An improved technique relating to mounting of a battery in an impact tool which has a handle configured to move with respect to a tool body. A hammer drill has a body, a handle part and a battery mounting part. The handle part is configured to slide with respect to the body under a biasing force of a coil spring. The battery mounting part has a plurality of mounting parts. At least one of the mounting parts of the battery mounting part is connected to the handle part and slides together with the handle part with respect to the body during operation.

A power tool, such as a rotary hammer, includes a housing, an output shaft for mounting a tool accessary and a motor having a motor shaft that generates a rotational output for rotating and linearly hammering the output shaft. The rotational output of the motor shaft is coupled to the output shaft via a driving mechanism that includes a hammer mechanism. An intervening member is axially movable relative to the motor shaft and is operably coupled between the motor shaft and the hammer mechanism. The hammer mechanism and the output shaft are supported by a movable support that is axially movable relative to the housing. Because the output shaft and the driving mechanism are movable relative to the motor and the housing, which preferably includes handle, via the intervening member and the movable support during hammering operations, vibration generated during hammering operations can be dampened before reaching the housing.

The power tool includes: a handle; a biasing member for biasing the handle in a direction away from a final output shaft in the axial direction; at least one guiding member disposed between a housing and a first part of the handle so as to extend in the axial direction and configured to slidably guide relative movement between the handle and the housing; and at least one elastic member disposed at least one of between the at least one guiding member and the housing and between the at least one guiding member and the first part of the handle. The at least one guiding member is disposed so as to be movable relative to the housing or the handle in a crossing direction that crosses the axial direction by elastic deformation of the at least one elastic member in the crossing direction.

Vibration suppression handle structures for high-vibration handheld machines (e.g., jackhammers) are provided that offer improved vibration suppression. The handle structures of examples include two handles that are rotatably connected to X-shaped structures for vibration suppression. For instance, one side of each of the first and second handles is rotatably connected to one of the X-shaped structures, and the other side of each of the first and second handles is rotatably connected to the second X-shaped structure. The X-shaped structures of examples are adjustable in size and stiffness and thus can be adapted for different sized or shaped handheld machines. Jackhammers are further provided that include the vibration suppression handle structures.

A device (100) for placing a seal (J) on a mounting (S) including a vibration generator (10), that includes: a main body (11); a distal portion (12), movable relative to the main body, onto which a cap (13) having a contact surface (13a) for engaging with the seal is attached; and drive elements (14), configured to drive the distal portion in reciprocal translation relative to the main body, such as to place the seal on the mounting when the contact surface (13a) of the cap (13) engages with the seal (J) that is placed on the mounting (S). The device includes: a grasping handle (20), connected to the main body; and resilient connection elements (30a, 30b) that are located between the main body and the grasping handle and are configured such as to limit the propagation, in the grasping handle, of the vibrations generated by the reciprocal translation movement.

The present invention introduces a system of modular attachments for planishing hammers and pistol-style air hammer/chisels, significantly enhancing their functionality and versatility in metalworking applications. The modular system includes three specialized attachments: the stepper, for creating precise stepped profiles; the flanger, for forming reinforced edges and flanges; and the shrinker/stretcher, for shaping complex curves through controlled shrinking and stretching. Each attachment integrates seamlessly with the tools via an attachment interface, designed for secure installation, rapid replacement, and ergonomic adaptability. The attachments can be used individually or in combination, offering precision and efficiency for tasks in automotive restoration, aerospace fabrication, artistic metalworking, and more. The invention also includes an innovative interface for use with handheld planishing hammers or air-powered chisels, enabling portable and powerful performance. By expanding the range of operations achievable with a single tool, this invention provides a versatile, efficient, and precise solution for modern metalworking.

A power tool having a hammer mechanism includes a final output shaft configured to removably hold a tool accessory and defining a driving axis of the tool accessory, a housing, and a handle movable relative to the housing in an axial direction of the driving axis. The housing and the handle at least partially have such a shape that a radial distance between the housing and the handle is shorter when the handle is located at a first relative position maximally separated from the housing in the axial direction than when the handle is located at a second relative position close to the housing in the axial direction.

A hydraulic hammer includes: a cylinder having a first cylinder end and a second cylinder end opposite the first cylinder end; a piston disposed within the cylinder, the piston having a first piston end, the piston being reciprocatingly movable with respect to the cylinder along an axial direction; a valve body disposed on the first cylinder end so as to define a valve body cavity; and a seal carrier sealingly arranged between the first piston end and the first cylinder end and being reciprocatingly movable with respect to the cylinder along the axial direction. The piston is reciprocatingly movable with respect to the seal carrier along the axial direction.

A method of driving a rod into the ground comprises coupling an impact portion of an attachment to a powered hammer, positioning the rod between a first jaw of the attachment and a second jaw of the attachment, activating a first motor to move the first jaw toward the second jaw, such that the rod is clamped between the two jaws, and activating a second motor to drive an axial impact mechanism of the powered hammer to deliver repeated axial impacts to the impact portion of the attachment.

A power tool having a hammer mechanism includes a final output shaft configured to removably hold a tool accessory and defining a driving axis of the tool accessory, a housing, and a handle movable relative to the housing in an axial direction of the driving axis. The housing and the handle at least partially have such a shape that a radial distance between the housing and the handle is shorter when the handle is located at a first relative position maximally separated from the housing in the axial direction than when the handle is located at a second relative position close to the housing in the axial direction.