A controller is provided for use in controlling a blade sharpening system that includes at least one grinding wheel operable to sharpen the blade. The controller includes a memory device, and a processor communicatively coupled to the memory device. The processor is configured to receive signals from at least one sensor, the at least one sensor operable to monitor rotation of the at least one grinding wheel. The processor is further configured to adjust a position of the at least one grinding wheel relative to the blade based on the received signals.

The present disclosure provides a Grinding apparatus for grinding working tips of hard metal inserts of rock drill bits, comprising: a grinding machine, means for holding a rock drill bit to be ground and a support system, the support system, the grinding machine equipped with a spindle assembly having an output drive shaft having a longitudinal axis, one of a plurality of grinding tools of different sizes and profiles detachably connected to the output drive shaft for grinding different sizes and profiles of working tips; and having a control system having a programmable operator control panel capable of directly or indirectly monitoring and adjusting one or more operational parameters, a programmable control card provided having a circuit board containing a central processor, an RFID reader provided within operator control panel together with a touch screen display wherein when the free end of a grinding cup equipped with an RFID tag in accordance with present invention is inserted into the RFID reader a proximity sensor detects the RFID tag and scans the data on the tag wherein the data includes a specific ID identifier for the particular grinding cup and the number of grinding cycles over which it has been used to date.

A power tool includes a housing, a motor supported by the housing, a battery pack interface configured to receive a battery pack, a plurality of sensors configured to generate sensor data indicative of an operational state of the power tool, and an electronic controller. The electronic controller includes an electronic processor and a memory. The memory includes a machine learning control program for execution by the electronic processor. The electronic controller is configured to receive the sensor data indicative of the operational state of the power tool, process the sensor data using the machine learning control program to determine whether the power tool is experiencing a stall condition, and disable the motor when the power tool is determined to be experiencing the stall condition.

Intelligent, hand-held, battery-operated, random-orbital nibber sander and polisher tools are adapted for removing defects in painted surfaces. Both tools are substantially the same size, with the exception of the head of the tool, wherein different pad sizes, RPM and orbital patterns are provided for the distinct sanding and polishing operations. Multiple operational features ensure accurate, reliable and repeatable sanding and polishing operations, with capabilities for identifying operator error. The inventive tools may include trigger time/RPM setting and indication, leveling, network communications, calibration downloading, and internal battery life monitoring with a charge-remaining indicator.

A grinding machine including a support pedestal that supports a drive motor that supports an abrasive wheel rotatably coupled to the drive motor; a motor drive operatively coupled to the drive motor; a safety controller operatively coupled with the drive motor and motor drive; an E-stop operatively coupled to the safety controller; a foot pedal switch operatively coupled to the safety controller; and a 480 volt alternating current 3 phase electrical power supply electrically coupled to the drive motor.

The present disclosure describes an apparatus and a method to detect a polishing pad profile during a polish process and adjust the polishing process based on the detected profile. The apparatus can include a polishing pad configured to polishing a substrate, a substrate carrier configured to hold the substrate against the polishing pad, and a detection module configured to detect a profile of the polishing pad. The detection module can include a probe configured to measure a thickness of one or more areas on the polishing pad, and a beam configured to support the probe, where the probe can be further configured to move along the beam.

Shortcomings associated with insufficient control of a conventional CMP-process are obviated by providing an CMP-apparatus configured to complement a constant force (to which a workpiece that is being polished is conventionally exposed) with a time-alternating force and/or means for measuring an electrical characteristic of the CMP-process. The time-alternating force is applied with the use of a system component that is electrically isolated from the workpiece and that is disposed in the carrier-chick in which the workpiece is affixed for CMP-process, while the electrical characteristic is measured with the use of a judiciously-configured reservoir in which the used fluid is collected. The use of such CMP-apparatus.

The present invention relates to a chemical mechanical polishing (CMP) apparatus for polishing a workpiece, such as a metal body, to a mirror finish. The chemical mechanical polishing apparatus includes: a polishing pad (2) having an annular polishing surface (2a) which has a curved vertical cross-section; a workpiece holder (11) for holding a workpiece (W) having a polygonal shape; a rotating device (15) configured to rotate the workpiece holder (11) about an axis of the workpiece (W); a pressing device (14) configured to press a periphery of the workpiece (W) against the annular polishing surface (2a); and an operation controller (25) configured to change a speed at which the rotating device (15) rotates the workpiece (W) according to a rotation angle of the workpiece (W). The pressing device (14) is disposed more inwardly than the workpiece holder (11) in a radial direction of the polishing table (3).

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.