Described herein are a system and methods for implementing a tool-agnostic device. In examples, the system may determine location and state information using sensors of the tool-agnostic device. Based on this information, the system may communicate with a virtual reality system for display and user interaction with a virtual reality environment. The tool-agnostic device may be removed and re-attached to a number of different tools. The tool-agnostic device allows tracking of a number of different tools without customization or retrofitting each tool. The tool-agnostic device may serve as a safety-shutoff device in addition to tracking tool use and movement. When the system determines that a tool is operating in an unsafe manner the tool-agnostic device may interrupt the power to the tool.

Described herein are a system and methods for implementing a tool-agnostic device. In examples, the system may determine location and state information using sensors of the tool-agnostic device. Based on this information, the system may communicate with a virtual reality system for display and user interaction with a virtual reality environment. The tool-agnostic device may be removed and re-attached to a number of different tools. The tool-agnostic device allows tracking of a number of different tools without customization or retrofitting each tool. The tool-agnostic device may serve as a safety-shutoff device in addition to tracking tool use and movement. When the system determines that a tool is operating in an unsafe manner the tool-agnostic device may interrupt the power to the tool.

Described herein are a system and methods for implementing a tool-agnostic device. In examples, the system may determine location and state information using sensors of the tool-agnostic device. Based on this information, the system may communicate with a virtual reality system for display and user interaction with a virtual reality environment. The tool-agnostic device may be removed and re-attached to a number of different tools. The tool-agnostic device allows tracking of a number of different tools without customization or retrofitting each tool. The tool-agnostic device may serve as a safety-shutoff device in addition to tracking tool use and movement. When the system determines that a tool is operating in an unsafe manner the tool-agnostic device may interrupt the power to the tool.

Described herein are a system and methods for implementing a tool-agnostic device. In examples, the system may determine location and state information using sensors of the tool-agnostic device. Based on this information, the system may communicate with a virtual reality system for display and user interaction with a virtual reality environment. The tool-agnostic device may be removed and re-attached to a number of different tools. The tool-agnostic device allows tracking of a number of different tools without customization or retrofitting each tool. The tool-agnostic device may serve as a safety-shutoff device in addition to tracking tool use and movement. When the system determines that a tool is operating in an unsafe manner the tool-agnostic device may interrupt the power to the tool.

A power tool and method for recording and playing back a motor parameter. The power tool includes a housing, a motor, a trigger, and a controller. The trigger outputs an activation signal based on a user input. The controller receives a user mode selection signal indicating a selected mode. The controller enters the recording mode when the user mode selection indicates the recording mode, and records a motor parameter to generate a recorded motor parameter. The recorded motor parameter covers a first time period in which motor is operating in response to depression of the trigger, a second time period in which motor is inactive in response to release of the trigger, and a third time period in which motor is operating in response to another depression of the trigger. In the playback mode, the controller operates the motor based on the recorded motor parameter upon receiving the activation signal.

A power tool and method for recording and playing back a motor parameter. The power tool includes a housing, a motor, a trigger, and a controller. The trigger outputs an activation signal based on a user input. The controller receives a user mode selection signal indicating a selected mode. The controller enters the recording mode when the user mode selection indicates the recording mode, and records a motor parameter to generate a recorded motor parameter. The recorded motor parameter covers a first time period in which motor is operating in response to depression of the trigger, a second time period in which motor is inactive in response to release of the trigger, and a third time period in which motor is operating in response to another depression of the trigger. In the playback mode, the controller operates the motor based on the recorded motor parameter upon receiving the activation signal.

A housing holding a stator has increased rigidity. A vibration driver drill includes a motor including a stator and a rotor rotatable relative to the stator, a gear case in front of the motor, a gear in the gear case to receive rotation of the rotor, an output shaft protruding frontward from the gear case to receive rotation from the gear, an integral cylindrical housing accommodating the motor and including a front portion with an opening and a rear portion closed, a gear case housing connected to the front portion of the integral cylindrical housing and including a right part and a left part and holding the gear case, and a grip housing extending downward from the gear case housing.

A housing holding a stator has increased rigidity. A vibration driver drill includes a motor including a stator and a rotor rotatable relative to the stator, a gear case in front of the motor, a gear in the gear case to receive rotation of the rotor, an output shaft protruding frontward from the gear case to receive rotation from the gear, an integral cylindrical housing accommodating the motor and including a front portion with an opening and a rear portion closed, a gear case housing connected to the front portion of the integral cylindrical housing and including a right part and a left part and holding the gear case, and a grip housing extending downward from the gear case housing.

A metal detector 20 includes a cover 25, a detection signal acquisition unit 31, a determination unit 32, a display unit 24, and a display control unit 34. The cover 25 is removably attached to a tip portion 18 of a handheld power tool 10. The detection signal acquisition unit 31 acquires a detection signal that changes according to the detection strength of rebar W1 in concrete W. The determination unit 32 determines the presence or absence of the rebar W1 on the basis of the acquisition result acquired by the detection signal acquisition unit 31. The display unit 24 displays the presence or absence of the rebar W1 by lighting lamps in different colors. The display control unit 34 controls so as to switch the color of the light displayed on the display unit 24 on the basis of the determination result by the determination unit 32.

A metal detector 20 includes a cover 25, a detection signal acquisition unit 31, a determination unit 32, a display unit 24, and a display control unit 34. The cover 25 is removably attached to a tip portion 18 of a handheld power tool 10. The detection signal acquisition unit 31 acquires a detection signal that changes according to the detection strength of rebar W1 in concrete W. The determination unit 32 determines the presence or absence of the rebar W1 on the basis of the acquisition result acquired by the detection signal acquisition unit 31. The display unit 24 displays the presence or absence of the rebar W1 by lighting lamps in different colors. The display control unit 34 controls so as to switch the color of the light displayed on the display unit 24 on the basis of the determination result by the determination unit 32.