A driving tool is provided, including: a rod member, including a first end and a second end which includes two separate connection sections; a swingable assembly, including a swingable member having a third end and a fourth end, a shaft and a ring retainer, the third end extending to between the two connection sections, the fourth end including an assembling portion, the shaft being disposed through the two connection sections and the third end, a first end of the shaft being protrusive out from a first one of the two connection sections, the ring retainer being detachably mounted on the first end of the shaft and blocked by the first one of the two connection sections in an axial direction of the shaft; and at least one driving member, detachably assembled with the assembling portion.

A striking wrench comprising a socket with a working side designed to cooperate with a fastener and an impact side disposed on an opposite end of the working side, a handle comprising an attachment end designed to cooperate with the socket via an interference fit to form a rigid connection, and an anvil disposed at an end of the handle opposite the attachment end. The striking wrench may also include a secondary retention element designed to further secure the rigid connection, which can be a retaining ring, a pin and tunnel, or a threaded fastener.

A striking wrench comprising a socket with a working side designed to cooperate with a fastener and an impact side disposed on an opposite end of the working side, a handle comprising an attachment end designed to cooperate with the socket via an interference fit to form a rigid connection, and an anvil disposed at an end of the handle opposite the attachment end. The striking wrench may also include a secondary retention element designed to further secure the rigid connection, which can be a retaining ring, a pin and tunnel, or a threaded fastener.

An extraction tool for extracting a shim located in a turbomachine and provided with a through-hole, includes an extractor pin configured to be inserted into the through-hole of the shim; a first gripping member with a first distal end intended to be positioned opposite the through-hole on a first side of the shim and arranged to retain a first end of the extractor pin; and a second gripping member including a second distal end intended to be positioned opposite the through-hole on a second, opposite side of the shim, and arranged to retain a second, opposite end of the extractor pin, after the extractor pin has been inserted into the through-hole of the shim.

An extraction tool for extracting a shim located in a turbomachine and provided with a through-hole, includes an extractor pin configured to be inserted into the through-hole of the shim; a first gripping member with a first distal end intended to be positioned opposite the through-hole on a first side of the shim and arranged to retain a first end of the extractor pin; and a second gripping member including a second distal end intended to be positioned opposite the through-hole on a second, opposite side of the shim, and arranged to retain a second, opposite end of the extractor pin, after the extractor pin has been inserted into the through-hole of the shim.

A tool includes an operative rod, a guiding rod, a conveying screw and two detaching elements. The guiding rod includes a middle section connected to the operative rod and two terminal sections extending from the middle section. The conveying screw includes two threaded sections. Threads of the threaded sections extend in opposite directions. Each of the detaching elements includes a fixing aperture and a screw hole. The fixing aperture receives a corresponding one of the terminal sections of the guiding rod. The screw hole receives a corresponding one of the threaded sections of the conveying screw. Thus, the detaching elements are moved toward each other when the conveying screw is rotated in a first direction and that the detaching elements are moved from each other when the conveying screw is rotated in a second direction.

An electric power tool in one aspect of the present disclosure includes a motor, an impact mechanism, an impact detector, and a control circuit. The control circuit controls a motor current based on a drive duty ratio in a first driving term. The first driving term corresponds to a time period from when the motor is started until impact is detect. The drive duty ratio corresponds to a sum of a basic duty ratio and a proportional duty ratio. The control circuit controls the motor current so that an actual rotational speed of the motor is consistent with a target rotational speed after elapse of the first driving term.

An electric power tool in one aspect of the present disclosure includes a motor, an impact mechanism, an impact detector, and a control circuit. The control circuit controls a motor current based on a drive duty ratio in a first driving term. The first driving term corresponds to a time period from when the motor is started until impact is detect. The drive duty ratio corresponds to a sum of a basic duty ratio and a proportional duty ratio. The control circuit controls the motor current so that an actual rotational speed of the motor is consistent with a target rotational speed after elapse of the first driving term.

The present disclosure relates to a method for use in installation of a mill liner, the method including (a) retaining a mounting bolt at least partially within a liner opening extending through the mill liner, (b) positioning the mill liner against a mill shell so that the retained mounting bolt is aligned with a mill shell opening extending through the mill shell, (c) selectively coupling an extraction tool to the mounting bolt, the coupling performed by an operator outside of the mill shell, (d) detaching the mounting bolt from the liner using the extraction tool; (e) pulling the mounting bolt through the mill shell opening so that at least a portion of the mounting bolt protrudes outside of the mill shell, and, (e) securing a fastener onto the mounting bolt to thereby attach the mill liner to the mill.

A nut runner device includes a main body including spindles, and support portions that support the spindles rotatably around a longitudinal axial line, a detachable unit that is detachably connected to a tip of the main body, and includes a wrench that is disposed coaxially with the spindles and is rotatable integrally with the spindles and an air passage that extends inside of the spindles and the detachable unit in a direction along the longitudinal axial line, and connects a discharge port provided in the spindle, and a suction port that opens to a tip surface of the detachable unit, wherein a tip portion of the wrench is disposed in the suction port, and air that is sucked from the suction port to the discharge port 20c via the air passage passes by the tip portion of the wrench and a fastening member fitted to a tip of the wrench.