Provided herein is a quick disconnect torch handle for use in a plasma arc system. In one approach, the plasma arc system includes a lead having a first end connected to a power source and a second end connected to a torch handle. The quick disconnect is located at a proximal end of the torch handle, and may include at least one signal connection, a pilot connection, a fluid connection, and a main power connection. The fluid and power connection may be formed by a connection between a main power socket and a conductive conduit. Specifically, the main power socket includes a conductive spring and an O-ring encircling an interior bore thereof. Removal of the conductive conduit from the main power socket causes the fluid connection to break between the O-ring and the conductive conduit, and then the power connection to break between the conductive spring and the conductive conduit.

An additive manufacturing system is disclosed including multiple conveying pipelines, a mixer and a nozzle. The multiple conveying pipelines are connected to respective material sources. The multiple conveying pipelines are connected to the mixer which is configured to mix in real time powder materials supplied via the multiple conveying pipelines during additive manufacturing. The mixer is connected via a supply pipeline to the nozzle which is configured to deliver mixed material onto a substrate to perform the additive manufacturing. Each of the multiple conveying pipelines is configured to change conveying amount or speed of the powder materials in real time. An additive manufacturing method for the above additive manufacturing system is also disclosed. The additive manufacturing system and method can adjust in real time types or proportions of the materials so as to meet different property requirements for different parts of a product.

Systems and methods for gas tungsten arc welding (GTAW) training systems are described. In some examples, a GTAW training system includes a GTAW torch and filler rod attachment having one or more markers to facilitate position and/or orientation detection and/or tracking of the GTAW torch and/or filler rod. One or more sensors of the GTAW training system may be configured to capture data relating to the markers of the GTAW torch and/or filler rod attachment. A training controller of the GTAW training system may use the markers and/or sensor data to track and/or determine positions, orientations, and/or movement of the GTAW torch and/or filler rod. The positions, orientations, and/or movement may be analyzed in conjunction with welding parameter data to provide training feedback.

A device for welding pipe branches and extensions to a main pipe from inside the main pipe. The device includes a frame (30) and a frame cylinder (31), an elongated electrode shaft (3) having a longitudinal central axis, around which the electrode shaft is rotatably arranged, a rotator disc (13) of the electrode shaft (3), through which the electrode shaft is able to slide axially, an electrode holder (4) in the end of the electrode shaft, an electrode (5) fastened to the holder (4), a welding jig (1, 1.2, 1.3; 2.3, 2.4, 2.5) for supporting the main pipe (6.1; 2.2a) in the welding station, a fastening element (8, 8a) of the welding jig, a rotating element (9) of the welding jig, to which the fastening element is fastened and which is rotatably bearing-mounted inside the frame cylinder (31) such that the rotational axis of the welding jig combines with the central axis of the electrode shaft. The welding jig has a support bracket (1.2, 1.3; 2.4, 2.5) for the main pipe (6.1; 2.2a), by which the main pipe is to be supported in the station, in which the centre axes of the main pipe (6.1; 2.2a) and the electrode shaft (3) are combined. The welding jig has, surrounding the electrode shaft (3), an adapter piece (23), to which is connected a shielding gas channel (24), the shielding gas being adapted to be guided through the adapter piece (23), into the main pipe, and through it, also into the pipe branch or extension to be welded, when the main pipe, or the pipe extension (6.3) to be welded to the main pipe, or the shielding gas pipe (2.3) surrounding the main pipe rests against the adapter piece (23). The rotator disc (13) of the electrode shaft is equipped with a locking device (12), with which the electrode shaft (3) is to be immovably locked in relation to the rotator disc (13).

Embodiments of a tungsten inert gas (TIG) welding torch with an improved air cooled handle are provided. The welding torch may include a body, a cable assembly, and a torch head, with a handle placed over the body and the cable assembly. The handle may feature a curved end designed to fit near the torch head without contacting the torch head, providing a closer gripping point to allow greater control of the torch. In addition, the handle may be spaced from the body and the cable assembly to form an air space within the handle through which air may flow to cool the handle.

A handling apparatus for performing a TIG weld comprises a main body for holding a filler rod; a feeding device attached to the main body and configured to advance the filler rod during welding; a control unit configured to act on the feeding device and to regulate the speed of the filler rod.

A GTAW system and a welding method suitable for ultra-narrow gaps, and belongs to the technical field of narrow gap welding. The device includes a argon arc welding machine, a GTAW torch, a welding trolley, a wire feeding device, and a gas protection device. The GTAW torch includes a rotating motor, a rotating tungsten, a conductive system, and a gas supply system. The non-axisymmetric rotating tungsten is drived by the rotating motor through the central rotating shaft. The conductive system is used for connecting and supplying electric power from the argon arc welding machine, and the air supply system is used for providing shielding gas into the welding torch. The GTAW torch is fixed on the welding trolley, and the GTAW torch is moved by the welding trolley, and the wire feeding device moves synchronously with the welding torch.

A TIG torch for welding, soldering or coating, wherein an electrode is radially surrounded by an inner gas nozzle as far as the electrode tip. A first gas flow in the direction of a workpiece surface through a gap between the inner lateral surface of the inner gas nozzle and the lateral surface of the electrode. The inner gas nozzle is fastened to a sleeve-shaped inner gas nozzle carrier and is surrounded by an outer gas nozzle fixed to an outer gas nozzle carrier or an outer gas nozzle. A second gas flow in the direction of the workpiece surface between the radially outer lateral surface of the inner gas nozzle and the inner lateral surface of the outer gas nozzle. An electrically insulating element is arranged between the inner gas nozzle carrier, inner gas nozzle and/or electrode and the outer gas nozzle carrier and/or outer gas nozzle.

The present invention relates to a welding torch including a mounting jig for mounting a wire-aiming guide which feeds a welding wire toward a molten pool of a work piece, wherein the mounting jig has a male screw that can be screwed into a female screw provided in a torch body, and is detachably mounted to the torch body; and a mounting jig. The present invention provides the welding torch with which a wire-aiming guide can be stably mounted and which can mount a highly versatile wire-aiming guide; and the mounting jig.

According to the present invention, there is provided a wire aiming guide capable of further improving usability. The present invention provides a wire aiming guide (1) configured to guide a welding wire (W) and feed the welding wire from a tip side thereof while being attached to a welding torch including: a first guide member (2) and a second guide member (3) configured to guide the welding wire (W): and a connecting portion (5) rotatably connecting the first guide member (2) and the second guide member (3), wherein a direction of the welding wire (W) fed from a tip end side of the first guide member (2) is adjusted by bending the first guide member (2) with respect to the second guide member (3).