A manufacturing system for assembling a vehicle includes a structure having a plurality of levels and including a plurality of manufacturing cells distributed among the plurality of levels. The manufacturing system includes a plurality of manufacturing capsules disposable at the plurality of manufacturing cells and configured to support a vehicular manufacturing process to assemble the vehicle, where the vehicular manufacturing process includes a plurality of manufacturing operations. The manufacturing system includes a transport system configured to move the plurality of manufacturing capsules to the plurality of manufacturing cells, where the transport system includes a vertical transport system configured to longitudinally move the plurality of manufacturing capsules between the plurality of levels. The manufacturing system includes a control system configured to control movement of the manufacturing capsules with the transport system.

A device is suitable for inserting sealing pads into one of the sectors of a turbine stator of a turbine, wherein the turbine stator includes a plurality of sectors with adjacent side faces abutting each other and slots arranged opposite each other in the adjacent side faces of two successive sectors. Each stator is configured to receive a predefined sealing pad. The device includes a support for supporting the sector; a robot arm configured to grip the sealing pads, each predefined in accordance with the slot intended to receive it. The robot arm is configured to insert each predefined sealing pad into the slot intended to receive it of one of the side faces of the sector.

A fastener feeding system and method for automatically delivering fasteners to a plurality of different manufacturing cells in a manufacturing line from a single load point. The fastener feeding system includes a fastener distribution assembly and a transport assembly for selecting and delivering fasteners to the manufacturing cells. Individual fasteners are selected from a fastener reservoir by a robotic manipulator of the fastener distribution assembly, and are placed on a fastener carrier supported on conveying structure extending between the fastener distribution assembly and the manufacturing cells for movement therealong. The fastener carrier is controlled to move along the track to deliver one or more fasteners to a manufacturing cell.

Systems, methods, and apparatus are provided for assembling a wing. Methods include coupling a robot arm to a bracket on a rib held against a wing panel, and operating the coupled robot arm to install shims between the rib and wing panel. Some methods further include mounting (e.g. detachably) the bracket, such as by aligning it with indexing features at the rib. In some methods, the bracket enforces a contour to the rib. Systems include a carriage coupled to a rib, and a robot arm extending therefrom that is operable to perform work (e.g. inspection, installing shims and/or fasteners, etc.) at an interface between the rib and a wing panel. Apparatus includes a robot arm dimensioned for placement at an interface between a rib and a wing panel, with the robot arm including an end effector to perform work upon the interface (e.g. inspection, installing shims and/or fasteners, etc.).

A radiating structure assembly system includes a movable conveyor that supports fixtures. Work stations are spaced about the conveyor such that the fixtures are moved sequentially to position the fixtures at the plurality of work stations. A first work station includes a loading assembly for loading the radiating elements on the fixtures. A second work station includes a first automated vertical assembly machine for mounting a first printed circuit board to the radiating element. A third work station includes a second automated vertical assembly machine for mounting a second printed circuit board to the radiating element to create a dipole assembly. A holding device is movable with the conveyor aligns and supports the first and second printed circuit boards relative to the radiating element. A fourth work station includes an unloading assembly for removing the dipole assembly from the conveyor.

A method and system for an automated modular construction factory is presented. A plurality of pre-cast construction panels, a quality control zone, a transportation system, a general stockyard, a sequencing system, an assembly zone, an assembly system, a transit system, a finishing zone, and a plurality of finishing stations are provided. The pre-cast construction panels undergo quality control under the quality control zone and are transported and ordered to the general stockyard through the transportation and sequencing systems. The panels are then assembled into a constructed room in the assembly zone through the assembly system. The constructed room is transported by the transit system to the finishing zone where the constructed room is furnished and completed by the plurality of finishing stations.

A fastening tool. In the fastening tool, a top part guiding matching portion engages a top part guiding portion in a sliding fit; a pressing part guiding matching portion engages a pressing part guiding portion in a sliding fit; a lever hinged to a base part; a transmission part engages a transmission part guiding slot in a sliding fit; the transmission part is driven to slide by the pressing part, and the lever is driven to rotate by the transmission part, then the top part is driven to slide out, due to a reaction force acting on the pressing part by the transmission part and the friction between the pressing part and the base part, the pressing part remains to be self-locked by friction, which can constrain the pressing part and the top part is locked.

Systems and methods are provided for assembling an airframe of an aircraft, including receiving a half barrel section of fuselage, advancing the half barrel section in a process direction across multiple stations to separately and simultaneously perform work on the half barrel sections, and subsequently joining the half barrel segments to form a section of the airframe. Each pair of half barrel sections, such as upper and lower half barrels, are progressed through assembly line processes to be delivered to a joining station for joining the half barrels together to form a circumferential section of the fuselage. Multiple joined circumferential sections are joined together to form an elongated extent of the fuselage. Indexing features are provided in the assembly process to monitor and control the progression of the half barrel sections in the work stations of the assembly line process.

A smart factory system for an electrified vehicle includes a components supplying section in which a drive-motor and a one-kit module of speed reducer component parts for forming a speed reducer to be assembled to the drive-motor are supplied to an upper portion of an autonomous mobile robot, a stator assembling section in which a stator to be assembled to the drive-motor is assembled, a speed reducer assembling section configured to sequentially assemble the speed reducer component parts to the drive-motor, a sub-assembling section in which the drive-motor, the stator, and the speed reducer component parts are electrically interconnected, and a test section in which an assembly quality of the drive-motor, the stator, and the speed reducer component parts is checked.

Techniques for flexible, on-site additive manufacturing of components or portions thereof for transport structures are disclosed. An automated assembly system for a transport structure may include a plurality of automated constructors to assemble the transport structure. In one aspect, the assembly system may span the full vertically integrated production process, from powder production to recycling. At least some of the automated constructors are able to move in an automated fashion between the station under the guidance of a control system. A first of the automated constructors may include a 3-D printer to print at least a portion of a component and to transfer the component to a second one of the automated constructors for installation during the assembly of the transport structure. The automated constructors may also be adapted to perform a variety of different tasks utilizing sensors for enabling machine-learning.