Methods and apparatuses for performing automated operations using a high-density robotic cell. An apparatus comprises a first plurality of robotic devices; a second plurality of robotic devices; and a control system. Each of the second plurality of robotic devices is coupled to a single function end effector. The control system controls the second plurality of robotic devices to concurrently perform tasks at a plurality of locations on an assembly, while the first plurality of robotic devices independently maintain a clamp-up at each of the plurality of locations.

A method of assembling a manufactured item without a guide rail and an assembly system are provided. The method includes disposing a base item on an unmanned independent vehicle system, moving the unmanned independent vehicle system to an assembly station, and attaching an additional item to the base item. The assembly system includes a number of unmanned independent vehicle systems, each unmanned independent vehicle system having at least one wheel. Each unmanned independent vehicle system is configured to be loaded with a base item. A number of assembly stations are provided, each being configured to complete at least one assembly operation. Each unmanned independent vehicle system is configured to independently move to multiple of the assembly stations to have a different assembly operation performed at each assembly station, resulting in additional items being attached to each base item to form each manufactured item.

A programmable device (D) arranged in a production environment, to assist an operator (O) in performing manual assembly operations carried out by the operator (O), particularly during assembly operations performed on pieces (P) transported by pallets (5) in a production line (1). The device (D) comprises an assembly means usable by the operator (O), a lighting device (4) for lighting a work area in which the operator (O) works, a sensor (6) configured to detect the position of the assembly means, an input device (10) usable by the operator, and an electronic control system (8) configured to memorize a learning sequence including a sequence of manual assembly operations.

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 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.

A production facility is provided with: an AGV for transporting a plurality of fuselage panels of multiple types having different shapes in a mixed state on a previously determined transport path; a plurality of A/Rs for riveting the fuselage panels; work areas set so as to correspond to the respective A/Rs in which the A/Rs move to rivet the fuselage panels; and a buffer area, set beforehand in the transport path adjacent to the work area, to which the A/R corresponding to the adjacent work area moves so as to rivet the fuselage panel. When there is no fuselage panel to be riveted in the work area adjacent to the buffer area and the fuselage panel to be riveted is present in the buffer area, a control device moves the A/R corresponding to the work area adjacent to the buffer area to the buffer area to rivet the fuselage panel.

A vehicle body assembling system forms a pre-buck section and a main buck section set along a transfer path of a floor assembly. A main buck unit is set at opposite sides of the transfer path in the main buck section, controls an upper portion of a side assembly in a state that a lower portion of each side assembly is pre-assembled to the floor assembly the pre-buck section, and assembles the upper portion of the side assembly and vehicle body parts using a second welding robot.

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.

The present subject matter illustrates a portable-arrangement for assembling a down-hole tool for usage in a well-bore. The arrangement comprises a plurality of intermodal-containers for multi-modal transportation of freight defined by a plurality of modules. The modules are adapted for perforating a received base-pipe, de-burring the perforated pipe, and facilitating assembly of a plurality of screen-units around the base-pipe to achieve a screen assembly for sand and flow control. A roller flow conveyor-module is configured for providing automated-conveyance in respect of the base pipe within and across the modules. Accordingly, the assembling cum manufacturing is achieved at a local location (i.e. onsite) in the country of oil and gas wells operations enabling delivery in shorter lead times, improved inventory management and high in country value.

The present disclosure relates to systems, apparatuses, and methods for assembling cartridges for aerosol delivery devices. The cartridges may be assembled by transporting carriages between various substations at which parts are added to a base. In another assembly method, the base may be moved between a plurality of robots which direct the base downwardly into contact with components to couple the components therewith. An inspection system may inspect the cartridges at various stages of completion.