Machine (10) and method for the automatic treatment of components of inhalers, in particular cartomizers for electronic cigarettes, wherein each component has a central body, preferably of tubular shape, having a lower end part normally protected by a removable lower cap and an upper end part normally protected by a removable upper cap. Upstream and downstream from one or more work stations (S3) and/or one or more inspection stations (S4) there are, respectively, a removal station (S2), configured to selectively and automatically remove the caps from the respective central bodies, and a repositioning station (S5), configured to selectively and automatically return the caps to the corresponding central bodies of the components.

An assembly system is provided for automotive lamps and an operation method thereof. In the invention, three kinds of function robots are responsible for the transmission work of the workpieces among various functional stations, which realizes automatic coating, fastening, and whole lamp performance testing, etc., and reduces the amount of manual intervention and improves the process integration. By setting a reasonable turnover area, the waiting time caused by the difference of transmission rate among processes is shortened. Meanwhile, the invention provides an assembly system with a bilateral assembly line operating simultaneously, which greatly improves the efficiency of the assembly system.

An assembly system is provided for automotive lamps and an operation method thereof. The assembly system includes two kinds of functional robots and many functional stations, and it uses the functional robots to transfer workpieces between the various functional stations to realize automatic gluing, fastening and whole lamp performance testing, etc., thereby reducing the amount of manual intervention and improving process integration. Further, the assembly system may provide an assembly system with a two-sided assembly line operating simultaneously, which greatly improves the working efficiency of thereof.

A method for performing operations on a target workpiece including taking an operating tool unit by an industrial robot, carrying the tool unit to the workpiece, releasing the tool unit at the workpiece, moving the robot away from the tool unit, performing one or more operations on the workpiece through the tool unit while the tool unit moves with the workpiece; and retrieving the tool unit from the workpiece after the tool unit has performed the one or more operations on the workpiece. A robotic assembly for performing a method including at least one industrial robot, at least one operating tool unit, and a quick tool changer for detachably coupling the tool unit with the industrial robot including a first tool changer part arranged in the industrial robot and a second tool changer part arranged in the operating tool unit.

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.

A fixture for automatically replacing a defective/burnback contact tip coupled to a torch arm of a robotic welder wherein the robotic welder is configured to feed a welding wire to the contact tip. The robotic welder includes a nozzle coupled to the torch arm which is disposed at the contact tip. The fixture includes a first station configured to remove the nozzle from the torch arm and to hold the nozzle for reattachment to the torch arm. A second station is configured to remove the contact tip from the torch arm. A third station includes a plurality of holding units each being configured to hold an unused contact tip, wherein the third station is configured to move one of the plurality of holding units to a predetermined location to locate the unused contact tip for attachment to the torch arm.

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.

A system and method for forming a foundation truss for a box spring or mattress foundation frame includes a first truss rail assembly station having a series of block feeders, a top rail hopper and a filler strip hopper that received stacks of truss components such as blocks, top rails and filler strips and feed such truss components into stacked registration. The stacked truss components are moved into engagement with a series of staplers that secure the filler strips, top rails and blocks together to form first truss rail portions, which are then fed to a second truss rail assembly station where a bottom rail is automatically applied thereto.

Material logistics system for coordinating transfer of production material so that production material is available as needed at production stations of a manufacturing facility, in particular a series production facility. Thus, multiple sensors are provided for sensing a production material supply at production stations, as well as a central unit in signal-transmitting connection with the sensors and which, based on output signals transmitted from the sensors, determines logistics data relating to the production material for a particular production station. And also, using logistics data, generates control signals for the transfer of production material and provides them for further data processing units. Furthermore, the central unit uses logistics data to control a driverless transport vehicle, having a transport rack including a transport level, for transporting production material accommodated in containers, for a partially automatic container transfer between a transport rack and a storage rack of a production station.

The invention relates to a device for measuring and adjusting the parameters of the chassis geometry at a rear axle of a motor vehicle on a production line for the motor vehicle. Gripping and holding means for the rear axle and loading means for the rear axle are associated with the production line. According to the invention, a plurality of interchangeable frames is associated with the production line, and positioning means for positioning one of the interchangeable frames into a position for gripping the rear axle in the production process are associated with the production line. The gripping and holding means for the rear axle and the loading means for the rear axle are associated with the interchangeable frame in question. The interchangeable frames can thereby be matched to rear axles of different vehicle types, such that these different rear axles can be processed in one assembly line.