Provided is an apparatus for preparing wire rope having a stand; a first cross-member; a second cross-member; a first clamp arm; a second clamp arm; a first clamp; a second clamp; an adjustment wheel; an adjustment screw; and an adjustment gear; wherein the second cross-member is at least partially contained within the first cross-member; wherein the first clamp is disposed at the distal end of the first clamp arm, the second clamp is disposed at the distal end of the second clamp arm, and wherein the first and second clamp arm are spaced from each other; and wherein the distance between the first and second clamp arm is adjustable. Also provided is a method of use for the same.

Embodiments include a clamping apparatus comprising a pair of adjustable anvils configured to apply a clamping pressure on a workpiece secured between the anvils; a center gear comprising a pair of anvil holders respectively coupled to the pair of anvils; an open center configured to receive the workpiece, the anvils being positioned within said open center; and a pair of outer gears arranged on either side of the center gear, the outer gears being configured to rotate about the open center. Rotation of the outer gears causes a linear movement of the anvils along an axis perpendicular to workpiece. Embodiments also includes a clamping system comprising the clamping apparatus, as well as a positioning device for driving the center gear based on a positioning input and a clamping device for driving the outer gears based on a clamping input.

A hold-down clamping apparatus comprising a hold-down clamp with body having a top lip and pair of guide legs disposed between a central screw in the body and a support having holes in vertical alignment with the legs and the screw for securing and holding down a sheet material for processing. The screw is threaded through the support screw hole as the legs are inserted within support holes until the top lips contacts the sheet material to hold down the material and to prevent twisting of the hold-down clamp. Supports with clamps may be fastened to tools or supports. In one embodiment, the support has a grid of holes for securing a plurality of materials with hold-down clamps. In another embodiment, the hold-down clamp comprises a top lip and a guide beam slotted in a support and secured.

A socket fusion jig includes a pipe saddle and coupling saddle spaced apart. Rotation of a handle causes the pipe saddle and coupling saddle to move laterally relative to one another so that the pipe held in the pipe saddle may be fused to the coupling held in the coupling saddle.

Embodiments of a multi-purpose utility clamp may include a component engagement member having a clamp head and a handle. A guide arm is operatively connected to the component engagement member at a first end of the guide arm. A first post is operatively connected to a second end of the guide arm to move linearly relative to the guide arm. A second post at an end of the support post is disposed generally perpendicular to the first post and has a first end connected to the first post and a second end, distal the first end, and the second end is disposed opposite the clamping head. The second post has a generally trapezoidal cross-sectional shape along a length thereof between the first end and the second end, and the second post is configured to be inserted into a channel having a corresponding trapezoidal shape and formed in an auxiliary component to be clamped to another component.

The disclosure relates to methods and tools for handling a component, the tools (10) comprising a first clamp seat (12) for receiving a first surface of the component and a second clamp seat (14, 16) for receiving a second surface of the component, the second surface being opposite to the first surface. The tool further comprises an actuator (45) for moving the first clamp seat to clamp the component between the first clamp seat and the second clamp seat with a predetermined clamping force, and an electric motor (40) for driving the actuator (45). The tool (10) further comprises a control configured to determine currents in the electric motor and to control the electric motor to provide the predetermined clamping force based on the determined currents. Also methods for determining a desired current level in an electric motor driving an actuator for clamping a component and methods for controlling a clamping force in a tool are provided.

The invention relates to a clamping device for clamping a workpiece, comprising a clamping element for clamping the workpiece; a rod having multiple radial slits disposed one behind the other in longitudinal direction of the rod, which each only extend along a partial circumferential area of the rod; a receiving device for receiving the clamping element and the rod; a longitudinal guide, within which the rod is disposed rotatably between a latching position and a release position; a locking mechanism disposed on the longitudinal guide, which does not engage with any of the radial slits in the release position such that the rod is movable in axial direction within the longitudinal guide, and engages with at least one of the radial slits in the latching position such that the rod is fixed in axial direction within the longitudinal guide. Furthermore, the invention relates to a processing table with a clamping device.

An alignment tool for use in a gas turbine engine according to an exemplary aspect of the present disclosure includes, among other things, a clamp portion, a component engagement portion and an arm portion that extends between the clamp portion and the component engagement portion. The clamp portion establishes a fixed datum surface for positioning a component within the gas turbine engine.

An alignment tool for use in a gas turbine engine according to an exemplary aspect of the present disclosure includes, among other things, a clamp portion, a component engagement portion and an arm portion that extends between the clamp portion and the component engagement portion. The clamp portion establishes a fixed datum surface for positioning a component within the gas turbine engine.

An apparatus configured to structurally replace a cracked weld in a nuclear plant may include: a first body portion that includes a first gripping portion; a second body portion that includes a second gripping portion; a wedge portion between the first and second body portions; and/or an adjustment portion. The first body portion may be configured to slidably engage the second body portion. The wedge portion may be configured to exert force on the slidably engaged first and second body portions. The adjustment portion may be configured to increase or decrease the force exerted by the wedge portion on the slidably engaged first and second body portions. When the adjustment portion increases the force exerted by the wedge portion on the slidably engaged first and second body portions, a distance between the first and second gripping portions may decrease.