The environmental change proposing system includes: an acquiring unit configured to acquire processing information regarding processing of a conveyance task from a conveyance robot that has executed the conveyance task using an environmental map; an evaluation computing unit configured to perform an evaluation computation for evaluating, based on the processing information, a virtual layout in which the arrangement of installation objects on the environmental map has been changed; and an output unit configured to generate and output proposal information regarding a change in arrangement of the installation objects, based on an evaluation result of the evaluation computing unit.

A robotic system for dynamic controlling the movement of a mobile robot is presented. The robotic system includes a multi-level transport system arranged in an xyz-space. The multi-level transport system includes a plurality of magnetic tracks configured to allow movement of the mobile robot in at least one direction in the xy-plane. The multi-level transport system further includes a plurality of transfer mechanisms configured to change the direction of the mobile robot in the xy-plane, and to allow the movement of the mobile robot in a direction along the z-axis, each transfer mechanism defining a transfer node in the multi-level transport system. The robotic system further includes a control system configured to dynamically control the movement of the mobile robot in the x,y,z direction at one or more transfer nodes of the multi-level transport system, by dynamically activating a corresponding magnetic track or a corresponding transfer mechanism.

Shuttle robots (107) are used that are suitable for moving trolleys (106, 106′) under the control of a monitoring and control unit (190) for handling objects so as to move them from a collection point (110) to a palletizing station (151) remote from the collection point, the shuttle robots being autonomously movable and being suitable for hitching to and unhitching from the trolleys, the monitoring and control unit controls the shuttle robots so that they move the objects on trolleys from the collection point to a buffer storage zone (141) where the articles on the trolleys are grouped together into batches of articles for palletizing, and the monitoring and control unit controls the shuttle robots so that they take the objects on trolleys grouped together in batches from the buffer storage zone and move them in sequence to the palletizing station.

Provided are a robot-based random warehousing method and apparatus, an electronic device, and a storage medium. In the method, randomly allocated goods position information is acquired, and a shelving robot is controlled according to the goods position information to carry goods to goods position corresponding to the randomly allocated goods position information; a prompt is given to a picker to prompt the picker to take the goods from the shelving robot and place the goods at the goods position, and goods information and goods position information of the goods are synchronized to an unshelving order; and order information of the unshelving order is acquired and a picking robot in the vicinity of the goods position is controlled to move to the goods position to instruct a picker to pick the goods at the goods position and pass the goods to the picking robot.

The invention relates to a conveyor arrangement (1) for conveying a conveyed material, comprising a motor-driven conveyor roller (100), comprising a roller body (10) mounted so as to be able to rotate about a roller axis (A), a drive unit (20) arranged inside the roller body (10), coupled mechanically to the roller body (10) and an axle element (16) and designed to generate a torque between the axle element (16) and the roller body (10), a sensor function unit (40) arranged inside the roller body (10) and designed to sense a conveyed material to be conveyed by the motor-driven conveyor roller (100), and a control unit (30) that is connected to the sensor function unit (40) in order to transmit signals, wherein the control unit (30) is designed to receive a sensor signal from the sensor function unit and to transmit a control signal to the drive unit (20) depending on the sensor signal, wherein the control signal contains data for driving the motor-driven conveyor roller, in a conveyor mode, with a characteristic profile that is predefined by the control signal.

Methods and systems for training a robotic manipulator. The system may include one or more sensor devices and a robotic manipulator for executing an item grasping strategy to grasp an item. The system may further evaluate the item grasping strategy to determine whether the strategy was successful.

A transport system is provided. The transport system includes a stocker configured to store an assigned wafer carrier and having a gate port. The transport system also includes a semiconductor apparatus configured to transmit a request signal including a processed time according to a processing wafer carrier loaded on the semiconductor apparatus. The transport system further includes a vehicle configured to transport the assigned wafer carrier from the gate port to the semiconductor apparatus and a control system configured to control the vehicle. When the control system receives the request signal, the control system controls the stocker to transport the assigned wafer carrier inside of the stocker to the gate port at a start time, which is earlier than the processed time, and the control system controls the vehicle to transport the assigned wafer carrier from the gate port to the semiconductor apparatus.

A stacker crane includes a transporter, a slide fork, first to third sensors, a counter, and a main controller. The transporter moves from a shelf on which an article is supported to an empty shelf. The slide fork is mounted on the lift stage and transfers the article to and from the shelf. The first, second and third sensors recognize an abnormality of the article moved by the movement of the transporter. The counter counts the number of event occurrences. When an abnormality is recognized by the sensor, the main controller reduces a moving speed of the transporter, and when no abnormality is recognized by the sensor upon reduction in the moving speed, the movement of the transporter is continued. When the number of event occurrences reaches a first threshold, the stacker crane is brought into an abnormal-stop state.

A transport system is provided. The transport system includes a stocker configured to store an assigned wafer carrier and having a gate port. The transport system also includes a semiconductor apparatus configured to transmit a request signal including a processed time according to a processing wafer carrier loaded on the semiconductor apparatus. The transport system further includes a vehicle configured to transport the assigned wafer carrier from the gate port to the semiconductor apparatus and a control system configured to control the vehicle. When the control system receives the request signal, the control system controls the stocker to transport the assigned wafer carrier inside of the stocker to the gate port at a start time, which is earlier than the processed time, and the control system controls the vehicle to transport the assigned wafer carrier from the gate port to the semiconductor apparatus.

A processing system is disclosed for processing objects. The processing system includes a perception system for providing perception data regarding an object, and a primary transport system for providing transport of the object along a primary direction toward a processing location that is identified based on the perception data.