Disclosed is a container treatment device with a transport device for transporting containers along a predetermined transport path, wherein the transport device has at least one transport device for transporting the containers and at least one container treatment device for treating the containers in a predetermined manner, wherein this transport device includes a preferably rotatable carrier, on which a plurality of holding devices for holding at least one container are arranged, these holding devices being movable relative to the carrier in such a way that a distance between two containers immediately following one another on the transport path can be varied, wherein the container-handling device is arranged in such a way that it can handle the containers transported by the transport device.

Disclosed is a device for delivering sorted elements of the cap, stopper or other type, in order to feed a downstream work station, the device including a unit for lifting elements, in which a first sorting operation is performed, and, mounted downstream, a unit for treating the elements in which the elements are treated individually. Also disclosed is a delivery device including a conveyor mounted downstream from the treatment unit in order to direct the elements towards the work station, the conveyor moving the elements singly. Further disclosed is a corresponding method.

A handling system in a machine for processing containers, including a plurality of support plates circulating in a closed circuit, each support plate including one or more housings, each housing being able to hold a container, a first portion, in which the support plates circulate in a horizontal position along a first axial direction, a second portion, known as the return portion, with a second moving member configured to move the support plates in an opposite second axial direction X1B, the support plates circulating in the second portion in a vertical return orientation, the handling system including a holding pallet to selectively either unload the support plates from the second portion onto the holding pallet or for loading the support plates from the holding pallet into the second portion.

An automated storage and retrieval system comprising an automated storage and retrieval grid and a delivery system. The automated storage and retrieval grid includes a container handling vehicle rail system for guiding a plurality of container handling vehicles 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 container handling vehicle rail system includes a first set of parallel rails arranged in a horizontal plane and extending in a first direction, and a second set of parallel rails arranged in the horizontal plane and extending in a second direction which is orthogonal to the first direction, which first and second sets of rails form a grid pattern in the horizontal plane including a plurality of adjacent container handling vehicle grid cells. Each container handling vehicle grid cell includes 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. The delivery system includes a remotely operated delivery vehicle including a container carrier adapted to support the storage container. The delivery vehicle is further adapted to transport the storage container between the delivery port and a second location for handling of the storage container by at least one of a robotic operator and a human operator.

A load-handling device for lifting and moving containers stacked in stacks in a storage structure, the storage structure including, above the stacks of containers, a first set of tracks extending in a first direction and a second set of tracks extending in a second direction which is transverse to the first direction, the load-handling device being configured to move on the tracks above the stacks, the load-handling device including at least one wheel which is provided by a combined wheel and wheel-control unit having the at least one wheel and a controller configured to control rotation of the at least one wheel.

An automated vial feed system for an automated prescription filling system. The system has a plurality of sensors located above a vial distribution table for controlling the pace of vial delivery to the table. The sensors determine the load of vials on the table and a control system uses the information as feedback to the vial delivery system.

Disclosed is a sorting device for elements of the cap or stopper type, used to close a bottle or vial, or of the plastic preform type. The device includes a continuous conveyor arranged to travel in a conveying direction and equipped with successive transverse stop members between which the elements can rest in transverse alignment. The sorting device includes an ejector for ejecting the elements from the conveyor by moving the elements essentially along the length of the transverse stop members, the ejector include at least one push member which can move at least transversely to the conveying direction so as to push the elements towards the exit zone. Also disclosed is a corresponding method.

A two-dimensional rail system includes a first set of parallel rails arranged to guide movement of container handling vehicles in a first direction across the top of a frame structure, and a second set of parallel rails arranged perpendicular to the first set of rails to guide movement of the container handling vehicles in a second direction which is perpendicular to the first direction. The first and second sets of parallel rails form a grid which divides the rail system into a plurality of grid cells. A container handling vehicle for operation on the two-dimensional rail system includes a base, a support structure, a container, and a support surface. The base includes moving guides for the container handling vehicle along the rail system in the first direction and the second direction respectively. The support structure is provided on the base and extends from a lower section at the base to an upper section. The container lifting device includes a lifting frame for lifting a storage container up from a storage position below the rail system. The lifting frame is suspended from a set of suspension points of the upper section of the support structure. The support surface supports the storage container and provides a first holding position arranged at a lower elevation than the lifting frame when the lifting frame is in a docked state adjacent the upper section of the support structure. The container handling vehicle includes a movement mechanism to translate horizontally the set of suspension points or the support surface with respect to the base, such that a lifted storage container can be placed on the support surface and the lifting frame disconnected from the lifted storage container.

An automated storage and retrieval system includes a framework structure forming a three-dimensional storage grid structure for storing the storage containers in storage columns. The framework structure includes a grid-based rail system arranged above the storage columns with the rail system providing available routes for the container handling vehicles handling and transferring the storage containers to and from the storage columns. Each container handling vehicle includes a first set of wheels configured to move the vehicle along a first lateral direction of the grid-based rail system and a second set of wheels configured to move the vehicle along a second lateral direction of the grid-based rail system. The second direction is perpendicular to the first direction. The movements of the container handling vehicles are controlled by a control system that determines which tasks are to be done by specified container handling vehicles, destination locations for performing the tasks, and which routes the container handling vehicles are to travel on the rail system. A method for routing and rerouting of container handling vehicles handling storage containers in the automated storage and retrieval system comprises the control system performing: (a) running a multi-agent pathfinding algorithm, MAPF, in the control system for establishing and assigning routes on the rail system for the container handling vehicles from their current locations to assigned tasks at destination locations; (b) determining how far the container handling vehicles can travel on a first part of the assigned routes within a set time interval, the first part being shorter than the assigned routes to the destinations; (c) locking the first parts of the assigned routes that the container handling vehicles can travel within the set time interval, wherein the locked first parts of the routes cannot be changed and are excluded from consideration of available routes during running the MAPF algorithm; (d) extending the locked first parts of the assigned route for a container handling vehicle which is given priority; and (e) instructing the container handling vehicles to move from their current locations to an end location on the assigned locked routes; and (f) repeating steps (a) to (f).

An electro adhesion (EA) conveyor system for transporting a metallic container includes at least one electro adhesion (EA) pad. The EA pad includes at least one positive electrode and at least one negative electrode arranged in a predetermined pattern. The predetermined pattern is configured to generate an electric field when a voltage is applied to one or more of the at least one positive electrode or the at least one negative electrode. The EA conveyor system includes a conveyor belt operable to transport the metallic container between a first position and a second position. The metallic container is held against the conveyor belt via EA generated by the EA pad during transportation. The EA conveyor system may be adjusted by a control unit of a control system based on production line information such as operational data received from sensors.