A fastener extractor tool and a method of using said tool. The tool comprising a torque-tool body, a plurality of engagement features, and a plurality of gripping edges. The engagement features radially positioned around a rotational axis of the torque-tool body and each comprising a first slanted section, a second slanted section, and a hollow section. The first and second slanted sections terminally and oppositely connected to the hollow section and an acute cavity angle being delineated between the first and second slanted sections of each engagement feature. The method comprising providing the fastener extractor tool, engaging the torque-tool body and engagement features with a fastener, cutting a channel into the fastener with the gripping edge, and rotating the fastener with the torque-tool body.

A bidirectional extraction socket may include a driven end configured to receive drive power from a driving tool, a drive end configured to interface with a fastener, and a body portion extending between the driven end and the drive end about an axis of the extraction socket. The drive end includes a fastener engagement recess extending into the body portion and coaxial with the body portion. The fastener engagement recess is configured to engage with the fastener such that the fastener is drivable in either a clockwise or a counterclockwise direction while avoiding contact with corner portions of the fastener.

The present invention relates in general to the field of high voltage power line insulators, and more specifically, to a tool for installing high voltage power line insulators and a method of use. The installation tool includes a feature that allows a lineworker to safely install high voltage power line insulators of different shapes and sizes using the same installation tool. In particular, the installation tool comprises differently sized sockets that correspond to the distinct head size dimensions of different types of high voltage power line insulators. A purpose of the invention is to provide a tool for installing high voltage power line insulators and a method of use that minimizes risk of injury to the lineworker during installation, is easy to use, and cost-effective to manufacture.

A nut driver includes an elongate drive shank and a reversible socket. The socket has a first hex socket opening sized to engage a hexagonal profile of a first size, and a second hex socket opening sized to engage a hexagonal profile of a second size that is larger than the first size. The socket is mountable on the drive shank in either a first orientation that presents the first hex socket opening for use, or a second orientation that presents the second hex socket opening for use. Additionally, in the first orientation, the socket is mountable in either a screw head receiving position or a drive bit receiving position.

Exemplary embodiments are disclosed of backup tools. In an exemplary embodiment, a backup tool generally includes a socket configured for receiving a nut of a flanged connection; a release nut; and an arm extending generally between the socket and the release nut. The arm defines a reaction surface configured to abut against at least a portion of the flanged connection for holding the nut against rotation when a bolt or another nut on a stud is being rotated relative to the nut within the socket of the backup tool, to thereby tighten the flanged connection.

A drill attachment to facilitate engagement and disengagement of a clamp. A main driver body is configured for attachment to drill such that operation of the drill causes rotation of the driver body and actuates the clamp.

A dual ratcheting tool having multiple ratchet assemblies and handles for rotating adapters, sockets, and other tools is provided. The dual ratcheting tool includes an upper ratchet assembly independently rotationally and mechanically connected to a lower ratchet assembly; a drive member connected to the upper ratchet assembly and the lower ratchet assembly; an upper handle connected to the upper ratchet assembly, the upper handle having an upper directional switch to set a drive direction of the upper ratchet assembly; and a lower handle connected to the lower ratchet assembly, the lower handle having a lower directional switch to set a drive direction of the lower ratchet assembly. The upper and lower handles of the dual ratcheting tool can independently and in combination can drive a socket more quickly and efficiently than ratchets having a single ratchet assembly and handle.

An adjustable socket assembly includes a collet having a first end, a second end, and a perimeter wall. The second end has a receiving aperture therein. The collet is divided into a plurality of sections. A sleeve has a bottom end that receives the collet. The sleeve has an interior surface that tapers inwardly and abuts the sections to move toward each other as the sleeve moves toward the second ends of the sections. A biasing member extends through a top end of the sleeve and engages each of the sections. The biasing member is actuated to bias the sleeve downward to close together the sections and engaged the valve actuator. An engagement head is attached to the upper end of the biasing member and engages a tool to rotate the collet.

A self-reacting center wheel nut assembly includes a reaction ring (120) formed between a center wheel nut (110) and a lock collar assembly (130). The self-reacting center wheel nut assembly may also include a washer (140) and O-rings. The self-reacting center wheel nut assembly improves and simplifies wheel bolt tightening; uses the lock collar assembly as a reaction point by transferring opposing torque generated during installation and removal through the reaction ring, which is reacted on by a dual sleeved drive assembly; may be used with HYTORC electric battery powered torque multiplier gun/tools to deliver quick, accurate and precise torque; eliminates the need for external reaction points such as the rim or ground, thereby eliminating side loads and damage to the wheel; is fully sealed and lubricated; eliminates vehicle movement and the need to lock the brakes; reduces operator fatigue, chances of injury and saves operator time and energy.

Sockets, for example, hexagon sockets, dodecagonal sockets, and splined sockets, that have inner surface geometries adapted to engage a flank of a fastener at a point away from a corner of the fastener. In general, the sockets engage the flank of the fastener at a distance of about 30 to 60 percent of half a length of the flank away from the corner of the fastener. This increases the strength and life of the socket, reduces a risk of the fastener becoming locked or stuck in the socket, and reduces the risk of the fastener being stripped or the socket slipping on the fastener.