An unloading arrangement, an unloading station, and a method of unloading an item (5) from a storage container (6), comprising: a delivery vehicle (30); a storage container (6) carried by the delivery vehicle (30); and an unloading station (10) for unloading an item (5) from the storage container (6) while it is being carried by the delivery vehicle (30) in an automatic storage and retrieval system (1), the unloading station (10) comprising: an unloading device (40); and a destination conveyor (60) configured to convey the item (5) to a target destination (TD), wherein the unloading device (40) is configured to move the item (5) through a side opening of the storage container (6) to the destination conveyor (60).

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.

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 automated storage and retrieval system includes an automated storage and retrieval grid, a container accessing station, a delivery rail system, and a delivery vehicle operating on the delivery rail system. The automated storage and retrieval grid includes a container handling vehicle rail system for guiding a plurality of container handling vehicles, the container handling vehicle rail system comprising a first set of parallel rails arranged in a horizontal plane (P) and. extending in a first direction (X), and a second set of parallel rails arranged in the horizontal plane (P) and extending in a second direction (Y) which is orthogonal to the first direction (X), which first and second sets of rails form a grid pattern in the horizontal plane (P) comprising a plurality of adjacent container handling vehicle grid cells, each container handling vehicle grid cell comprising a container handling vehicle grid opening defined by a pair of neighboring rails of the first set of rails and a pair of neighboring rails of the second set of rails; and a delivery column adapted for transport of a storage container arranged in a stack of storage containers beneath the container handling vehicle rail system between a container handling vehicle and a delivery port situated at a lower end of the delivery column. The delivery rail system includes at least a first set of parallel rails arranged in a horizontal plane (P1) and extending in a first direction (X), and at least a second set of parallel rails arranged in the horizontal plane (P1) and extending in a second direction (Y) which is orthogonal to the first direction (X), the first and second sets of rails together defining a delivery grid of delivery grid cells. The delivery vehicle includes a motorized vehicle body and a container carrier provided above the motorized vehicle body for carrying the storage container. The delivery vehicle is arranged to transport the storage container from the delivery port of the storage grid across the delivery grid to the delivery grid cell situated below the container accessing station. The container accessing station includes an access opening through which a human and/or robot may access contents of the storage container; a base opening; and a lifting device arranged to retrieve the storage container from a first level beneath the base opening and lift it up through the base opening to a second level so that the storage container may be accessed through the access opening. The delivery vehicle is arranged to deliver the storage container to the lifting device of the container accessing station, or receive a storage container from the lifting device and return the storage contain

A system for transporting a proppant for fracking may include a transport vehicle, a proppant container, a container clutch part, and a floating clutch part. The transport vehicle may include a carriage having forks for engaging fork pockets of the proppant container. The proppant container may house proppant releasable using a release gate and actuator. The container clutch part may be connected to the proppant container and configured to transfer rotational movement to the actuator. The floating clutch part may be connected to the carriage of the transport vehicle and configured to engage and selectively rotate the container clutch part when the forks engage the fork pockets. The forks and fork pockets vary in size which leads to a potential for misalignment between the container and floating clutch parts. The floating clutch part is vertically and laterally positionable to compensate for misalignments between the container and floating clutch parts.

A doffing apparatus can be configured to couple to an automatically guided vehicle (AGV). The doffing apparatus can comprise at least one elongate arm, each elongate arm having a proximal end, a distal end, and a length, and at least one driver, each driver being configured to move along a respective elongate arm to move a bobbin toward the distal end of the elongate arm. The doffing apparatus can further comprise at least one alignment device. The doffing apparatus can further comprise a processor, wherein the processor is configured to: receive feedback from the at least one alignment device, provide a control signal to cause the AGV to align the elongate arm with a receptacle at a loader, and move the driver a select distance along the length of the elongate arm.

The operation of container handling vehicles and remotely operated specialized container handling vehicles are controlled by a method such that total elapsed time or waiting time cost for transferring specified storage containers between them is minimal or optimal. The specialized container handling vehicles are operating at a level below an automated storage and retrieval system having a framework structure defining a storage grid for storing storage containers in grid cells. The storage containers are stored and retrieved by container handling vehicles running on top of the storage grid. At least one operational controller, which is in communication with a first type of controller in each container handling vehicle and a second type of controller in each specialized container handling vehicle, performs the followings steps: when a specified storage container is to be transferred from a storage column and its corresponding grid cell to a specialized container handling vehicle: assigning and instructing a container handling vehicle to pick up the storage container from the grid cell and lower it to a selected port, located at the lower end of an identified free delivery column by transmitting instructions to the first type of controller of the assigned container handling vehicle, where the port selected is included as a variable in a weighting function together with time and waiting cost to derive a trade-off of the container handling vehicle and the specialized container handling vehicle having the best matching travel time to the port; moving the container handling vehicle to the grid cell, picking up the storage container and transporting it to a grid cell of the delivery column where the port is; transmitting a signal to the specialized container handling vehicles comprising information of the selected port at a first location and when the storage container will be available at the port; based on responses from the specialized container handling vehicles, assigning and instructing a specialized container handling vehicle to retrieve the specified storage container at the selected port; moving the assigned specialized container handling vehicle to the selected port at the first location, picking up the storage container and bringing it to a second location; and/or, when a specified storage container is to be transferred to a grid cell, for storage in its corresponding storage column, by a specialized container handling vehicle: determining which port at a first location that is to be used, where the port selected is included as a variable in a weighting function together with time and waiting cost to derive a trade-off of the container handling vehicle

A remotely operated delivery vehicle for transport of a storage container between an automated storage and retrieval grid configured to store a plurality of stacks of storage containers, and a second location for handling of the storage container by at least one of a robotic operator and a human operator, the remotely operated delivery vehicle comprising: rolling devices configured to move the remotely operated delivery vehicle in a horizontal plane along tracks of a delivery rail system comprising a first set of parallel rails arranged in a first direction and a second set of parallel rails arranged in a second direction orthogonal to the first direction, rolling device motors for driving the rolling devices, and a power source configured to provide propulsion power to the rolling device motors. The remotely operated delivery vehicle further comprises a container carrier configured to receive the storage container from above and onto or at least partly into the container carrier so that contents of the storage container are accessible by the at least one of the robotic operator and the human operator.

A remotely operated delivery vehicle for transport of a storage container between an automated storage and retrieval grid configured to store a plurality of stacks of storage containers, and a second location for handling of the storage container by at least one of a robotic operator and a human operator, the remotely operated delivery vehicle comprising: rolling devices configured to move the remotely operated delivery vehicle in a horizontal plane along tracks of a delivery rail system comprising a first set of parallel rails arranged in a first direction and a second set of parallel rails arranged in a second direction orthogonal to the first direction, rolling device motors for driving the rolling devices, and a power source configured to provide propulsion power to the rolling device motors. The remotely operated delivery vehicle further comprises a container carrier configured to receive the storage container from above and onto or at least partly into the container carrier so that contents of the storage container are accessible by the at least one of the robotic operator and the human operator.

Provided herein is a mobile robot including: a first carrying device configured to carry a first item; a second carrying device configured to carry a second item; a control device connected to the first driving device and the second driving device and configured to control operation of the first driving device and the second driving device; the first driving device configured to drive, under control of the control device, the mobile robot to travel along a delivery path matching routings of the first item and the second item; and the second driving device, connected to the first carrying device and the second carrying device and configured to drive, under the control of the control device, the first carrying device to deliver the first item and the second carrying device to deliver the second item.