A manufacturing apparatus that includes a conveyance device that moves a stage, where an electronic device shaped by multiple layers is placed, in X-axis and Y-axis directions. A first shaping unit, a second shaping unit, and a component mounting unit are arranged within a range in which the stage can move. The manufacturing apparatus performs additive manufacturing of the electronic device on the stage by performing a sequential movement of the stage to respective working positions of different units. As a result, in this manufacturing apparatus, a workpiece on the stage does not have to be removed and repositioned during each work process such as shaping by a first shaping unit, shaping by a second shaping unit, and electronic component mounting by a component mounting unit.

A method of processing O-rings in an automated mass production system includes: (a) advancing an O-ring retainer toward a loading position in alignment with an output end of a feed device; (b) discharging a leading O-ring from the output end in electronic synchronization with advancement of the O-ring retainer to the loading position to initiate loading of the O-ring into the retainer prior to the retainer arriving at the loading position; (c) after loading the O-ring into the retainer, advancing the retainer away from the loading position toward an unloading position; and (d) moving an end effector in electronic synchronization with advancement of the retainer to the unloading position to synchronize arrival of the retainer at the unloading position with arrival of the end effector at a pick-up position in alignment with the O-ring at the unloading position for pick up of the O-ring by the end effector.

A plant for managing products provides a plurality of work areas, each bounded by perimeter walls. Each work area has at least one robotic unit for moving and handling the products. The work areas are connected together by at least one overhead conveying unit for conveying products from one work area to another. The plant is efficient, reliable, versatile and safe.

Embodiments of the present disclosure relate to an apparatus for assembling a prism, and a production facility. The apparatus includes: a first station, configured for placement of the prism; a second station, configured for placement of a fitting body; a manipulator, configured to grasp the prism; a first drive unit, connected to the manipulator, and configured to drive the manipulator to be lifted or lowered; and a second drive unit, connected to the first drive unit, and configured to drive the first drive unit to reciprocate between the first station and the second station; a clamping device, disposed in the mounting slot of the fitting body, and configured to clamp the prism; and a controller, connected to the manipulator, the first drive unit, and the second drive unit.

Systems and methods for manufacturing aircraft are disclosed. For example, an aircraft manufacturing system for repetitively manufacturing aircraft comprises a first manufacturing zone configured to repetitively manufacture first aircraft subassemblies, a second manufacturing zone configured to repetitively manufacture second aircraft subassemblies, and a third manufacturing zone configured to receive the first aircraft subassemblies from the first manufacturing zone, to receive the second aircraft subassemblies from the second manufacturing zone, and to repetitively assemble the first aircraft subassemblies and the second aircraft subassemblies into the aircraft. In another example, a method for repetitively manufacturing aircraft assemblies comprises assembling first aircraft subassemblies and second aircraft subassemblies in parallel on separate assembly lines at a common geographic region; and transferring the first aircraft subassemblies and the second aircraft subassemblies to a final assembly facility located in the same common geographic region.

Disclosed are a matrix track system, a production line with associated loops and a production method using the production line. The matrix track system includes a plurality of track nodes which are arranged in a matrix and a plurality of fixed guide rails connecting the track nodes. The fixed guide rails include a plurality of longitudinal guide rails and a plurality of transverse guide rails. Each of the track nodes includes a turnout mechanism which includes a straight guide rail, an arc guide rail and a switch component for the switching of the straight guide rail and the arc guide rail.

An object is to reduce the risk of outflow of defects and improve the work efficiency of assembly work. An assembly system 10 according to an embodiment of the present invention is used to assemble a finished product while sequentially placing and fixing multiple types of components to a workpiece. The assembly system 10 includes a collaborative robot 20 configured to collaborate with a worker 100, an identification information reading unit 27 configured to read identification information indicated on a component placed on the workpiece, and a controller 70 configured to determine whether a type of the component placed on the workpiece is correct or incorrect based on the read identification information and control the collaborative robot in accordance with a result of the correctness determination.

A carrying mechanism for providing placement of at least one flexion item to a sponge pool having a lower sponge and a lateral sponge particularly used in mattress production includes at least one holder for fixing said flexion item thereon, at least one compression mechanism configured to at least partially compress the flexion item from the sides towards the center thereof, and at least one pushing group configured to separate the flexion item from the carrying mechanism in the sponge pool.

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.

Systems are provided for fabricating a preform for a fuselage section of an aircraft. The system includes advancing a series of arcuate mandrel sections in a process direction through an assembly line, laying up fiber reinforced material onto the arcuate mandrel sections via layup stations, uniting the series of arcuate mandrel sections into a combined mandrel; and splicing the fiber reinforced material laid-up onto the arcuate mandrel sections.