An example welding accessory includes: a weld input configured to receive first welding-type power; and power conversion circuitry configured to: convert a first portion of the first welding-type power to second welding-type power; output the second welding-type power to a weld circuit; convert a second portion of the first welding-type power to preheating power; and output the preheating power to a preheater.

Apparatuses and methods for repairing a defect in a nuclear reactor are provided. The apparatus includes a body for insertion in a tubular structure, the body includes: an end effector having a weld torch operable to deposit weld material by forming molten weld droplets and depositing the weld droplets the tubular structure. A drive unit includes a brace for selectively anchoring against said tubular structure; at least one linear actuator for moving the apparatus relative to the brace; and a rotational actuator coupled to rotate the weld torch. The method includes inserting a repair apparatus into tubular structure of the nuclear reactor; moving the repair apparatus to a defect location; depositing a protective weld layer over the defect by sequentially depositing weld droplets atop a weld pool on the tubular structure, wherein the protective weld layer bonds to the tubular structure surrounding the defect.

A method of aligning first and second pipes end-to-end in a position ready for welding. Each pipe has an end bevelled with a shape scanned and stored in memory of a control unit. At least one of the pipes has machine readable codes distributed around their circumference of the pipe. The method includes effecting relative movement of the ends of the first and second pipes towards each other, reading at least one of the codes with a reader, and ascertaining the relative movement required to align the pipes in accordance with a target orientation. The relative movement is ascertained with information provided by the read code and the shapes of the bevelled ends stored in the control unit memory. In other aspects, a closed loop control method and machine-learning may be used to align the pipes. A pipe-laying vessel including pipe handling equipment and the control unit is also provided.

Disclosed is a hybrid additive manufacturing system that includes a laser system and an additive manufacturing tool, such as an arc welding type torch. The tool is configured to receive a metallic electrode wire, which is heated by a power supply to create droplets for deposition to create the part by building up successive layers of metal. The additive manufacturing system operates through coordination of the laser system to generate a laser beam, which is applied to a weld bead, and an arc welding process, which provides material for the part. A threshold value of laser intensity and/or power can be applied to the weld puddle to stabilize the arc. Through the laser beam, an arc cone position can be manipulated such that the energy into the molten pool can be redistributed.

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 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.

Provided is a turbine rotor disc repairing method for removing a defect portion created in an outer peripheral portion of a turbine rotor disc having a blade groove formed in the outer peripheral portion and then reforming the blade groove. The method includes: removing a region including the defect portion from the turbine rotor disc with a rotating shaft supported horizontally to form a disc under repair; annularly joining an edge plate along an outer peripheral edge of the disc under repair by welding; performing build-up welding of a surface to be welded while rotating the disc under repair around the rotating shaft; and removing an excess thickness of a build-up weld and the edge plate from the disc under repair, wherein the disc under repair includes a first groove and a first route surface continuous with the first groove.

Provided is a turbine rotor disc repairing method for removing a defect portion created in an outer peripheral portion of a turbine rotor disc having a blade groove formed in the outer peripheral portion and then reforming the blade groove. The method includes: removing a region including the defect portion from the turbine rotor disc with a rotating shaft supported horizontally to form a disc under repair; annularly joining an edge plate along an outer peripheral edge of the disc under repair by welding; performing build-up welding of a surface to be welded while rotating the disc under repair around the rotating shaft; and removing an excess thickness of a build-up weld and the edge plate from the disc under repair, wherein the disc under repair includes a first groove and a first route surface continuous with the first groove.

The application relates to a method for producing a double-walled pipe (1) and a pipe (1) of this type, hating an outer pipe (3) which is press-fitted with an inner pipe (2) consisting of a corrosion-resistant alloy, wherein an adhesive (4) is inserted at least in regions between the outer pipe (3) and the inner pipe (2), wherein, after adhering the inner pipe (2) with the outer pipe (3), the inner pipe (2) and the adhesive layer (4) are removed at the pipe ends, and the inner side of the outer pipe (3) is plated via an integral connection with the inner pipe (2).

The application relates to a method for producing a double-walled pipe (1) and a pipe (1) of this type, hating an outer pipe (3) which is press-fitted with an inner pipe (2) consisting of a corrosion-resistant alloy, wherein an adhesive (4) is inserted at least in regions between the outer pipe (3) and the inner pipe (2), wherein, after adhering the inner pipe (2) with the outer pipe (3), the inner pipe (2) and the adhesive layer (4) are removed at the pipe ends, and the inner side of the outer pipe (3) is plated via an integral connection with the inner pipe (2).