Provided is a welding program production system that can increase efficiency of a welding operation by a welding robot. The welding program production system includes a display control unit that causes a plurality of candidate welding lines detected on the basis of an image of a photographed object to be welded to be displayed in superimposed relation on the image, an input receiving unit that receives an input to select the welding lines from among the plurality of candidate welding lines and an input to specify a welding order and a welding direction for each of the selected welding lines, and a program production unit that produces a welding program on the basis of the specified welding order and welding direction.

In various examples, a computer-implemented method of generating instructions for a welding robot. The computer-implemented method comprises identifying an expected position of a candidate seam on a part to be welded based on a Computer Aided Design (CAD) model of the part, scanning a workspace containing the part to produce a representation of the part, identifying the candidate seam on the part based on the representation of the part and the expected position of the candidate seam, determining an actual position of the candidate seam, and generating welding instructions for the welding robot based at least in part on the actual position of the candidate seam.

A weld overlay system includes a rotation drive section which rotates a tube around its axis; and a welding unit which applies a weld material to the outer peripheral surface of the rotating tube, while the welding unit is advanced along an axial direction of the tube, the welding unit includes: a welding torch; and a weld material supply section which supplies the weld material, the welding torch is disposed such that a tip end of the welding torch is located at an angular position that is advanced at a predetermined angle in a direction opposite to a rotational direction of the tube, and the welding torch is inclined at a predetermined angle in the rotational direction of the tube with respect to a reference line passing through a center axis of the tube and the tip end of the welding torch, viewed from the axial direction of the tube.

Methods for fabricating high-strength aluminum-boron nitride nanotube (Al—BNNT) wires or wire feedstock from Al—BNNT composite raw materials by mechanical deformation using wire drawing and extrusion are provided, as well as large-scale, high-strength Al—BNNT composite components (e.g., with a length on the order of meters (m) and/or a mass on the order of hundreds of kilograms (kg)). The large-scale, high-strength Al—BNNT composite components can be made via wire-based additive manufacturing.

A 3D printer can print a structure by depositing material into a weld pool that is moving relative to a workpiece. An electrode wire can supply energy to the weld pool while being fed at a first feed rate into the weld pool. A second wire can be fed into the weld pool at a second feed rate to deposit additional material and thereby speed up the overall material deposition rate. All of the energy in the weld pool may be supplied by the electrode wire. The printer can dynamically control the first feed rate and the second feed rate during printing. A mathematical model can be used to determine the second feed rate as a function of the first feed rate, the energy put into the weld pool, and the print head travel speed. The second feed rate may optimize the material deposition rate according to the model.

The presently disclosed technology includes a friction stir welding apparatus comprising a frame, a moving platform and a parallel mechanism composed of three branch mechanisms, wherein a first branch mechanism comprises a first sliding pair, a first revolute pair, a telescopic rod and a first spherical pair connected in sequence. A second branch mechanism and a third branch mechanism both comprise a third sliding pair, a second revolute pair, a third linkage and a second spherical pair connected in sequence. The friction stir welding apparatus has high stiffness, low inertia, high dynamic performance and high accuracy, which can achieve precision welding with high requirements on processing quality and accuracy for jointing annular seams of large-scale rocket fuel storage tank barrels in the aviation field, for example. The presently disclosed technology also includes a corresponding friction stir welding system.

A welding method and system (4) using a robotic arm (10), a welding robot (18) and a welding table (2) placed at an angle from horizontal to hold two C-channels (6 and 8) facing each other to maintain position and be welded together. C-channels (6 and 8) face each other to form a closed channel at increased welding speed with less materials having resulting benefits including constant welding, less distortion, and less welding material. Welding begins with restraining C-channels (6 and 8) in conjunction with the angled welding table (2). A robotic arm (10) handles C-channels (6 and 8) to move, place and restrain them relative to each other and the welding table (2). A pressing tool (12) may be a set of pressure-exerting tools (26). A welding robot (18) with a seam finding system (24) preferably welds the restrained C-channels (6 and 8) from top to bottom.

The present invention provides a work piece processing system for operating on a work piece or at least one component of a work piece. The processing system includes a base system for transporting the at least one work piece component, at least one processing head for operating on the work piece component, and means for controlling, the means for controlling the processing system. In a first embodiment, the processing system further includes a support structure, the support structure including at least one frame member having a track. Here, the at least one processing head travels along the track. In a second embodiment, the processing system further includes a multi-linkage robotic arm, the robotic arm including a plurality of rotary joints and a plurality of arm segments interconnecting the rotary joints. Here, the at least one processing head is operably mounted to a free end of one of the plurality of arm segments.

There is described a modular welding device having a welding torch assembly defining a welding axis and having a welding torch rotatable about the welding axis. The welding device further includes a drive assembly releasably attachable to the welding torch assembly and operable to linearly translate the welding torch assembly along an axis of translation. When the drive assembly is attached to the welding torch assembly in a first orientation relative to the welding torch assembly, the drive assembly is detachable from the welding torch assembly and re-attachable to the welding torch assembly so as to be disposed in a second orientation relative to the welding torch assembly.

A system for positioning and welding a bracket 30 to a mounting surface, such as a vehicle side rail 40, including using a pivoting tool 20 on a moveable arm 10 that allows the bracket 30 to pivot to minimize the gap between the bracket 30 and its intended mounting surface. The pivoting tool 20 secures, positions near the surface, and allows the bracket 30 to pivot for a precise surface match. A welder 50 welds the bracket 30 to the surface with the gap minimized while the bracket 30 is held in the desired position. The pivoting tool 20 is preferably on an adjustable appendage 12 or combination end 60 mounted on a distal end of the arm 10. The flexible tooling does not require the bracket 30 to be forced with substantial pressure against the mounting surface.