A binding system including: a binding device including a binding machine that binds reinforcing bars with a wire, and a transfer robot that moves the binding machine to a binding position; a remaining wire amount detection unit configured to detect a remaining amount of the wire to be used in the binding machine; and processing circuitry configured to control a binding operation of the binding device based on the remaining amount of the wire detected by the remaining wire amount detection unit.

A binding system including: a binding device including a binding machine that binds reinforcing bars with a wire, and a transfer robot that moves the binding machine to a binding position by a relative movement between the binding machine and the reinforcing bars; an information acquisition unit configured to acquire binding related information related to an operation of binding the reinforcing bars with the wire; and a position information acquisition unit configured to acquire position information of the binding position in a manner associable with the binding related information for the binding position acquired by the information acquisition unit.

An exoskeleton system includes a first exoskeleton unit configured to support a first body part, a second exoskeleton unit configured to support a second body part, and a control device. The first exoskeleton unit and the second exoskeleton unit are mechanically decoupled from each other. The control device is configured to control, based on a control model, at least one of the first exoskeleton unit and the second exoskeleton unit. The control model is based on a multibody system that models the first exoskeleton unit, the second exoskeleton unit, and at least one of the first body part and the second body part.

An EUV stocker and an EUV pod device is disclosed. The EUV stocker includes an AI driven dynamic control circuitry, an AI controlled safety interlock, and an independent air return control device. The EUV stocker includes a Mass Flow Control (MFC) that operates in conjunction with one or more valves. The EUV stocker further includes a hydrocarbon detecting assembly, oxygen detecting assembly, pressure detecting assembly, and temperature detecting assembly and more to maintain the required condition within the EUV stocker. The EUV stocker also includes automated transportation devices such as AMHS, OHT, MR, AGV, RGV, or the like to provide a safe EUV mask storage environment for operators.

An apparatus for transporting a load is described, including: a body including a part or portion for engaging with or connecting to a load to be transported; a ground-engaging device supporting the body, the ground-engaging device for effecting movement of the body over a surface; a transmitter module; a receiver module; and a controller for communicating with the transmitter and receiver modules and the ground engaging device and for receiving status signals from components and/or devices of the apparatus, wherein the controller is capable of conducting a check as to the status of the components and/or devices of the apparatus, and after completing said check to provide an “apparatus operative” or “apparatus non-operative” signal to the transmitter module, wherein the transmitter module is configured to transmit the “apparatus operative” or “apparatus non-operative” signal, and wherein the receiver module is configured to receive from a first predetermined, or designated, other such apparatus its respective “apparatus operative” or “apparatus non-operative” signals.

A method for providing transport data for controlling goods transport in a production environment includes determining occupancy data based on sensor data of a sensor unit on a production unit in the production environment. The occupancy data relate to an occupancy state of a goods inlet of a production unit with stored components. Component data that indicate which components are required at the production unit for a production order assigned to the production unit are determined, as well as procurement data for the required components that indicate an expected transit time for transporting a component from a relevant storage location to the production unit. Further, transport data that describe a transport process to be performed and that depend on the occupancy data, the component data and the procurement data are determined.

The present application provides a method, apparatus and system for controlling transportation between warehouses. The method includes: receiving, from the source RCS, first transportation information which includes information of a first to-be-transported object; transporting the first to-be-transported object to a handover area; transferring control over the AGV from the source RCS to the target RCS; receiving a location of a first target storage space from the target RCS; transporting the first to-be-transported object from the handover area to the first target storage space. In the present application, the AGV transfers the control over itself from the source RCS to the target RCS after moving the to-be-transported object to the handover area, such that the target RCS could take over the AGV and control the AGV to transport the first to-be-transported object from the handover area to the first target storage space. In this way, a fully automatic transportation is achieved, improving the efficiency of transporting and warehousing compared to manual transporting.

A method for providing transport data for controlling goods transport in a production environment includes determining occupancy data based on sensor data of a sensor unit on a production unit in the production environment. The occupancy data relate to an occupancy state of a goods inlet of a production unit with stored components. Component data that indicate which components are required at the production unit for a production order assigned to the production unit are determined, as well as procurement data for the required components that indicate an expected transit time for transporting a component from a relevant storage location to the production unit. Further, transport data that describe a transport process to be performed and that depend on the occupancy data, the component data and the procurement data are determined.

An apparatus for transporting a load is described, including: a body including a part or portion for engaging with or connecting to a load to be transported; a ground-engaging device supporting the body, the ground-engaging device for effecting movement of the body over a surface; a transmitter module; a receiver module; and a controller for communicating with the transmitter and receiver modules and the ground engaging device and for receiving status signals from components and/or devices of the apparatus, wherein the controller is capable of conducting a check as to the status of the components and/or devices of the apparatus, and after completing said check to provide an “apparatus operative” or “apparatus non-operative” signal to the transmitter module, wherein the transmitter module is configured to transmit the “apparatus operative” or “apparatus non-operative” signal to a receiver module of one or more other apparatus and to its own receiver module.

A method for adjusting a system autonomy level of a cargo handling system configured for autonomous control by a processor is disclosed. In various embodiments, the method includes receiving by the processor a sensor database from a plurality of sensing agents in operable communication with the processor; determining by the processor a confidence level based on the sensor database; and adjusting by the processor the system autonomy level for continued operation of the cargo handling system.