A container stacking storage system loading trolley that includes a chassis and a height-adjustable container seat that includes a receiving region with a container contact surface, wherein a lifting device that operates in a lifting direction is arranged between the chassis and the container seat. The container stacking storage system operates in an economical manner, whereby a bearing arrangement is arranged between the container seat and the chassis, which bearing arrangement enables a movement of the container seat transversely to the lifting direction relative to the chassis.

A pallet exchanger and load splitter apparatus and method are provided. The apparatus has a pallet-receiving assembly with a pallet-receiving zone configured to receive, at least in part, a pallet supporting a pallet load; a clamp assembly connected to the pallet-receiving assembly having a clamping zone configured to secure a first side, a second side, and a rear of the pallet load once the clamp assembly is activated by a pneumatic circuit so that the pallet load is supported by the clamp assembly; and the pneumatic circuit is for controlling a clamping pressure of the clamp assembly.

A pick assist system may include a pallet destacker storing a front column of pallets and a back column of pallets. At least one rfid reader is configured to read an rfid tag on a pallet in or below at least one of the front column of pallets or the back column of pallets. The pick assist system may include a pallet sled including a display indicating a product to be retrieved. The pallet sled may determine that the product has been placed in a center of a pallet on the pallet sled. A method for verifying a pallet may include identifying skus on exterior products in a layer in a stack of products. Based upon that determination, the skus of the interior products may also be determined. For example, it may be determined that the interior products were part of a layer pick.

The present invention relates to an auxiliary battery and an auxiliary battery rental device, and the auxiliary battery rental device according to the present invention comprises: a battery port allowing an auxiliary battery to be discharged therefrom or returned thereto; a battery queue in which auxiliary batteries are vertically stacked and loaded; a carrier for discharging an auxiliary battery loaded in the battery queue to the battery port, or loading an auxiliary battery returned to the battery port in the battery queue; a lift for lifting at least some of the auxiliary batteries loaded in the battery queue; a charging unit for charging at least some of the auxiliary batteries loaded in the battery queue; and a control unit for controlling an operation of the rental device such that lending and returning operations of the auxiliary batteries are automatically performed. According to the present invention, lending, returning, charging, and lending of auxiliary batteries can be circularly and automatically performed.

A container supply device includes a guide plate that guides stacking of a plurality of lids in a vertical direction, a lower claw capable of advancing/retreating and mounting a first container located at the lowermost position in a plurality of stacked containers, an upper claw capable of advancing/retreating and including a recess into which a flange portion of a second container sequentially stacked on the first container in the plurality of stacked containers is inserted, and a suction pad that adsorbs and separates the first container from the second container in a state where the second container is supported by the upper claw.

Container depalletization systems and methods may include various example depalletizing stations including a frame and a plurality of fork assemblies. For example, the frame may receive a stack of containers, and the plurality of fork assemblies may engage, lift, lower, and release layers of containers from the stack of containers to downstream stations or processes. In addition, the example depalletizing stations may include transfer elevator assemblies that may receive layers of containers from the plurality of fork assemblies and transfer the layers of containers to downstream stations or processes. Further, the example depalletizing stations may include movable frames that may move between a first position, at which layers of containers may be engaged and lifted by the plurality of fork assemblies, and a second position, at which layers of containers may be lowered and released by the plurality of fork assemblies and transferred to downstream stations or processes.

A pallet blocking apparatus for use with a pallet dispenser, and related method and system are described. The pallet blocking apparatus comprises, a first wall, a second wall substantially parallel to the first wall and spaced apart for allowing movement of a pallet stack with a top pallet and a bottom pallet there inbetween, the pallet stack being dispensed from the pallet dispenser, a pallet storage area defined by the space between the first wall, the second wall, and a pallet blocker, and the pallet blocker spanning the first wall and the second wall, and substantially perpendicular to the first wall and the second wall, the blocker for blocking the top pallet in the pallet stack and urging the top pallet into the pallet storage area.

A stacking storage arrangement and method of operating stacking storage arrangement. The stacking storage arrangement includes multiple container receiving spaces and a loading space arranged below the container receiving spaces. A loading vehicle that is movable in the loading space includes a chassis and a container seat that is height-adjustable relative to the chassis. A holding device is arranged between each container receiving space and the loading space and a hold-open device is arranged on the chassis separately from the container seat.

The disclosure relates to a storage device system configured to carry cuttings from an offshore oil drilling rig to a vessel and then to shore for disposal. The system includes a set of nested boxes and lids designed to contain solids as well as some hydrocarbons. The ability to nest the boxes and lids leads to considerable reduction in space requirements relative to conventional systems. For example, according to an embodiment, each box is configured to only take up an additional 12″ in height for each nested box. As such, five nested boxes and lids only occupy a height equivalent to two stacked conventional boxes. Each box and lid is configured to serve as a closed container having hatches for filling the container with cuttings. The container is configured to withstanding pressures up to 5 psi while preventing fumes from escaping. Embodiments may have greater or fewer than five boxes.

A container supply device includes a guide plate that guides stacking of a plurality of lids in a vertical direction, a lower claw capable of advancing/retreating and mounting a first container located at the lowermost position in a plurality of stacked containers, an upper claw capable of advancing/retreating and including a recess into which a flange portion of a second container sequentially stacked on the first container in the plurality of stacked containers is inserted, and a suction pad that adsorbs and separates the first container from the second container in a state where the second container is supported by the upper claw.