A method and a cylindrical grinding machine for centerless cylindrical grinding of a workpiece. The workpiece is supported on a first contact surface and a second contact surface arranged at an angle relative to one another. A grinding disk is applied to the workpiece with an application force, whereby the workpiece is in turn pressed against the first and second contact surfaces, which cause braking of the workpiece (which is rotationally driven solely by the grinding disk). The braking reduces the rotational speed of the workpiece such that the grinding disk produces grinding in addition to rotationally driving the workpiece. The rotational speed of the workpiece can be precisely set by means of an additional brake that applies an adjustable braking force to the workpiece.

This document provides a method of operating a floor grinding machine 100. The method comprises providing a grinding machine 100 comprising a frame 101, a motor 102 and at least one grinding element 1, causing the motor to drive the grinding element so as to rotate at a rotational speed, while in contact with a floor surface to grind, polish or mill the floor surface, determining an actual value of a motor operating parameter, determining a nominal value of the motor operating parameter, comparing the actual value of the motor operating parameter with the nominal value of the motor operating parameter, if a difference between the actual value of the motor operating parameter and the nominal value of the motor operating parameter exceeds a predetermined difference threshold, determining at least one grinding parameter to be adjusted, and causing the at least one grinding parameter to be adjusted.

This document provides a method of operating a floor grinding machine 100. The method comprises providing a grinding machine 100 comprising a frame 101, a motor 102 and at least one grinding element 1, causing the motor to drive the grinding element so as to rotate at a rotational speed, while in contact with a floor surface to grind, polish or mill the floor surface, determining an actual value of a motor operating parameter, determining a nominal value of the motor operating parameter, comparing the actual value of the motor operating parameter with the nominal value of the motor operating parameter, if a difference between the actual value of the motor operating parameter and the nominal value of the motor operating parameter exceeds a predetermined difference threshold, determining at least one grinding parameter to be adjusted, and causing the at least one grinding parameter to be adjusted.

Disclosed is a device for removing burrs from an aluminum alloy hub. The device includes a workbench, columns, a brush, a spindle, a spindle box, a cross beam, a spindle motor, a controller, a parallel robot, and a displacement sensor. Columns are fixedly connected to the workbench, and the cross beam is connected to the columns and a position of the cross beam can be adjusted along the columns; the spindle box is connected to the cross beam, and moves horizontally on the cross beam; the spindle, the spindle motor and the controller are mounted on the spindle box, and the brush is mounted at the end of the spindle; the brush is driven to rotate by the spindle motor and controlled by the controller; and the displacement sensor is mounted in the brush. The parallel robot can implement precise adjustment, and can perform real-time posture adjustment according to the instruction of the controller to ensure that the brush is always in close contact with the back cavity of the hub.

An abrading apparatus (1) including a drum (2), a movable abrasive surface (4) about at least part of the circumferential surface of the drum (2) and a plurality of treatment chambers (5) mounted about the drum (2). Each treatment chamber (5) has upstream and downstream faces (53, 54), which describe an open side facing the drum (2), such that the abrasive surface (4) forms a wall of the chamber (5). The downstream face (53) of each chamber (5) is substantially aligned with a radial plane (R) of the drum (2).

An abrading apparatus (1) including a drum (2), a movable abrasive surface (4) about at least part of the circumferential surface of the drum (2) and a plurality of treatment chambers (5) mounted about the drum (2). Each treatment chamber (5) has upstream and downstream faces (53, 54), which describe an open side facing the drum (2), such that the abrasive surface (4) forms a wall of the chamber (5). The downstream face (53) of each chamber (5) is substantially aligned with a radial plane (R) of the drum (2).

A method is provided and includes: measuring a surface profile of a polishing pad; obtaining a reference profile of the polishing pad; comparing the surface profile of the polishing pad with the reference profile to generate a difference result; determining a conditioning parameter value according to the difference result; and conditioning the polishing pad using the conditioning parameter value.

A processing apparatus includes a first distinguishing display unit which, when a mechanism making a holding force or a processing force act on a workpiece causes an error, displays a workpiece illustration representing the workpiece to which the error is caused and on which the holding force or the processing force acts distinguishably from another workpiece illustration. The workpiece on which the holding force or the processing force of the mechanism causing the error acts can be thereby identified easily.

A processing apparatus includes a first distinguishing display unit which, when a mechanism making a holding force or a processing force act on a workpiece causes an error, displays a workpiece illustration representing the workpiece to which the error is caused and on which the holding force or the processing force acts distinguishably from another workpiece illustration. The workpiece on which the holding force or the processing force of the mechanism causing the error acts can be thereby identified easily.

A polishing apparatus includes a polisher that polishes a target object to be polished. A holder is rotatable while holding the target object to be polished. Multiple concentric elastic members around the center of a rotation shaft of the holder are provided on the holder and elastically press the target object to be polished against the polisher. Multiple sensors are provided in the elastic members and detect vibration from a polishing surface of the target object to be polished. The detected vibration allows the polishing apparatus to create an unevenness map of the polishing surface and correspondingly actuate the concentric elastic members to remove the unevenness, according to a control sequence set in advance, based on the detected vibration, in a polishing control program to control the concentric elastic members.