A welding torch includes a torch body including a flow path forming portion that forms a shielding gas flow path into which an inert gas flows and an outer gas flow path communicating with the shielding gas flow path, a first gas lens that straightens the inert gas in the shielding gas flow path and blows the inert gas out as a shielding gas, and a second gas lens that straightens the inert gas in the outer gas flow path and blows the inert gas out as an outer gas. Provided is an all-position welding device that performs butt welding of tubes, and includes the welding torch and a rotation mechanism for rotating the welding torch around the tube.

A pistol grip for a processing torch is disclosed. The pistol grip includes a main body having a proximal end and a distal end, a pistol trigger having a trigger extension, and a locking mechanism movably coupled to the main body adjacent the proximal end of the main body. The proximal end may be configured to engage a portion of the processing torch. The pistol trigger may be pivotably coupled to the main body. The locking mechanism may be movable between an unlocked position and a locked position where the locking mechanism locks the main body in a fixed position with respect to the processing torch.

Some examples include a computing device that receives optical signal information based on respective optical signals received through a plurality of optical fibers during a welding operation. For example, the plurality of optical fibers may be positioned to receive electromagnetic radiation from a weld area during the welding operation. The computing device may compare the optical signal information corresponding to a first one of the optical fibers with the optical signal information corresponding to a second one of the optical fibers. Based at least partially on the comparing, the computing device may determine whether at least one of a weld geometry or a welding arc is irregular. The computing device may perform at least one action based on determining that at least one of the weld geometry or the welding arc is irregular.

Provided is a high-temperature object observation device including a camera capable of acquiring an image of an observation region adjacent to a heat source and a light shielding device. In the high-temperature object observation device, a light shielding device includes a light shielding part that covers the vicinity of the heat source, a holding object that holds the heat source at a position exposed from the light shielding part, and an actuator that releases engagement of the holding object, and immediately after the light shielding device is brought into operation and the heat source is covered with the light shielding part, the camera acquires an image of the observation region.

A TIG (Tungsten Inert Gas) welding torch (10) comprises a torch body (22), a collet (38a,b,c) for retaining a tungsten rod, and a back cap (42), in which the collet 838a,b,c) passes through an aperture in the torch body (22) from the front of the torch body (22) to the rear of the torch body (22), and is joined directly to the back cap (42) by a screw thread (40a,b,c), the collet (38a,b,c) being drawn backwards against a front section of the torch body (22), to close the collet (38a,b,c) and retain the tungsten rod when the screw thread (40a,b,c) is tightened.

A vibrating welding torch attachment utilizes a battery-operated vibrating mechanism secured within a cylindrical housing. The attachment is configured to be detachably secured to the welding end of a traditional TIG-style welding torch. The battery pack within the attachment is rechargeable.

A torch assembly for cutting or spraying applications. The torch assembly includes a torch connector that connects to at least one cable that communicates with a power supply. The torch assembly includes a trigger mounted on the torch assembly to start and stop torch operations. The trigger electrically communicates with the power supply via the at least one cable. The torch assembly also includes a remote switch mounted on the torch assembly to allow an operator to remotely adjust an output of the power supply to a desired output level. The remote switch is electrically coupled to the power supply via the at least one cable.

Through the present invention, the load of a torch (16) applied to a welding workpiece (W) in a touch start method is reduced, and stability is significantly enhanced. A welding head (10) has a rigid straight-advancing movable part (12), an elevator drive tower (14) for moving the straight-advancing movable part (12) straight forward in the vertical direction, and a torch (16) mounted on the straight-advancing movable part (12) so as to be able to move in the vertical direction. One end part of a balance arm (28) rotatably attached to a multi-purpose support part (22) of the straight-advancing movable part (12) is connected to a torch body (30), and a balance weight (98) is attached to the other end part of the balance arm (28).

A welding gun assembly having a connection between a diffuser and the inner gun tube which provides increased strength between the diffuser and the gun tube to prevent inadvertent damage to the welding torch and upstream components. The diffuser comprises an engagement portion which engages with, and overlaps, at least a part of a sturdier portion of the inner gun tube. This engagement provides a stronger and more stable connection between the gun tube and the diffuser.

A welding gun assembly having a connection between a diffuser and the inner gun tube which provides increased strength between the diffuser and the gun tube to prevent inadvertent damage to the welding torch and upstream components. The diffuser comprises an engagement portion which engages with, and overlaps, at least a part of a sturdier portion of the inner gun tube. This engagement provides a stronger and more stable connection between the gun tube and the diffuser.