The present application relates to a field system and methods that can be deployed in the application of pipe welding. The field system provides many embodiments relating to pipe welding systems and methods, that can be used in combination with one another, or individually. Such welding systems and methods, include, for example, internal welding systems and methods, tie-in welding system and methods, pipe inspection systems and methods, pipe handling systems and methods, internal pipe cooling systems and methods, non-destructive testing systems and methods, as well as remote interface and database systems and methods (uLog), to name a few. The application further relates to welded pipes that result from some or all of such processes.

In certain embodiments, inductive heating is added to a metal working process, such as a welding process, by an induction heating head. The induction heating head may be adapted specifically for this purpose, and may include one or more coils to direct and place the inductive energy, protective structures, and so forth. Productivity of a welding process may be improved by the application of heat from the induction heating head. The heating is in addition to heat from a welding arc, and may facilitate application of welding wire electrode materials into narrow grooves and gaps, as well as make the processes more amenable to the use of certain compositions of welding wire, shielding gasses, flux materials, and so forth. In addition, distortion and stresses are reduced by the application of the induction heating energy in addition to the welding arc source.

A welding current source for supplying an electric welding current circuit with electric current and electric voltage for carrying out an electric welding process, wherein the welding current source is provided with a power conditioning device for conditioning electric current supplied to the welding current source for suitability in an electric welding process, wherein furthermore on a housing of the welding current source there are provided two pole contact devices, each of which protrude from the housing, and the welding current source is equipped with a cooling device, with which thermal heat loss released by the welding current source can be dissipated. In the case of such a welding current source and despite sufficient cooling of the electrical components, it shall be possible that the housing of the welding current source can be designed to be also smaller than before.

A method (100) for processing conductor segments (2) of a winding support (3) of an electric motor, wherein at least two conductor segments (2) are arranged on the winding support (3), wherein the conductor segments (2) protrude out of the end side of the winding support (3) by way of end sections (4). The method (100) ensuring sufficient precision when positioning the end sections joined for a welding operation using at least the following steps: advancing (200) a processing unit (6), which can be moved on a circular path (K) along a guide device (5) and having at least one first actuator element (7a) and at least one second actuator element (7b) to at least one first end section pair (4a, 4b) having a first end section (4a) and a second end section (4b) or the first end section (4a) and the second end section (4b) to the processing unit (6), joining (300) the first actuator element (7a) and the second actuator element (7b) so that, in a clamping region (9), a clamping force joins the first end section (4a) and the second end section (4b) into a welding position, welding (400) the first end section (4a) and the second end section (4b).

Systems and methods are disclosed relating to welding-type power supplies. In some examples, the power supplies may have no vents, which may help prevent environmental contaminants from entering the power supplies. Instead, the power supplies include one or more thermal interfaces configured to conduct heat generated by internal circuitry of the power supply from the interior of the power supply to an exterior of the power supply. Additionally, the thermal interface(s) may be configured for attachment to one or more exterior heat dissipating devices.

A method of manufacturing a metallic part in a weldable material by solid freeform fabrication comprising generating three dimensional model of the part, slicing the three dimensional model into a set of parallel, sliced layers and then dividing each layer into a set of one-dimensional pieces and, with reference to layered weld-bead geometry data, forming a computer-generated, direction specific, layered model of the part. The method also comprises uploading the layered model into a welding control system and directing the welding control system to deposit a sequence of one-dimensional weld beads of the weldable material onto the supporting substrate in a pattern required to form a first layer of the layered model and depositing a second welded layer onto the previous deposited layer in a configuration the same as the second layer, and repeating each successive weld bead until the entire part is completed. The method further includes displacing the atmosphere within the immediate vicinity of the heat source with an inert gas atmosphere which produces a required flow rate, and in which that inert atmosphere contains a maximum oxygen concentration, wherein the inert gas is delivered by an apparatus through a matrix of individual gas diffusers; and engaging an induction heating and closed loop cooling apparatus synergic to a welding control system and pre-heating the substrate material including the deposited weld beads, relevant to the type of weldable material, wherein induction heating and cooling cycles are applied constantly or pulsed from the first layer to the final layer, where optimal heating and/or cooling cycles of the weldable material are relative to the final desired part shape and microstructure.

A method for forming a large-diameter special-shaped cross section thin-wall tubular part. A tailor welded barrel blank is adopted as an original blank for forming of the large-diameter special-shaped cross section thin-wall tubular part. After a desired shape is formed, the original weld joint is removed and butt joint tailor welding is performed on the tubular part again. Since the tailor weld joint of the original barrel blank is removed from the final part, there is no need to consider the consistency or coordination of the microstructure of the weld joint and the base metal during the forming process and the subsequent thermal treatment process.

An assembly is provided for induction welding. This assembly utilizes a plurality of heat shields (e.g., mica heat shields) that are aligned/disposed in end-to-end relation, with each such heat shield having a recess. An induction welding coil may be disposed within a heat shield recess during induction welding operations and is movable along a welding path while proceeding along the recesses of the various heat shields. This welding path may be axially extending or may be curved. The induction welding assembly may be used to induction weld a stiffener to a curved skin or shell, for instance where a base of the recess for each heat shield is curved such that the induction welding coil may be moved along a curved welding path and while maintaining a constant spacing between the induction welding coil and the recess base of the various heat shields.

The invention relates to a welding device for welding at least one workpiece, comprising: a welding torch, which is designed to create an electric arc for welding the at least one workpiece; and a nozzle apparatus, which is arranged on the welding torch and has a cooling nozzle array, which has at least one row of cooling nozzles, wherein for cooling the workpiece, the respective cooling nozzle can be supplied with an adjustable volume flow of a cooling medium.

A machining apparatus for laser machining a workpiece (12) in a machining zone (13) is provided, having a first interface (14) for a machining laser source for generating a machining laser beam (15), an outlet opening (18) for the machining laser beam (15), In an optical system between the first interface (14) and the outlet opening (18), which has at least one laser beam guiding device (22) having at least one movable surface (24) and at least one actuator (26), with which the movable surface (24) is dynamically adjustable, and a cooling device (28) for cooling the at least one actuator (26), wherein the cooling device (28) has at least one primary circuit (30) through which a first cooling fluid can flow without contact with the actuator (26). Furthermore, a set of parts for a machining apparatus for laser machining a workpiece (12) and a method of laser machining a workpiece (12) using such machining apparatus are also provided.