A system includes an article supply location, wherein the article supply location includes a plurality of articles to be sorted, first and second transport vehicles, each having a first position in which an article is stowed about the vehicle and a second position in which the article is deposited into a proximal container. And a control system. The control system is configured to receive an order for a plurality of disparate articles, determine one destination container of a plurality of destination containers to direct the transport vehicle to deposit a selected article, direct the first transport vehicle to transport a selected article to the destination container and deposit the article by manipulation of the first transport vehicle from the first position to the second position for deposit of the selected article in the destination container.

The initial setting method for the unmanned forklift includes a step of acquiring a measurement value of floor surface inclination of a stop position where the unmanned forklift stops when the unmanned forklift unloads a palette on a rack, a step of setting the stop position where a predetermined inclination pattern is detected, as a precise adjustment position, from the acquired measurement value, a step of causing the unmanned forklift to unload the palette in accordance with an operation program, and measuring a deviation amount of the palette unloaded by the unmanned forklift, at the precise adjustment position, and a step of correcting a command value of the unmanned forklift at the stop position, based on the measured deviation amount.

A method for calibrating a sensor unit disposed on a load-bearing device of an industrial truck includes the steps of: determining a first position of the sensor unit relative to an object located remotely from the industrial truck, displacing the sensor relative to the object in a first direction by a first distance, determining a second position of the sensor unit relative to the object, determining the spatial position or arrangement of the sensor unit relative to the load-bearing device based on the first and second positions, the direction of movement, and the distance between the first and second positions.

A system includes an article supply location, wherein the article supply location includes a plurality of articles to be sorted, first and second transport vehicles, each having a first position in which an article is stowed about the vehicle and a second position in which the article is deposited into a proximal container. And a control system. The control system is configured to receive an order for a plurality of disparate articles, determine one destination container of a plurality of destination containers to direct the transport vehicle to deposit a selected article, direct the first transport vehicle to transport a selected article to the destination container and deposit the article by manipulation of the first transport vehicle from the first position to the second position for deposit of the selected article in the destination container.

A pallet comprises an upper load supporting surface having a peripheral edge, and a lower surface having a peripheral edge. The lower surface has substantially the same dimensions as the upper load supporting surface. A plurality of peripheral supports are provided at or near the peripheral edge of the lower surface and extend upwardly therefrom to the upper load supporting surface so that the upper load supporting surface and the lower surface are spaced from each other and define sides of the pallet. Each side of the pallet has a first opening and a second opening which are defined by the upper load supporting surface, the lower surface, and a pair of peripheral supports. Inclined surfaces are provided on the lower surface.

An automatic storage and retrieval system includes: a delivery vehicle; a storage container carried by the delivery vehicle; and an unloading station for unloading an item from the storage container while it is being carried by the delivery vehicle. The unloading station includes: an unloading device; and a destination conveyor configured to convey the item to a target destination, wherein the unloading device is configured to move the item through a side opening of the storage container to the destination conveyor.

Automated systems and methods for deployment of mounting tubs that support photovoltaic modules are provided in which a feeder assembly includes a screw thread assembly and a pivot arm. The screw thread assembly has at least one rotatable threaded component, and two such components in exemplary embodiments, positioned within the feeder assembly. The rotatable threaded component supports the stack of mounting tubs and rotates to separate the individual mounting tub from the stack of mounting tubs and lower the individual mounting tub onto the pivot arm. The pivot arm is configured to interact with an individual mounting tub and pivots to dispense the individual mounting tub onto a mounting surface. A sensor may be provided to detect the positions of the individual mounting tubs as they are moved, and a control system communicates with the sensor and the feeder assembly. The feeder assembly and a hopper holding the stack of mounting tubs may be mounted on an autonomous cart.

A storage, retrieval and processing system is disclosed for processing objects. The system includes a plurality of bins including objects to be distributed by the processing system, said plurality of bins being provided in at least a partially generally circular arrangement, a programmable motion device that includes an end effector for grasping and moving any of the objects, said programmable motion device being capable of reaching any of the objects within the plurality of bins, and a plurality of destination containers for receiving any of the objects from the plurality of bins, said plurality of destination containers being provided in a region that is generally within the at least partially generally circular arrangement of the plurality of bins.

A transport device includes rollable elements configured to both support and move the transport device on a surface; and a drive mechanism for driving the rollable elements. A load bearing mechanism is movable between a lowered position adjacent to the surface and at least one raised position, and is supported by a support frame having a front wall, two side walls and an open back. The load bearing mechanism is mounted such that the side walls and front wall of the support frame extend around the load bearing mechanism. An actuator is mounted on one of the walls of the support frame for controllably raising and lowering the load bearing mechanism and the rollable elements are mounted adjacent to the side walls of the support frame and support the two side walls at four locations, such that a center of gravity is between the four locations.

Traditionally, counterweight fork type autonomous mobile robots (AMR) have been used for any kind of pallet. But the challenge is it occupies lot more maneuvering space while making turns, which cannot work in narrow operating zones. Hence fork over AMR is preferred. However, these fork over AMR have extended parts always touching the ground surface and thus are not suitable for pallets with a wooden plank at the bottom of the fork opening in the pallet. To overcome the above technical problems, an Adjustable Counterweight-based Fork Type Autonomous Mobile Robot (ACFTAMR) is provided that includes chassis assembly and vertical mast unit, a horizontal cross slide mechanism and forks. The chassis assembly is provided counterweight assembly and counterbalance shafts that move forward and backward during pickup and release of payload when the vertical mast unit moves in upward/downward direction, thus providing better stability and counterbalance to the ACFTAMR.