A power tool is provided including a housing defining a cavity therein, where the housing includes a motor case and a handle portion extending along a longitudinal axis of the housing from the motor case; an electric motor having a drive shaft and mounted within the motor case; a partitioning wall extending radially and separating the motor case portion from the non-motor case portion of the housing; and a bearing pocket with an open end facing the motor case portion formed in the partitioning wall and a main body extending away from the electric motor for receiving a rotor bearing. The handle portion includes two elongate walls extending from the partitioning wall, a circuit board supported by the two elongate walls and including a motor drive circuit, and two covers secured to the two elongate walls to cover the circuit board.

A power tool is provided including a housing defining a cavity therein, where the housing includes a motor case and a handle portion extending along a longitudinal axis of the housing from the motor case; an electric motor having a drive shaft and mounted within the motor case; a partitioning wall extending radially and separating the motor case portion from the non-motor case portion of the housing; and a bearing pocket with an open end facing the motor case portion formed in the partitioning wall and a main body extending away from the electric motor for receiving a rotor bearing. The handle portion includes two elongate walls extending from the partitioning wall, a circuit board supported by the two elongate walls and including a motor drive circuit, and two covers secured to the two elongate walls to cover the circuit board.

A surface processing device includes a machining mechanism and a driving mechanism driving the machining mechanism to polish a workpiece. The machining mechanism includes a machining assembly and a first transmission shaft eccentrically coupled with the machining assembly at a first end. The first transmission shaft rotates to bring the machining assembly into revolving around the first transmission shaft. The driving mechanism includes a motor connected to a second end of the first transmission shaft for outputting power to the machining mechanism. The surface processing device provides smooth machining without the noise of a pneumatically-powered tool.

A power tool is provided including a gear case having a spindle, a motor case connected to a rear end of the gear case along a longitudinal axis; a handle portion extending from a rear end of the motor case along the longitudinal axis; a motor housed inside the motor case; a fan in rotational connection with the motor; at least one air intake arranged at least one of the motor case or the handle portion near the rear end of the motor case; and a power module including power switches for driving the motor and a heat sink. The power module is housed in at least one of the motor case or the handle portion near the rear end of the motor case such that rotation of the fan causes air flow to enter through the air intake and flow near the heat sink and through the motor.

A power tool includes a three-phase DC motor, a power switching network, a power source, and an electronic processor. A first phase of the motor is connected between a first low side electronic switch and a power source electronic switch, and connected to the power source via a first high side electronic switch in parallel with a diode. The electronic processor is configured to receive an indication to stop the motor during operation of the motor and activate the first low side electronic switch and a second low side electronic switch for a first predetermined time responsive to receiving the indication such that a back-electromagnetic force generated by the motor is stored in the first phase. The electronic processor is configured to deactivate the second low side electronic switch after the first predetermined time such that a first regenerative current is provided to the power source via the diode.

A power tool includes a three-phase DC motor, a power switching network, a power source, and an electronic processor. A first phase of the motor is connected between a first low side electronic switch and a power source electronic switch, and connected to the power source via a first high side electronic switch in parallel with a diode. The electronic processor is configured to receive an indication to stop the motor during operation of the motor and activate the first low side electronic switch and a second low side electronic switch for a first predetermined time responsive to receiving the indication such that a back-electromagnetic force generated by the motor is stored in the first phase. The electronic processor is configured to deactivate the second low side electronic switch after the first predetermined time such that a first regenerative current is provided to the power source via the diode.

A surface preparation support apparatus includes a creeper and a linear actuator. The linear actuator includes a base-end and a tool-end that is opposite the base-end. The base-end is coupled to the creeper. The tool-end is linearly movable relative to the base-end. A surface preparation tool is coupleable to the tool-end of the linear actuator. The surface preparation support apparatus also includes an actuator-controller. The actuator-controller is coupled to the linear actuator. The actuator-controller is operable to selectively actuate the linear actuator. The surface preparation support apparatus further includes a tool-controller. The tool-controller is configured to be coupled to the surface preparation tool. The tool-controller is operable to selectively energize the surface preparation tool.

A surface preparation support apparatus includes a creeper and a linear actuator. The linear actuator includes a base-end and a tool-end that is opposite the base-end. The base-end is coupled to the creeper. The tool-end is linearly movable relative to the base-end. A surface preparation tool is coupleable to the tool-end of the linear actuator. The surface preparation support apparatus also includes an actuator-controller. The actuator-controller is coupled to the linear actuator. The actuator-controller is operable to selectively actuate the linear actuator. The surface preparation support apparatus further includes a tool-controller. The tool-controller is configured to be coupled to the surface preparation tool. The tool-controller is operable to selectively energize the surface preparation tool.

A hand-held power tool includes an electronically commutated motor including a motor winding. Motor electronics of the hand-held power tool are configured to electronically commutate the motor winding using a selected one of a plurality of electrical precontrol angles, thereby adapting the motor winding to different mechanical load conditions of the electronically commutated motor.

A method for operating a machine tool (1), in particular an angle grinder, comprising a tool (3) that can be rotatably brought into operative connection with a driven shaft (7), the machine tool (1) having a drive device (4) for actuating the driven shaft (7), a control device (8) for actuating the drive device (4) and at least one sensor device (9, 10) operatively connected to the control device (8). The sensor device (9, 10) is used to determine whether a device (3, 11) is operatively connected in a defined manner to a defined region of the machine tool (1), the control device (8) enabling operation of the drive device (4) only if the query result is positive. A machine tool (1) for carrying out a method of this kind is also described.