A high visibility push-pull handler configured to be mounted on a lift truck. The handler comprising a frame assembly, a pantograph mechanism coupled to the frame assembly, and a faceplate assembly coupled to the pantograph mechanism. The hander is configured with a view window extending through the handler, the view window not obstructed by parts of the handler when the handler is in any normal operating configuration, including a fully extended configuration, a fully retracted configuration, and any configuration in between the full extended and fully retracted positions.

An automated mobile vehicle (AMV) including a frame forming a pallet bed for a pallet, and having an automated mobile robot bus, separate and distinct from the pallet bed, a drive section coupled to the frame to provide automated vehicle mobility, and a controller operably coupled to the drive section to effect automated vehicle mobility, wherein, the robot bus has a bus interface for docking independent automated mobile robots (AMR) to the frame so that the AMR is carried by the frame, wherein the AMR has independent automated mobility so that undocked from the frame, the AMR is free to roam independent from the AMV, and wherein the AMR is fungible for docking with the frame from a number different AMRs, to effect a predetermined material handling characteristic, and wherein the controller is coupled to the AMR to manage control of the predetermined material handling characteristic with the AMR undocked from the frame and moving as a unit apart from the frame.

A high visibility push-pull handler configured to be mounted on a lift truck. The handler comprising a frame assembly, a pantograph mechanism coupled to the frame assembly, and a faceplate assembly coupled to the pantograph mechanism. The hander is configured with a view window extending through the handler, the view window not obstructed by parts of the handler when the handler is in any normal operating configuration, including a fully extended configuration, a fully retracted configuration, and any configuration in between the full extended and fully retracted positions.

A retractable pallet fork carriage assembly is provided that enhances the safe operation of a lift vehicle, such as a loader or telehandler. A carriage assembly is coupled to a fork tyne assembly through scissor links that expand and retract the tynes relative to the carriage assembly. When the scissor links are closed, the fork tynes extend through the carriage assembly to receive a payload (e.g., a pallet). When an operator wants to remove the payload, the fork tynes retract while the payload is supported against the carriage assembly. In this way, the load remains in one stationary position while pallet fork tynes are retracted under the payload to release the payload. Various sensors generate and/or send signals to limit the operation of the boom lift, boom, and/or retractable attachment when a distance or load is out of a threshold range.

A high visibility push-pull handler configured to be mounted on a lift truck. The handler comprising a frame assembly, a pantograph mechanism coupled to the frame assembly, and a faceplate assembly coupled to the pantograph mechanism. The hander is configured with a view window extending through the handler, the view window not obstructed by parts of the handler when the handler is in any normal operating configuration, including a fully extended configuration, a fully retracted configuration, and any configuration in between the full extended and fully retracted positions.

A high visibility push-pull handler configured to be mounted on a lift truck. The handler comprising a frame assembly, a pantograph mechanism coupled to the frame assembly, and a faceplate assembly coupled to the pantograph mechanism. The hander is configured with a view window extending through the handler, the view window not obstructed by parts of the handler when the handler is in any normal operating configuration, including a fully extended configuration, a fully retracted configuration, and any configuration in between the full extended and fully retracted positions.

This invention relates to a fork carriage for a truck mounted forklift, the fork carriage comprising an upright rear section for mounting onto the lifting assembly of the forklift, an upright forward section, shorter than the upright rear section, for reception of tines, and a pantograph linkage connecting the upright rear section and upright forward sections together. The pantograph linkage comprises a first and second linkage arm however the second linkage arm is shorter than the first linkage arm and does not extend all the way forward to the upright forward section. Instead, there is provided a third linkage arm with a hinge joint along its length, the third linkage arm being connected at various positions along its length to each of the first linkage arm, the second linkage arm and the upright forward section. In this way, the pantograph linkage can achieve the same reach with a lower upright forward section and access to top far side loads is facilitated.

An industrial truck includes a main chassis, a transport platform to transport goods, a lifting device to raise and lower the transport platform, and a pushing device with at least one actuatable pushing arm. The pushing device displaces the goods relative to the transport platform.

A method and apparatus for rapid loading stacks of items aboard vessels which can include rotating palletized items to depalletize the items, and then placing the items on a lifting robot, lifting the robot and items into the hold of a vessel, removing the items from the robot using a load push lift truck, and then using the load push lift truck to stow the items in a stowage location. The empty robot can be removed from the hold of the vessel and put in a position to receive a another depalletized stack of cartons. In one option the robot has a plurality of fork channels for receiving the blades of a load push lift truck along with receiving the blades or a rotating lift truck.

A controller obtains dumping area data indicative the shape of an edge of a dumping area. The controller obtains material data indicative the shape of material in the dumping area. The controller decides, based on the material data, a plurality of segments into which the material is divided. The controller decides dumping positions of the dumping work according to combinations of the plurality of segments and the plurality of dumping candidate positions.