A welded pipe assembly includes a first and a second metal pipes, and a welded joint or welded material connecting the first pipe with the second pipe. The first and second metal pipes each have a length of at least 30 and an exterior diameter of less than 24. The weld material includes a plurality of weld pass layers including a first internal pass layer and a second internal pass layer disposed on top of the first internal pass layer. The second internal pass layer is positioned closer to an interior longitudinal axis of the welded first and second pipes than the first internal pass layer. The welded joint includes a first internal bevel formed in the first metal pipe and a second internal bevel formed in the second metal pipe. The first internal pass layer is disposed in a region defined by the first and the second internal bevels.

A field system for welding two pipes includes a first pipe engagement structure, a second pipe engagement structure, one or more weld torches, a motor and one or more processors. The one or more weld torches are configured to be positioned within the pipes to create an internal weld at an interface region between the pipes. The motor is operatively associated with the one or more weld torches to rotate the one or more weld torch along the interface region between the pipes. The one or more processors control the motor and the one or more weld torches. The one or more processors operate the motor and the one or more weld torches to generate a complete circumferential weld along the interface region by rotating the one or more weld torches along the interface region in a single rotational direction until the complete circumferential weld is completed.

Apparatus, systems, processes, control systems, means and methods for near-weld gas purging and welding. A focused circumferential near-weld purge gas delivery system for pipeline welding. A near-weld purge rig which has a near-weld purge gas channel and which achieves a low oxygen concentration proximate to a pipe gap for welding. The gas used for purging is also directed against an interior surface of the pipe to be welded. The directed gas cools the pipe to a desired temperature.

An auxiliary device for installing piston rings is described, which includes a mounting base, a transmission device, a connecting rod and a bracing structure. The mounting base includes a platform, an opening hole and an accommodating space. The transmission device is disposed in the accommodating space and includes a guide screw rod, a sliding base and a motor. The sliding base is slidably screwed on the guide screw rod. The motor can drive the guide screw rod to move the sliding base. The connecting rod is disposed on the sliding base. An external diameter of the piston ring while being put around the connecting rod is greater than an inner diameter of the opening hole. The bracing structure is disposed on the connecting rod. An external diameter of the bracing structure is getting greater from one end connected to the connecting rod. The bracing structure can accommodate the piston.

A vibration dampening device for the manufacture by rotational friction welding of a turbomachine rotor including a first disc and a second disc each having a hub with an internal surface is provided. The device includes a first clamping device configured to be positioned coaxially to the hub of the first disc and having a pair of radially opposite jaws suited to come into contact with the internal surface of the hub of the first disc.

The present disclosure discloses a light-transmittance device and a use method, and belongs to the technical field of manufacturing of rotary equipment. The light-transmittance device includes cylinder sections, a two-column vertical lathe, and a vertical lathe platform; T-shaped supporting fixtures are arranged inside the cylinder sections; light-transmittance tools are arranged at center positions of the cylinder sections; two ends of the cylinder sections are provided with rolling ring base plates which are paired and mounted with the cylinder sections; a roller frame is arranged on a lower side of each group of cylinder section; furthermore, the rolling frames are slidably connected with a rigid rail; a theodolite is arranged on one side close to the cylinder sections; and a triangular bracket and a light-transmittance platform are arranged on a lower side of a shell of the theodolite.

An alignment rectifying device for a rectifying a joint between two joint between two pipes includes a central hub, multiple plunger-cylinder assemblies, and a curved plate member. Each plunger-cylinder assembly comprises a plunger portion in sliding communication within a cylinder portion, where each plunger-cylinder assembly outspreads radially from the central hub, each plunger-cylinder assembly actuated by a hydraulic pump positioned within the hub to radially extend the plunger portion of the plunger-cylinder assembly. The curved plate member is positioned at the distal end of the plunger portion each plunger-cylinder assembly, where the curved plate member is configured to contact a surface of joint between two pipes internally, where each curved plate member actuated by the hydraulic pump applies pressure on the joint to rectify misalignment at the joint.

A roll-out wheel has a base housing secured to a working surface. A rolling arm having a lever end and a working end pivots about a hinge point in the housing. A hand wheel and a pipe chuck are rotatably attached to the working end by a rolling sleeve. A pipe to be welded is securable on the pipe chuck and rotatable in unison with the hand wheel. Rotation of the hand wheel permits welding about the perimeter of the pipe without moving the welding tool. A clamping mechanism can permit or prevent rotation of the hand wheel. A pivoting mechanism can raise or lower the working end.

A method of fabrication by friction stir welding (FSW) at an interface between adjoining components such as pipe lengths of a pipeline has layers of different metals on each side. FSW is performed from one side of the adjoining components by effecting relative movement of a first FSW tool along the interface. FSW is performed from an opposite side of the adjoining components by effecting relative movement of a second FSW tool along the interface. Advantageously, FSW is performed simultaneously from both sides of the adjoining components with the FSW tools applying loads in mutual opposition about the adjoining components.

A method of fabricating a metal pipeline by friction stir welding (FSW) along a circumferential interface includes spinning first and second FSW tools about respective axes of rotation in contact with a pipe wall to heat, plasticize, and stir respective zones of plasticized metal at the interface. The zone of plasticized metal produced by the second FSW tool extends deeper into the pipe wall than the zone of plasticized metal produced by the first FSW tool. Relative circumferential movement of the FSW tools along the interface is controlled such that the second FSW tool following the first FSW tool enters the zone of plasticized metal produced by the first FSW tool while the metal in that zone remains plastic.