A pressure welding device (1) includes a plastification device (7), an upsetting device (8) and a mounting (11) for the components (2,3) to be welded together and a machine frame (12). The pressure welding device further includes a machine head (13) and an upsetting head (27) which can be moved relative one another along a machine axis (6). The mounting (11) includes a component seat (36), which is mounted on the machine frame (12) so as to be able to float between the machine head (13) and the upsetting head (27), and a preferably automatic adjusting device (17) for adaptation to different component dimensions, in particular component lengths.

A pressure welding device (1) includes a plastification device (7), an upsetting device (8) and a mounting (11) for the components (2,3) to be welded together and a machine frame (12). The pressure welding device further includes a machine head (13) and an upsetting head (27) which can be moved relative one another along a machine axis (6). The mounting (11) includes a component seat (36), which is mounted on the machine frame (12) so as to be able to float between the machine head (13) and the upsetting head (27), and a preferably automatic adjusting device (17) for adaptation to different component dimensions, in particular component lengths.

A system for manufacturing a drive shaft assembly comprises a welding apparatus configured to weld a tube to an end fitting to form the drive shaft assembly having an annular weld. A transport apparatus is configured to transport the drive shaft assembly away from the welding apparatus. A knurling apparatus receives the drive shaft assembly from the transport apparatus. The knurling apparatus is configured to knurl the weld of the drive shaft assembly. The knurling apparatus includes a pair of knurling plates having textured surfaces in facing relationship. One of the knurling plates is configured to move relative to the other of the knurling plates to roll the drive shaft assembly between the textured surfaces, thereby knurling the weld to improve an appearance and texture of the outer surface of the drive shaft assembly.

A pressure welding device (1), especially a friction welding device, holds workpiece parts (2, 4) in clamping devices (6, 7) and axially moves the workpieces towards each other by means of a feed device (21). The pressure welding device (1) has a measuring device (8, 13), measuring in a contactless manner. The measuring device detects the surface condition and/or the concentricity and/or true running and/or the axial runout and/or radial runout in a front welding region (3, 5) of a workpiece part (2, 4).

A pressure welding device (1), especially a friction welding device, holds workpiece parts (2, 4) in clamping devices (6, 7) and axially moves the workpieces towards each other by means of a feed device (21). The pressure welding device (1) has a measuring device (8, 13), measuring in a contactless manner. The measuring device detects the surface condition and/or the concentricity and/or true running and/or the axial runout and/or radial runout in a front welding region (3, 5) of a workpiece part (2, 4).

An arc welding process is disclosed. In one example, the process comprises arranging an electrode at the front of a joining gap formed by joining partners contacted with opposite poles to the electrode; arranging a pair of magnetic poles at the rear or top of the joining gap and substantially centered with respect to the front electrode surface; generating the arc such that the joining partners form a welding zone comprising a weld pool with substantially simultaneous induction of a low-frequency oscillating magnetic field between the pair of magnetic poles; progressively moving the electrode along the joining gap to move the weld pool between the joining partners, leaving behind a weld seam, with synchronous entrainment of the low-frequency oscillating magnetic field. A magnetic flux density of the low-frequency oscillating magnetic field is selected such that an induced Lorentz force supports the weld pool and prevents escape from the joining gap.

A magnet arrangement for a magnetically impelled arc butt welding system, wherein the system is used to weld an airfoil to a platform of a gas turbine. The magnet arrangement includes a first plurality of magnets wherein the magnets are located adjacent a first curved airfoil surface and arranged in a first curved shape corresponding to a shape of the first curved airfoil surface. The magnet arrangement also includes a second plurality of magnets wherein the magnets are located adjacent a second curved airfoil surface and arranged in a second curved shape corresponding to a shape of the second curved airfoil surface such that the first plurality of magnets has a different curvature than the second plurality of magnets. The first and second plurality of magnets guide an electric arc of the system along mating surfaces to heat the mating surfaces to enable the airfoil and platform to be forged together.

A magnet arrangement for a magnetically impelled arc butt welding system, wherein the system is used to weld an airfoil to a platform of a gas turbine. The magnet arrangement includes a first plurality of magnets wherein the magnets are located adjacent a first curved airfoil surface and arranged in a first curved shape corresponding to a shape of the first curved airfoil surface. The magnet arrangement also includes a second plurality of magnets wherein the magnets are located adjacent a second curved airfoil surface and arranged in a second curved shape corresponding to a shape of the second curved airfoil surface such that the first plurality of magnets has a different curvature than the second plurality of magnets. The first and second plurality of magnets guide an electric arc of the system along mating surfaces to heat the mating surfaces to enable the airfoil and platform to be forged together.

Apparatuses, systems, and/or methods relate to a welding system that provides a field former for use in welding applications. The welding system includes a welding torch that includes one or more coil windings through which flows current that forms a magnetic field. The magnetic field is concentric to the tool center point. An arc is formed between the electrode and a workpiece. The magnetic field forces the arc in a center of the welding torch or the one or more coiled windings.

Apparatuses, systems, and/or methods relate to a welding system that provides a field former for use in welding applications. The welding system includes a welding torch that includes one or more coil windings through which flows current that forms a magnetic field. The magnetic field is concentric to the tool center point. An arc is formed between the electrode and a workpiece. The magnetic field forces the arc in a center of the welding torch or the one or more coiled windings.