An additive manufacturing system includes an energy source and a material delivery device. The energy source is configured to direct an energy beam toward a component to form a melt pool. The material delivery device is configured to feed a wire toward the melt pool to deposit material on the component. In some examples, the material delivery device is configured to discharge a current to the wire to disengage the wire from the melt pool. In some examples, the material delivery device is configured to measure an arc voltage between the wire and the component.

An additive manufacturing system includes an energy source and a material delivery device. The energy source is configured to direct an energy beam toward a component to form a melt pool. The material delivery device is configured to feed a wire toward the melt pool to deposit material on the component. In some examples, the material delivery device is configured to discharge a current to the wire to disengage the wire from the melt pool. In some examples, the material delivery device is configured to measure an arc voltage between the wire and the component.

Device (1) for displacing at least one assembly (2, 2′) between a provisioning zone (3) and a working zone (4) of at least one process chamber (5) of a process chamber apparatus (6) for soldering, in particular for reflow soldering, comprising at least one displacement device (7), wherein the at least one assembly (2, 2′) carries out, at least in sections, a displacement movement (9), or such a displacement movement (9) can be carried out, such that the at least one assembly (2, 2′) is displaced by means of a force (8), in particular pushing force, which is transmitted or generated by the displacement device (7), in particular directly, and acts on the assembly (2, 2′).

Device (1) for displacing at least one assembly (2, 2′) between a provisioning zone (3) and a working zone (4) of at least one process chamber (5) of a process chamber apparatus (6) for soldering, in particular for reflow soldering, comprising at least one displacement device (7), wherein the at least one assembly (2, 2′) carries out, at least in sections, a displacement movement (9), or such a displacement movement (9) can be carried out, such that the at least one assembly (2, 2′) is displaced by means of a force (8), in particular pushing force, which is transmitted or generated by the displacement device (7), in particular directly, and acts on the assembly (2, 2′).

A workpiece support device including a base, an electrically conductive worktable rotatably supported with respect to the base, a motor, a reducer that transmits rotation of the motor to the worktable and reduces a speed of the rotation, and a metal adapter interposed between the worktable and the reducer to separate the worktable and the reducer from each other. The worktable and the adapter are electrically insulated by an insulating coating film formed by a surface treatment on a surface of the worktable or the adapter.

A workpiece support device including a base, an electrically conductive worktable rotatably supported with respect to the base, a motor, a reducer that transmits rotation of the motor to the worktable and reduces a speed of the rotation, and a metal adapter interposed between the worktable and the reducer to separate the worktable and the reducer from each other. The worktable and the adapter are electrically insulated by an insulating coating film formed by a surface treatment on a surface of the worktable or the adapter.

The present invention relates to a method for butt welding at least two metal sheets, namely a first metal sheet and a second metal sheet, wherein, in particular, a tailored blank is produced from the metal sheets.

The present invention relates to a method for butt welding at least two metal sheets, namely a first metal sheet and a second metal sheet, wherein, in particular, a tailored blank is produced from the metal sheets.

A system for assembling vehicle body components includes an index table rotatably installed on a mounting frame, assembly units disposed on an upper surface of the index table in four directions by rotary plates, and each including a replacement jig and a fixing jig, the replacement jig and the fixing jig being configured to allow the first and second components to be loaded thereon, and the assembly units being configured to be rotated by a predetermined angle by the index table so that the first and second components are joined together by welding while passing through a plurality of assembly sections, a replacement jig palette positioned in a first assembly section, a component palette positioned in a second assembly section, a plurality of clamping units positioned in a third assembly section, and welders positioned in the third assembly section and the fourth assembly section.

A system and method for automatically joining a cut blank has a mandrel and clamps to conform the cut blank to the mandrel. The clamps include band clamps and pad clamps that pivot about axes that are obliquely angled with respect to the centerline of the mandrel. The clamp axes on one side of the centerline are a mirror image to the clamp axes on the other side. The cut blank has a line of symmetry and is clamped to the centerline of the mandrel with a locator bar. The clamps are then moved to a clamped position. In the clamped position, one edge of the cut blank meets another edge, and a robotic welder joins the edges.