A system for preparing recipes with components coming from closed containers (S1-S5) provides for using one or more robotic units (1), each of which withdraws a selected container, arranging a plurality of hoppers (7.1-7.5), in each of which the withdrawn selected container is inserted by the robotic unit (1), and in each of which the container is automatically opened for loading the component into the hopper (7), discharging a preset component dose from each hopper (7), and collecting the dosed components for preparing the required recipe; a driving and control unit (15) provides for driving and controlling all of these operations as a function of the required recipe. Thereby, an automatic system for preparing recipes is achieved, which is fast, with a low processing cost, and free from risks related to the processing.

A method for the partial emptying of buoyant objects, which are stored in a loading aid having at least one opening is provided. A processing weight to be partially emptied is established. A fill weight is determined of the objects in the loading aid via a first weighing. The loading aid is at least partially immersed in a liquid bath. The loading aid is positioned or moved for a retention time predefined as a function of the fill weight and of the processing weight in the bath such that there is an on-average constant flow relative to the loading aid and such that the opening is disposed at least partially below a fill level surface of the bath, whereby the objects are taken along by the flow. The at least partially emptied loading aid is lifted out of the bath after the retention time has elapsed.

Systems, methods, and apparatuses are disclosed for automated container shaking systems. In one embodiment, an example container shaking system may include a first support disposed at a first side of a first container slot, a second support disposed at a second side of the first container slot, and a first moveable platform disposed on the first support and the second support. The first moveable platform may be configured to slide on the first support and the second support, and the first moveable platform may be configured to receive a first container. The system may include a first actuator coupled to the first moveable platform, the first actuator configured to push and pull the first moveable platform, and an optional first sensor configured to detect an item deposited into the first container. Feedback from the first sensor may optionally be used to trigger the first actuator.

A method for unloading a container having packages with a rail device comprising a rail having a hand element displaceable in the longitudinal direction. The hand element has a plurality of finger elements having two flexible flank elements extending jointly from one end to the opposite end of the finger element. Each are connected flexibly to each other via a plurality of webs. The finger elements adjustable from a curved position into an extended position and back. The packages are stacked in the container forming a front face in which the rail device is brought close to the front face of the stacked packages. One hand element grips one package from the stack of packages and removes it from the stack. Following the removal, it is displaced along the rail and following the displacement grips one further package and removes it from the stack of packages.

An article transport facility includes a transport conveyor (34) and a weighing device (24), which includes a support portion (28) for supporting a container (C1) and a measuring portion (30) configured to measure a weight of the container (C1) supported by the support portion (28). The article transport facility is configured to perform a state change between a withdrawn state in which the support portion (28) is withdrawn downward relative to a transport surface (34A) and a protruding state in which the support portion (28) protrudes upward relative to the transport surface (34A) by moving the support portion (28) and the transport conveyor (34) relative to each other in a vertical direction (Z). A support surface (28A) of the support portion (28) is inclined such that one corner portion (8A) of multiple corner portions (8) located at corners of the container (C1) is lower than the other corner portions (8).

Driverless transport vehicles or DTVs, which are automatically guided vehicles, are gaining importance in the sorting of cargo. A method for loading a driverless transport vehicle with a cargo item in a transfer point, includes loading the DTV with the cargo item by using a known delivery system during the journey of the DTV. In order to prevent cargo items from falling during loading, a higher-level control sets the delivery speed of the cargo item and the speed of travel before the cargo item is transferred to the transport vehicle, such that the delivery speed component of the transport direction is equal to the speed of travel of the transport vehicle. In this way, the continued use of existing delivery systems such as are known under the term HSI (high speed induction) is possible. A system for loading a driverless transport vehicle is also provided.

A material transfer system for a machine having a conveyor adapted to transfer material into a material holding space of a receptacle. The material transfer system also includes an adjustable deflector positioned proximate to a discharge end of the conveyor. The material transfer system further includes a sensor positioned proximate to the discharge end of the conveyor. The sensor is configured to monitor the material holding space of the receptacle. The material transfer system includes a controller communicably coupled with the adjustable deflector and the sensor. The controller is configured to receive a first input signal from at least one of the sensor and a machine operator for adjusting a position of the adjustable deflector, determine an optimal position of the adjustable deflector based on receipt of the first input signal, and generate a first command signal for adjusting the position of the adjustable deflector to the optimal position.

A storage, retrieval and processing system for processing objects is disclosed. The storage, retrieval and processing system includes a plurality of storage bins providing storage of a plurality of objects, where the plurality of storage bins is in communication with a retrieval conveyance system, a programmable motion device in communication with the retrieval conveyance system for receiving the storage bins from the plurality of bins, where the programmable motion device includes an end effector for grasping and moving a selected object out of a selected storage bin, and a movable carriage for receiving the selected object from the end effector of the programmable motion device, and for carrying the selected object to one of a plurality of destination bins.

The invention relates to a device comprising a stationary transfer station (3) and a trailer train (1) comprising at least one trailer-train trailer (2), for transferring loads (L) from the trailer-train trailer (2) into the stationary transfer station (3), the trailer-train trailer (2) being provided with a continuous conveyor (25) driven by a motor (27), for receiving the load (L). The motor (27) of the continuous conveyor (25) of the trailer-train trailer (2) is powered by a battery (6) of the trailer train (1). Another continuous conveyor (30) driven by another motor (32) is arranged in the transfer station (3), for receiving the load (L), the other motor (32) of the other continuous conveyor (30) being powered in the transfer station (3) in a pre-determined handling position by the battery (6) of the trailer train (1).

A manufacturing device has a manufacturing cell for processing workpieces, with a laterally circumferential safety partition, in which a lock is formed for performing a loading operation of the workpieces, wherein a first light barrier arrangement is formed at the lock, and with a driverless conveyor with a load receiver for conveying the workpieces. For performing the loading operation, a second light barrier arrangement and a third light barrier arrangement are formed between the conveyor and the lock, so that the load receiver and the workpieces are laterally bounded on opposite sides by the second light barrier arrangement and by the third light barrier arrangement.