segment grindstones and that is extended toward a side of the annular base such that the slit has a width of the gap.

A workpiece reverse support device has a pair of workpiece pinching members for abutting on their respective opposing side portions of the workpiece held by the robot hand so as to pinch the workpiece and a pinching state switching unit for switching the pair of workpiece pinching members between a pinching state of pinching the workpiece and a releasing state of releasing the workpiece. In a workpiece reverse support device for supporting a face/back reverse of a workpiece in a robot hand, flexibility of its installation state, namely installation location, installation posture, or the like can be enhanced.

A grinding machine for finishing turned surfaces of a rotor disc for a gas turbine engine, including a retaining mechanism for retaining the rotor disc and rotatable about a rotational axis corresponding to a central axis of the rotor disc, a spindle engaged to a grinding wheel and rotatable about a rotational axis corresponding to a central axis of the grinding wheel, the grinding wheel having an outer super abrasive surface, a translating mechanism engaged to at least one of the retaining mechanism and the spindle and actuable to provide a relative translational motion between the retaining mechanism and the spindle along three perpendicular axes, and a pivoting mechanism engaged to one of the retaining mechanism and the spindle and actuable to provide a pivoting motion of the rotational axis of one of the retaining mechanism and the spindle around a pivot axis perpendicular thereto.

Provided is an automatic chamfering machine for chamfering workpieces, comprising: a feed inlet, a linear guide, a positioning mechanism, a working platform, an automatic grasping mechanism, a grinding stick and an outlet. One end of the linear guide is connected to the feed inlet and the other end of the linear guide is connected to the outlet; the positioning mechanism and the working platform are arranged on the linear guide. The workpieces enter the linear guide from the feed inlet and pass through the positioning mechanism, the positioning mechanism performs a position alignment calibration to the workpieces. The automatic grasping mechanism grasps the workpieces after the position alignment calibration to the working platform. The grinding stick chamfers the workpieces on the working platform. The workpieces after chamfering are discharged through the outlet along with the linear guide. A chamfering method using the automatic chamfering machine is further provided.

The present disclosure relates to a grinding head for a floor grinding machine for grinding floor surfaces of stone or stone-like material. Such a grinding head comprises a lower casing member, comprising a lower support and an upwardly extending edge portion, and an upper casing member, comprising an upper cover and a downwardly extending edge portion, wherein the upper casing member is joinable to the lower casing member by causing axially distal portions of the edge portions to bear on each other.