Patent application number | Description | Published |
20140138366 | SELF-ADJUSTING WIRE FOR WELDING APPLICATIONS - Disclosed are self-adjusting wires, methods of making these self-adjusting wires, and thermal joining processes (such as gas metal arc welding or laser brazing) and other processes using these self-adjusting wires. The wires have a core of a metal or metal alloy suitable as a joining material in the joining process and an exterior layer of a shape-memory alloy, which may be continuous about the exterior of the core or discontinuous such as a longitudinal strip or strips. The shape-memory alloy of the self-adjusting wire is “trained” to a straight-wire shape in its austenite phase. In using the self-adjusting wire in a process, a bent end of the self-adjusting wire is straightened by heating the self-adjusting wire above the austenite phase transition temperature of the shape-memory alloy. | 05-22-2014 |
20140138367 | SELF-ADJUSTING CLAD WIRE FOR WELDING APPLICATIONS - Disclosed are self-adjusting wires, methods of making these self-adjusting wires, and thermal joining processes (such as gas metal arc welding or laser brazing) and other processes using these self-adjusting wires. The wires have an outer layer of a metal or metal alloy suitable as a joining material in the joining process and a core of a shape-memory alloy. The outer layer may be continuous about the exterior of the core or discontinuous such as a longitudinal strip or strips. The shape-memory alloy of the self-adjusting wire is “trained” to a straight-wire shape in its austenite phase. In using the self-adjusting wire in a process, a bent end of the self-adjusting wire is straightened by heating the self-adjusting wire above the austenite phase transition temperature of the shape-memory alloy. | 05-22-2014 |
20140144893 | WELDING A JOINT - Methods for welding a joint are disclosed herein. One example of the method involves welding the joint between two workpieces. Energy is focused onto the joint to weld the joint. The focus of the energy moves relative to the joint. A vaporized material is displaced from a keyhole created by the welding. The vaporized material is vaporized by the energy. A pool of molten material is formed adjacent the keyhole during operation of the energy at the joint. The pool of molten material is manipulated by displacing a portion of the molten material from a near end of the pool and from lateral sides of the pool to a far end of the pool. The far end of the pool is distal to the near end. | 05-29-2014 |
20140231396 | METHOD FOR RESISTANCE WELDING WITH PRE-CHILLING - A method for improving a resistance spot weld includes stacking two or more metal sheets and positioning first and second opposed electrodes on opposite sides of the metal stack. At least one of the metal sheets is chilled in the region where the weld is to be made. Weld current is applied to the electrodes and passes through the metal sheets to create the electric resistance spot weld only after the chilling of the at least one metal sheet reduces the temperature at the faying interface at least 5° C., thereby improving the formation of the weld nugget and quality of the weld joint. The chilling can be obtained by flowing chilled gas onto the surface of one or both of the outermost metal sheets, or by contacting the outermost metal sheets with the chilled electrode for a period of time prior to applying the weld current. | 08-21-2014 |
20140367368 | RESISTANCE SPOT WELDING THIN GAUGE STEELS - Resistance spot welding of a thin-gauge steel workpiece to another steel workpiece is achieved by through the combined use of specific spot welding electrodes and a pulsating welding current. Each of the spot welding electrodes has a weld face that is smaller in diameter than a typical steel spot welding electrode. And the pulsating welding current that is used in conjunction with the smaller-sized spot welding electrodes includes at least two stages of electrical current pulses. | 12-18-2014 |
20150096961 | RESISTANCE SPOT WELDING STEEL AND ALUMINUM WORKPIECES USING INSERTABLE COVER - A method of resistance spot welding a steel workpiece and an aluminum or aluminum alloy workpiece together includes several steps. One step involves inserting a cover between the aluminum or aluminum alloy workpiece and an adjacent welding electrode. In another step, the adjacent welding electrode is pressed against cover, and another opposed welding electrode is pressed against the steel workpiece at a weld site. In yet another step, electrical current is passed between the welding electrodes, passed through the cover, and passed through the workpieces in order to initiate and grow a molten weld pool within the aluminum or aluminum alloy workpiece. | 04-09-2015 |
20150096962 | Aluminum Alloy to Steel Welding Process - A resistance spot welding method may involve spot welding a workpiece stack-up that includes a steel workpiece and an aluminum alloy workpiece that overlap one another to provide a faying interface. A pair of opposed welding electrodes are pressed against opposite sides of the workpiece stack-up with one welding electrode contacting the aluminum alloy workpiece and the other welding electrode contacting the steel workpiece. The welding electrodes are constructed so that, when an electrical current is passed between the electrodes and through the workpiece stack-up, the electrical current has a greater current density in the steel workpiece than in the aluminum alloy workpiece to thereby concentrate heat within a smaller zone in the steel workpiece. Concentrating heat within a smaller zone in the steel workpiece is believed to modify the solidification behavior of the resultant molten aluminum alloy weld pool in a desirable way. | 04-09-2015 |
20150202718 | SUPPRESSING LASER-INDUCED PLUME FOR LASER EDGE WELDING OF ZINC COATED STEELS - A system and method for stabilizing the molten pool in a laser welding operation by suppressing a laser-induced plume which occurs when zinc coated steels are laser welded. The plume is a result of vaporization of zinc, and the zinc vapor in the plume disturbs the molten pool and causes blowholes, spattering and porosity. The stabilization is achieved by applying a gas such as air through a nozzle to the weld area, where the gas has sufficient velocity and flow rate to blow the zinc vapor away from the molten pool. Dramatically improved weld quality results have been demonstrated. Configuration parameters which yield optimum results—including gas flow rate and velocity, and nozzle position and orientation relative to the laser impingement location on the steel—are disclosed. | 07-23-2015 |
20150231730 | RESISTANCE SPOT WELDING STEEL AND ALUMINUM WORKPIECES WITH PROTUBERANCE - A method of resistance spot welding a steel workpiece and an aluminum or aluminum alloy workpiece (“aluminum workpiece”) together includes several steps. In one step a workpiece stack-up is provided. The workpiece stack-up includes a steel workpiece and an aluminum workpiece. Another step involves forming a protuberance in the steel workpiece. In another step a first and second welding electrode is provided. Yet another step involves clamping the first and second welding electrodes over the workpiece stack-up and over the protuberance. And another step involves performing one or more individual resistance spot welds to the workpiece stack-up. | 08-20-2015 |
20150290736 | WELDING WIRE FEEDING DEVICE AND METHOD - Disclosed are wire feeding devices having a wire feeding pipe and a feed unit that pushes a wire through the wire feeding pipe. Either the wire feeding pipe comprises a two- way shape-memory alloy or the wire feeding pipe has an attached, over-lapping, or inserted extension segment extending beyond a distal end of the wire feeding pipe, the extension section comprising a two-way shape-memory alloy. The two-way shape-memory alloy has a trained shape in a martensite phase having a passageway for a wire and a trained shape in an austenite phase having a passageway for a wire that is narrower than the martensite phase passageway. When heated to the austenite phase of the two-way shape-memory alloy, the narrower passageway applies pressure to straighten a bend in the wire. | 10-15-2015 |
20150352658 | INTRUDING FEATURE IN ALUMINUM ALLOY WORKPIECE TO IMPROVE AL-STEEL SPOT WELDING - A method of spot welding a workpiece stack-up that includes a steel workpiece and an adjacent aluminum alloy workpiece involves passing an electrical current through the workpiece stack-up and between facially aligned welding electrodes in contact with opposed sides of the stack-up. The formation of a weld joint between the adjacent steel and aluminum alloy workpieces is aided by an intruding feature located in an aluminum alloy workpiece that provides and delineates one side of the workpiece stack-up and against which a welding electrode is pressed over the intruding feature at the weld site. The intruding feature affects the flow pattern and density of the electrical current that passes through the overlapping workpieces and is also believed to help minimize the effects of any refractory surface oxide layer(s) that may be present on the aluminum alloy workpiece that lies adjacent to the steel workpiece. | 12-10-2015 |
20150352659 | COVER PLATE WITH INTRUDING FEATURE TO IMPROVE AL-STEEL SPOT WELDING - A method of spot welding a workpiece stack-up that includes a steel workpiece and an adjacent aluminum alloy workpiece involves passing an electrical current through the workpieces and between opposed welding electrodes. The formation of a weld joint between the adjacent steel and aluminum alloy workpieces is aided by a cover plate that is located between the aluminum alloy workpiece that lies adjacent to the steel workpiece and the welding electrode disposed on the same side of the workpiece stack-up. The cover plate, which includes an intruding feature, affects the flow pattern and density of the electrical current that passes through the adjacent steel and aluminum alloy workpieces in a way that helps improve the strength of the weld joint. | 12-10-2015 |