A dual-interface coupler includes a utilities unit, a number of utility cables configured to provide a number of utilities to the utilities unit, a first coupling unit associated with the utilities unit, and a second coupling unit associated with the utilities unit. The first coupling unit is configured to mechanically couple the utilities unit to a first corresponding coupling unit and comprises a utility interface. The number of utilities are configured to flow from the utilities unit through the utilities interface. The second coupling unit is configured to mechanically couple the second coupling unit to a second corresponding coupling unit.

A seat frame assembling unit includes: a setting device and a setting robot. The setting device is driven in a state where side frames, a connecting frame, a pan frame, a member frame and an upper frame are arranged. The setting robot installs the side frames side by side and subsequently installs the connecting frame, the pan frame, the member frame and the upper frame between the side frames. The setting device moves the side frames to positions in which the side frames are to be assembled with the connecting frame, the pan frame, the member frame and the upper frame.

A robot assembling system for assembling a multi-layer cage comprises a first assembling workstation, a second assembling workstation, a third assembling workstation, and a robot. The multi-layer cage includes a bottom case, a top case, a partition plate, and a partition assembly. The first assembling workstation assembles the partition plate and the partition assembly to form a partition device. The second assembling workstation assembles the partition device and the top case to form a top case assembly. The third assembling workstation assembles the top case assembly and the bottom case to form the multi-layer cage. The robot transmits the bottom case, the top case, the partition plate, the partition assembly, the partition device, or the top case assembly between the workstations. The robot assists an assembly process at each of the workstations.

Systems, methods and apparatus for automated vehicle wheel removal and replacement are provided. One system includes a computer system with applications for scheduling the replacement of tires for the vehicle. An electronically controlled lift device and robotic apparatus is configured for interaction with the computer system. The lift device mechanically adjusts arms for placement on lift points of vehicles. The robotic apparatus detects positioning of lug nut configuration for a wheel, removes lug nuts, and then removes the wheel from the wheel hub with gripping arms. The wheel and tire are then handed off to a separate tire changing machine. When a new tire is replaced the robotic apparatus then mounts the wheel to the original wheel hub, and then secures the lug nuts to the lug nut bolts.

The invention relates to a device for assembling a plurality of panels of an aircraft fuselage, said device comprising at least one anvil body, comprising a surface for supporting the said plurality of panels, the said anvil body comprising at least one anvil rail mounted movably in a cavity of the anvil body and configured to move between a top position in which the upper surface of the anvil rail extends into the extension of the support surface and a bottom position in which a workspace is created between the upper surface of the anvil rail and the support surface so as to allow a machining and/or stripping tool to pass through.

Robot system which includes a master device configured to receive an operating instruction from an operator, slave arm, storage device configured to store operating sequence information that defines processing carried out by slave arm, and control device configured to control operation of slave arm. Control device includes a receiver configured to receive an input signal, motion controller configured to determine whether operating mode of slave arm is to be automatic, manual or correctable automatic mode and control operation of slave arm in determined operating mode, and continuation determinator configured to determine whether continuation of automatic mode is permitted. In a process at which slave arm is scheduled to operate in automatic mode, after motion controller suspends operation of slave arm in automatic mode at a given step of process, continuation determinator determines whether continuation of automatic mode is permitted based on input signal received by receiver when operation is suspended.

A robot main body having a robotic arm, a remote control device which includes a robotic arm operational instruction input part installed outside of a working area and by which an operational instruction for the robotic arm is inputted, and a contactless action detecting part configured to detect a contactless action including at least one given operating condition parameter change instructing action by an operator, a control device communicably connected to the remote control device and configured to control operation of the robot main body.

An assembly system that assembles insulation plates and mounting bars to a stack may include a stack transferring device that discharges a stack pressed by a stack pressing device to the outside; an insulation plate attaching device that attaches insulation plates to a first opposite side and a second opposite side of the stack that is discharged to the outside by the stack transferring device; a mounting bar attaching device that attaches mounting bars to the stack to which the insulation plates are attached; and a bolt assembling device that assembles bolts to the mounting bars that are attached to the stack.

An assembly system that assembles insulation plates and mounting bars to a stack may include a stack transferring device that discharges a stack pressed by a stack pressing device to the outside; an insulation plate attaching device that attaches insulation plates to a first opposite side and a second opposite side of the stack that is discharged to the outside by the stack transferring device; a mounting bar attaching device that attaches mounting bars to the stack to which the insulation plates are attached; and a bolt assembling device that assembles bolts to the mounting bars that are attached to the stack.

Systems, methods and apparatus for automated vehicle wheel removal and replacement are provided. One system includes a computer system with applications for scheduling the replacement of tires for the vehicle. An electronically controlled lift device and robotic apparatus is configured for interaction with the computer system. The lift device mechanically adjusts arms for placement on lift points of vehicles. The robotic apparatus detects positioning of lug nut configuration for a wheel, removes lug nuts, and then removes the wheel from the wheel hub with gripping arms. The wheel and tire are then handed off to a separate tire changing machine. When a new tire is replaced the robotic apparatus then mounts the wheel to the original wheel hub, and then secures the lug nuts to the lug nut bolts.