A side lift spreader (20) for lifting an upper intermodal transport container (10) and a lower intermodal transport container (10) stacked on each other comprises a container locking arrangement (30) arranged at a first longitudinal end of the spreader, the container locking arrangement (30) comprising an upper male lock insert configured to be connected to a bottom corner casting of the upper container (10) and a lower male lock insert configured to be connected to a top corner casting of the lower container (10), wherein said container locking arrangement (30) comprises an indicator configured to provide an indication if an attempt is made to connect the lower male lock insert to the bottom corner casting of the upper container (10).

A raising/lowering conveyance device for a container for conveying an article has container supports that can move toward or away from a container in the horizontal direction and up and down with respect to the container. The container supports have a plurality of container support pins that can advance/retreat in the horizontal direction from the container and that are forcibly held at a position protruding from a front surface of the container support. The container supports are configured to lift the container by the container support pins which protrude under a downward step surface formed on the outside of the container. A pin main body of the container support pins protrudes from the front surface and has a flat tip perpendicular to the center axis of the pin main body, and has a tapered shape that increases in diameter toward the flat tip and is thicker toward the end.

Containers can be stored, retrieved, or moved in multilevel storage racks of a transfer facility by storage and retrieval units that can travel in aisles extending parallel to respective rows of compartments of storage units of the multilevel storage rack that, for longitudinal side storage of the containers, has a plurality of storage units of a depth corresponding to a container width that are consecutively arranged in rows longitudinally of the containers along one aisle side and are each separated transversely by one aisle. The storage and retrieval units can move back forth in the aisles and have raisable and lowerable telescopic grabs that can be extended and retracted transversely to the aisles for suspending a container. Corners supports in each of the compartments support the containers only at corners of the containers.

An automated temperature-controlled outdoor terminal for storage and handover of online grocery orders allowing simultaneous operation of two transactions and a method to operate the terminal is described here.

A container-handling vehicle picks up storage containers from a three-dimensional grid of an underlying storage system. The container-handling vehicle has a vehicle body and wheels for moving the vehicle in two perpendicular directions on the grid. The vehicle body surrounds a cavity within which at least a first lifting device and a second lifting device are positioned adjacent to each other. Each lifting device is independently controlled and arranged to lift a storage container from the grid and into the cavity. The vehicle includes at least one vertical frame guiding element arranged inside the cavity. The frame guiding element extends between the lifting devices.

A container-handling vehicle for picking up storage containers from a three-dimensional grid of an underlying storage system includes a first set of wheels arranged at opposite sides of a vehicle body, for moving the vehicle along a first direction on the grid; a second set of wheels arranged at opposite sides of the vehicle body, for moving the vehicle along a second direction on the grid, the second direction being perpendicular to the first direction; and the first set of wheels displaceable in a vertical direction between a first position, wherein the first set of wheels allow movement of the vehicle along the first direction, and a second position, wherein the second set of wheels allow movement of the vehicle along the second direction. The vehicle body surrounds a cavity within which at least a first lifting device and a second lifting device are positioned adjacent to each other, each lifting device is arranged to lift a storage container from the grid and into the cavity, such that a bottom of the storage container is at a level above the lowest level of the second set of wheels.

Embodiments of this document provides improved safety logic for a mobile container handler of the reach stacker or top pick type. The improved logic involves limitations surrounding the hoist function of the machine subsequent to attaching to a shipping container. This improvement addresses damage to the container spreader caused by abrupt joystick hoist inputs by the operator immediately subsequent to attaching onto a shipping container. Due to space between the spreader arms and spreader body, which is so designed to facilitate movement of the arms inside the spreader body, sudden vertical movement of the spreader results in impact forces being exerted on various parts of the spreader body and spreader arms. These impacts accelerate fatigue leading to premature catastrophic failure of the spreader body and/or spreader arms' structural steel.

The present invention teaches a method used in connection with a forklift truck for quickly and easily nesting and un-nesting bulk seed boxes. A lower surface of the first lower box unit is engaged with forks extending from a forklift truck. The stacked first and second box units are then elevated to a target height. Next, the forklift truck is advanced forward until the stacked first and second box units are in a predetermined horizontal position in a box inverter apparatus, wherein the stacked first and second box units are positioned between opposing box engaging surfaces of first and second rotary clamp pads associated with the box inverter apparatus. The rotary clamp pads are then moved toward the stacked first and second box units until the opposing box engaging surfaces engage opposing outer surfaces of the second, upper box unit at a clamping location below the center of mass of the second, upper box unit. The forks of the fork truck carrying the first, lower box unit are then lowered until the first lower box unit is separated from the second, upper box unit, thereby affecting rotation of the first, upper box unit and rotary clamp pads about first and second spindle and bearing assemblies associated with and extending radially outwardly from opposing rear surfaces of the first and second rotary clamp pads until the second, upper box unit rotates a full 180 degrees to an inverted position. The forks carrying the lower box unit are raised upwardly such that the lower box unit nests inside the now inverted upper box unit. The rotary clamp pads are released from engagement with the outer surfaces of the upper box unit. Lastly, the nested first and second box units are removed from the box inverter apparatus.

A system includes a platform having an upper surface and defining a recess having a floor, the recess configured to seat a dish, and a movable securing frame that is movably connected with the platform, the frame including a lift support having an upper surface that is movable along a path from a first location that is beneath the floor of the recess, through the recess, to a second location that is coplanar with the upper surface of the platform. A motor configured to cause oscillation of the platform and the movable securing frame can be used. A method of using the system can include placing a dish above a recess defined by an upper surface of a platform, and lowering the frame with respect to the platform, thereby seating the dish within the recess.

The present invention teaches an apparatus and method used in connection with a forklift truck for quickly and easily nesting and un-nesting bulk seed boxes. A box inverter apparatus includes first and second rotary clamp pads, each clamp pad having a box engaging surface and an opposing rear surface. The first and second rotary clamp pads are positioned such that the box engaging surfaces thereof face one another in a spaced apart relationship. First and second spindle and bearing assemblies are associated with and extend radially outwardly from the opposing rear surfaces of the first and second rotary clamp pads, respectively. Each of the spindle and bearing assemblies has a first end attached to the rear surface of the rotary clamp pad and a second end attached to a frame such that each spindle and bearing assembly permits rotation of the rotary clamp pad relative to the frame. Means for adjusting the distance between the spaced apart facing box engaging surfaces of the first and second rotary clamp pad assemblies are provided. Positioning means for determining and selecting an optimal positioning of the pair of bulk seed boxes in between the opposing box engaging surfaces of the first and second rotary clamp pads are provided. Means for actuating the adjusting means to affect engagement of the box engaging surfaces with opposing sides of one of the pair of bulk seed boxes are also provided.