A method for manufacturing a laminated core includes a laminating process of obtaining a laminate in which a plurality of core pieces are laminated, and a welding process of forming a weld bead which extends in a thickness direction of the laminate on a side surface of the laminate. In the welding process, a heat input when a center portion in a longitudinal direction of the weld bead is formed is greater than a heat input when an end portion of the weld bead is formed.

A non-magnetic member 32, a first magnetic member 34 and a second magnetic member 36 are prepared. The first magnetic member 34 and the second magnetic member 36 are connected to the non-magnetic member 32. Then, a first bonding portion 56 and which bonds the non-magnetic member 32 and the first magnetic member 34 to each other, and a second bonding portion 60 which bonds the non-magnetic member 32 and the second magnetic member 36 to each other are formed. A hot isostatic pressing process is performed to the non-magnetic member 32, the first magnetic member 34 and the second magnetic member 36 to establish diffusion-bond. Thereafter, the non-magnetic member 32, the first magnetic member 34 and the second magnetic member 36 are hollowed, and the first bonding portion 56 and the second bonding portion 60 are removed. Thereafter, the non-magnetic member 32 becomes a non-magnetic body 26, the first magnetic member 34 becomes a first magnetic body 28, the second magnetic member 36 becomes a second magnetic body 30 and a sleeve 10 is obtained.

A method for repairing a ceramic matrix composite (CMC) article including a ceramic material in a matrix including a metal alloy, wherein a localized region of the metal alloy has a defect. The method includes applying heat to the localized region for a time sufficient to increase the temperature of the metal alloy in the localized region above the melt temperature thereof and cause the metal alloy in the localized region to flow and seal the crack.

A ball forming device 50 for forming a ball 43 at a tip of a wire 42 by producing discharge between a torch electrode 48 and the tip of the wire 42, the device includes: a current supply unit 54 configured to supply a ball-forming current between the torch electrode 48 and the tip of the wire 42; and a current control unit 57 configured to control the current supply unit 54, so that a signal of the ball-forming current for a predetermined period includes a first period in which the signal takes a predetermined current value and a second period including a triangle wave. With this, it is possible to provide a ball forming device, a wire-bonding apparatus, and a ball formation method that are capable of suppressing formation of deformed balls.

A welding device for automatically welding a workpiece by a welding robot using a welding wire includes a welding control device that controls operation and welding work of the welding robot. The welding control device includes a sensing unit configured to detect a position of the workpiece, a root gap calculating unit configured to determine a root gap, and a storage unit including wire melting information as a database of a proper welding current corresponding to a feeding rate for each of the welding wire. A lamination pattern and a welding condition are provided in accordance with the root gap determined by the root gap calculating unit and the wire melting information so that an amount of heat input is equal to or less than a predetermined amount of heat input.

A welding device for welding a workpiece using a welding robot includes a welding control device that controls operation of the welding robot and a preheating device that preheats the workpiece. The welding control device includes an input unit through which at least one or both of dimensions of the workpiece and a shape of a welding joint, and preheating information are inputted, and a storage unit that includes at least welding robot operation orbit teaching data, welding condition data, and preheating condition data. The welding control device automatically provides a preheating condition, a welding robot operation orbit, and a welding condition for the welding joint to be welded, and preheating and welding are performed.

A repair pin-stud used in processes for repairing panels, such as honeycomb panels. The repair pin-stud includes a cylindrical stud member, a tip on a first end of the cylindrical stud member, and an elongated installation member connected to a second end of the cylindrical stud member. The repair pin-stud further includes a tubular pin concentric with the cylindrical stud member. A first end of the tubular pin is connected to the cylindrical stud member, and a second end of the tubular pin is open and the elongated installation member extends outwardly from the second end of the tubular pin.

A method of forming a fused rail assembly in which one or more heating elements are positioned in a gap between first and second end faces of aligned first and second rails. The end faces are covered by a non-oxidizing atmosphere, and the heating elements are energized, to heat portions of the first and second rails to a predetermined hot working temperature. While one or more of the first end faces is moving transversely relative to center lines of the rails, and while the heated portions are at the predetermined hot working temperature, the first and second end faces are engaged with each other, to fuse together, forming the fused rail assembly. The transverse motion of the first end face or the second end face or both may commence before or after the first and second end faces are engaged.

A method of connecting together two unit elements (2, 4) of an undersea fluid transport pipe that is subjected to fatigue, by welding together two metallic or bi-metallic unit pipe elements that have been put into abutment via their respective free ends (2a, 4a), the welding being done by making three distinct weld beads (6, 8, 10), with a last weld bead (8) being deposited between two lateral first weld beads (6, 10), and being followed directly by controlled sanding of the weld beads in order to apply compression stresses on them.

A welding system is disclosed that includes a power supply, a controller in communication with the power supply, and a welder in communication with the controller. The controller detects a configuration of the welder that includes at least a 1G configuration. Upon the controller detecting the 1G configuration, the controller inverts a height adjustment and automatically calculates a contact tip to work distance.