A transport system for transporting a vehicle body at a manufacturing plant is provided. The transport system includes a guide rail attached to a floor of a trailer of a truck and includes a pair of elongated channels defining an elongated passage therebetween. The transport system further includes a carriage adapted to support the vehicle body and configured to facilitate a transfer of the vehicle body to the trailer. The carriage includes at least one guide pin configured to engage with the guide rail and adapted to be arranged inside the elongated passage. The at least one guide pin guides a movement of the carriage along the guide rail.

Provided is an automotive glass setting apparatus, including a setting base supporting a glass having a plurality of edges, a plurality of alignment units allowing the glass to be aligned with the setting base; a scanning unit scanning the edges of the glass, a plurality of moving mechanisms moving the plurality of alignment units, and a controller controlling the moving mechanisms based on data scanned by the scanning unit to align a center of the glass with a center of the setting base.

A conveying system for simultaneously transporting workpieces and workers having a plurality of vehicles, which each have a workpiece receptacle, an assembly platform for workers to move around on, and a separate drive, with which each vehicle can be driven independently of other vehicles of the conveying system. Furthermore, the conveying system includes a plurality of workstations, which are set up for carrying out different work steps. A control device is configured to control the vehicles such that they can pass individually through a different succession of workstations depending on the transported workpiece.

An assembly station for interconnecting a chassis and a body of a vehicle comprises a first carrier to support the chassis. A second carrier is suspended in a positive z-direction with respect to the first carrier and includes a plurality of spaced apart rests adapted to support the body prior to interconnecting the chassis and the body. A plurality of supports are coupled to the second carrier and spaced apart from the body when the body is supported on the rests. A portion of each of the supports is pivotable from a first position in a path of travel of the chassis to a second position outside of the path of travel of the chassis. The first carrier is moveable relative to the second carrier. The supports are adapted to engage the chassis and simultaneously support both the chassis and the body when the supports are in the first position.

A control system for controlling a plurality of manufacturing capsules in a manufacturing system for assembling a vehicle includes a processor and a nontransitory computer-readable medium comprising instructions that are executable by the processor. The instructions include generating vehicle assembly instructions based on the vehicular manufacturing process, one or more selected levels from among the plurality of levels, and one or more selected manufacturing cells disposed at the one or more selected levels, defining a nominal path based on the one or more selected manufacturing cells and the one or more selected levels, and controlling movement of the manufacturing capsules based on the nominal path.

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.

The present disclosure provides a workpiece conveyance system that can be configured at a low cost. A first exemplary aspect is a workpiece conveyance system configured to convey a first workpiece inside a facility and raise the first workpiece, the workpiece conveyance system including: an on-floor carriage configured to be movable on a floor of the facility, the on-floor carriage including a placement part on which the first workpiece is placed; and an elevating machine configured to push up the placement part, the elevating machine being configured separately from the on-floor carriage.

The present invention provides a vehicle component conveyance apparatus and a vehicle component conveyance method with which it is possible to easily convey an assembly component while maintaining a posture thereof. A conveyance apparatus 10 conveys an assembly component temporarily assembled by bonding, with an uncured adhesive, contact portions of base parts 101 and 102, side parts 103 and 104, a rear part 105, and an upper part 106. The conveyance apparatus 10 includes a temporary assembly jig 20 and a conveyance means 40. The temporary assembly jig 20 has a base 21, base-part support portions 23 and 25, side-part support portions 27, and a rear-part support portion 29. The side-part support portions 27 each have a pressing portion 31 that presses the pair of side parts 103 and 104 from outside toward inside in a vehicle width direction.

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.

Robotic systems are provided for flexibility in assembly operations. A robotic system includes a suction module having a front side with a face shaped to match a mating component and a rear side with a coupling for a suction line. Openings extend through the face. The suction module defines internal passages connecting the coupling with the at least one opening through the face. An end-effector has a base plate, a mounting plate selectively moveable relative to the base plate, and a clamp. The suction module is selectively mounted to the mounting plate and releasably secured by the clamp. An actuator is mounted to selectively move the mounting plate and the suction module relative to the base plate.