A fork-carriage apparatus for a lift truck includes: (a) a mounting frame assembly mountable to the lift truck for vertical movement; (b) a side shifter frame assembly slidably mounted to the mounting frame assembly; (c) a pivot frame assembly pivotably mounted to the side shifter frame assembly for translating therewith; (d) a fork assembly mounted to the pivot frame assembly for pivoting therewith; and (e) at least one load-pulling connector mounted to the pivot frame assembly and configured to connect a load to the fork-carriage apparatus for pulling the load.

A materials handling vehicle is provided including a vehicle power unit, a monomast coupled to the vehicle power unit, and a fork carriage apparatus supported on the monomast. The fork carriage apparatus includes a mast carriage assembly directly coupled to the monomast for vertical movement, a fork carriage mechanism to which forks are mounted, and a reach mechanism coupled to the mast carriage assembly and to the fork carriage mechanism for actuating the fork carriage mechanism to move between an extended position and a retracted position.

An automated storage and retrieval system includes a storage array of storage locations for case units. An in-out case conveyor is capable of bi-directionally transporting case units to and from the storage array, and an in-out loaded pallet conveyor is capable of bi-directionally transporting loaded pallets towards and away from the storage array. A palletizer-depalletizer cell includes a bi-directional pallet transport system with more than one independently driven pallet transports, each with a different pallet holder independently movable relative to a cell frame. Placement of case units commissioning a pallet layer loading a pallet, and removal of case units decommissioning a pallet layer unloading another pallet are both effected at the common pallet layer interface at a predetermined level of the cell frame. The pallet transports independently index a first and a second of the different pallet holders, each independently holding the pallet loading at the common pallet layer interface.

A manipulator for transporting a load laterally with respect to a vehicle includes a support frame adapted for mounting on a vehicle. A movable guide is supported by the support frame for lateral translation with respect to the support frame. A carriage which is capable of supporting a load engaging attachment for supporting a load is supported by the guide for translation with respect to the guide in the lengthwise direction of the guide. The carriage can translate with respect to the guide in the lengthwise direction of the guide at the same time that the guide is translating laterally with respect to the support frame.

A side shifter configured for use on a lift truck with an actuator of the side shifter embedded in and almost completely surrounded by the weight bearing components of the side shifter, particularly the fork base top bar and back carriage top bar. This arrangement provides additional protection to the actuator. Embedding the actuator in the weight bearing components of the side shifter also provides for a larger unobstructed view through the middle side shifter.

An industrial truck is proposed comprising: a lifting frame; an operator compartment which can be moved upwards and downwards; a lateral push frame, arranged on the operator compartment, in the front thereof, and which can be moved upwards and downwards together with the operator compartment and carries a load-receiving device, which can be moved back and forth; and a vibration-damping means, which can be moved upwards and downwards, for damping vibrations. The vibration-damping means being arranged between the operator compartment and the load-receiving device, is designed to make vibration compensation movements of the load-receiving device relative to the operator compartment possible. Preferably, an over-reach device is provided, combined with the vibration-damping means, for moving the lateral push frame to the straight forward travel direction of the industrial truck and relative to the operator compartment, so as to increase the lateral movement range of the load-receiving device relative to the operator compartment.

A clamp assembly for a lift truck load handler comprising a frame with one or more guide channels and one or more load handler appendages such as forks or clamp arms. The appendages are coupled to arms, each slidingly inserted in one of the guide channels. The guide channels each have a segmented channel bearing set inserted therein. Each segmented channel bearing set has an outer channel bearing set, an inner channel bearing set and a bearing spine. Each of the segmented channel bearing sets is inserted into the first guide channel with an outer channel bearing set closer to a load handler appendage than the inner channel bearing set.

A load-bearing support is provided for an industrial truck, which can be fastened to another device. At least one load-bearing means can be displaced horizontally in relation to the industrial truck and can be fastened in such a way that the load-bearing support can be tilted in vertical direction, wherein the area through which the driver of the industrial truck can see at a corresponding lifting height of a lifting carriage is maximized The load-bearing support has a rear and a front part, wherein the front part of the load-bearing support has at least one upper holder and a lower holder for the at least one load-bearing means and the two parts are connected to each other in such a way that the two parts can be rotated and laterally displaced.

An equipment (1) for a lift truck or similar self-propelled work machines, comprising: a fixed frame (2) which can be mounted solidly constrained to an arm of said lift truck, a movable frame (3), to which a tool (41, 42) is fixed, and actuating means (5) for displacing said movable frame (3) with respect to said fixed frame (2). The fixed frame (2) comprises a straight upper guide (22, 23) and a straight lower guide (24, 25) which lie on parallel or coincident planes. The movable frame (3) comprises upper connecting means (31, 32) and lower connecting means (33, 34) slidably coupled respectively to the upper guide (22, 23) and to the lower guide (24, 25) and coplanar thereto, so as to enable translation of the tool (41, 42) with respect to the fixed frame (2).

A clamping apparatus includes a frame adapted for mounting on a forklift so as to be raised and lowered along a mast of the forklift, a carriage supported by the frame for movement with respect to the frame in the widthwise direction of the forklift, two lifting arms supported by the carriage and extending in the widthwise direction of the frame, and a drive mechanism operatively connected to one of the lifting arms for producing relative movement of the lifting arms in the fore-and-aft direction of the frame to enable the lifting arms to grasp and release a load. The clamping apparatus can lift a portion of the objects in a closely-spaced layer and remove them from the layer without disturbing other objects in the layer. The clamping apparatus is particularly suitable for handling buckets.