There is provided herein a lifting and inversion bar especially configured for repositioning cable spools which typically comprise fragile end stop annuli. The present cable spool lifting and inversion bar is configured for repositioning a cable spool comprising a length and radius between horizontal (that is wherein the axis of the cable spool is horizontal) and vertical (that is wherein the axis of the cable spools vertical) orientations. The inversion bar comprises a straight frame and an orthogonal shaft bisecting the frame into long and short ends. Furthermore, for the vertical orientation, the spool is able to freely rests atop the frame without additional support which negates the requirement for horizontal spacers as does the prior art. In this way, the spool may be conveniently lifted from the inversion by using a forklift, a convenient procedure not made possible by the prior art arrangements.

A materials handling vehicle is provided comprising a pair of forks to be inserted in a longitudinal direction of the forks into a pallet having one or more stringers. A pallet clamp device is provided including first and second operating devices, one mounted in each fork for actuating respective punch members into engagement with an adjacent surface on the pallet. Each operating device comprises a module located within a cavity in one of the forks, the module including an actuator, one of the respective punch members, and a linkage structure connecting the actuator and the respective punch member.

A suspended tire manipulator for use by an operator in lifting a tire having a mounting aperture includes a first handle attached to a first proximal arm. The first proximal arm is connected to a first distal arm at an obtuse angle. The manipulator includes a rotary balancer pivotally mounted to the first distal arm. The rotary balancer provides a pivoting torque to the first distal arm in response to operator movements raising and lowering the manipulator via manual force applied at the handle. A vertical support has a lower end and an upper end. The lower end connects to the rotary balancer. The manipulator includes a pair of gripper shoes. The pair of gripper shoes are slidably mounted on a rail and move in opposite inboard and outboard directions on the rail.

A fork assembly can include multiple forks configured to surround a load. Multiple attachments can be made on the forks to couple to straps for support a load. The fork assembly can further include multiple fork extensions having end attachments to couple to straps for pulling on the load. Alternatively, the fork assembly can include multiple fork lifters having blades rotatable between a non-lift position and a lift position. The fork extensions can also have blades rotatable between a non-pullable position and a pullable position. The blade rotation can be performed by a remote rotate mechanism by an operator operating the fork assembly. In some embodiments, the fork attachment assembly for a forklift or a forklift vehicle can include roller legs coupled at far ends of the fork beams or the fork extensions. The fork assembly can include roller legs coupled at far ends of the fork beams or the fork extensions. The fork assembly can include a clamping device coupled at a far end of the fork beam or the fork extension.

A fork assembly can include multiple forks configured to surround a load. Multiple attachments can be made on the forks to couple to straps for support a load. The fork assembly can further include multiple fork extensions having end attachments to couple to straps for pulling on the load. Alternatively, the fork assembly can include multiple fork lifters having blades rotatable between a non-lift position and a lift position. The fork extensions can also have blades rotatable between a non-pullable position and a pullable position. The blade rotation can be performed by a remote rotate mechanism by an operator operating the fork assembly. In some embodiments, the fork attachment assembly for a forklift or a forklift vehicle can include roller legs coupled at far ends of the fork beams or the fork extensions. The fork assembly can include roller legs coupled at far ends of the fork beams or the fork extensions. The fork assembly can include a clamping device coupled at a far end of the fork beam or the fork extension.

An apparatus for the non-compression transportation of a convolutely wound web material parent roll is disclosed. The apparatus comprises a motivator and an end effector operably, cooperatively, and pivotably engaged to the motivator. The end effector provides a pair of opposed core plugs capable of cooperative and penetrating engagement with a core of the parent roll when the first core plug is disposed proximate to a first portion of the core of the parent roll and the second core plug is disposed proximate to a second portion of the core of the parent roll disposed distal therefrom.

A clamping assembly for a load-carrying vehicle capable of exerting an adjustable clamping force, comprises first and second clamp arms, and first and second clamp arm sensing elements. The first and second clamp arms are movable towards and away from each other to contact and exert a clamping force on a load sufficient for lifting the load and transporting the load. The first clamp arm sensing elements are positioned at spaced apart locations on the first clamp arm. The second clamp arm sensing elements are positioned at spaced apart locations on the second clamp arm. The first clamp arm sensing elements and the second clamp arm sensing elements are configured sense and feed back forces exerted by the first and second clamp arms, respectively, in engaging the load such that the clamp arms can be moved relative to each other to adjust the clamping force applied to the load.

Some illustrative embodiments of a fire tube implement for extraction and insertion of a fire tube may include an elongate shaft that is configured to extend outward and to be received within an opening in the fire tube. In some embodiments, the elongate shaft may carry at least one extender that is moveable between an extended position and a retracted position normal to a longitudinal axis of the elongate shaft. The at least one extender may be configured to engage an internal surface of the fire tube within the opening when the at least one extender is in the extended position. In some embodiments, a stabilizer may be laterally disposed from an exterior surface of the elongate shaft and securable to the fire tube. The elongate shaft may be operable by a powered machine.

An implement is disclosed for use in moving a fire tube in relation to a heat treater. The disclosed implement includes a frame extending along a first axis, a shaft extending from the frame along a second axis, and a stabilizer extending from the frame that is configured to inhibit rotation of the fire tube when the implement is employed to move the fire tube.

A clamping assembly for a load-carrying vehicle capable of exerting an adjustable clamping force, comprises first and second clamp arms, and first and second clamp arm sensing elements. The first and second clamp arms are movable towards and away from each other to contact and exert a clamping force on a load sufficient for lifting the load and transporting the load. The first clamp arm sensing elements are positioned at spaced apart locations on the first clamp arm. The second clamp arm sensing elements are positioned at spaced apart locations on the second clamp arm. The first clamp arm sensing elements and the second clamp arm sensing elements are configured sense and feed back forces exerted by the first and second clamp arms, respectively, in engaging the load such that the clamp arms can be moved relative to each other to adjust the clamping force applied to the load.