A method for synchronizing welding currents of at least two welding current sources prior to performing a simultaneous welding process on at least one workpiece, in particular a welding process with non-consumable electrodes, wherein the method includes the following steps: a first welding current source outputting a reference signal, wherein the reference signal contains synchronization information; a second welding current source measuring or receiving the reference signal and evaluating the synchronization information contained in the reference signal; synchronizing a second welding current of the second welding current source with a first welding current of the first welding current source on the basis of the synchronization information. The invention furthermore relates to a welding current source and to a system having at least two welding current sources.

Welding system and method permit exchange of data with Smart Grid monitors and/or controllers. The welding systems include a welding power supply configured to convert power between the power grid and the welding power supply. A grid interface cooperates with control circuitry to transmit data to and/or from the grid monitors and/or controllers on the grid side. The control circuitry may control operation of the welding power supply based upon data from the grid. The system may include power generation devices (e.g., engine-drive generators) and energy storage devices (e.g., batteries), The control circuitry may control operation of such devices, the exchange of power between them, and the draw of power from the grid or the application of power to the grid based upon the data exchanged with the grid monitors and/or controllers.

A hybrid welding system is provided. In one embodiment, the welding system includes an engine-driven generator, an energy storage device, a contactor, and a controller. The controller may be configured to control delivery of weld power from the generator when a commanded output is below a threshold level, and from both the generator and the energy storage when the commanded output is above the threshold level. Closing of the contactor enables the energy storage device to contribute to weld power during welding operations and to be charged by the generator output independent of charging between weld operations. Additional hybrid welding systems and methods are also disclosed.

A system for depositing a material on a workpiece may include a tool unit to support an electrode and having an electrode supporting element and movement structure configured to move the electrode via the supporting element. The system may include electrical circuitry to produce a voltage potential between the electrode and the surface. The electrical circuitry may have a power source to provide power to elements of the circuitry, and a bank of capacitors configured to be selectively charged by the power source and discharged via an electrode engaged by the electrode supporting element to the surface. In embodiments, the power source may comprise a rechargeable battery. In embodiments, the electrical circuitry may include a processor to control discharge of the bank of capacitors via the electrode to the surface when the electrode is engaged by the electrode supporting element.

A wire feeding device configured to feed welding wire from a wire feeding source to a welding torch is provided with: an intermediate wire feeding source that is disposed between the wire feeding source and the welding torch and is configured to temporarily store the welding wire fed from the wire feeding source and to feed the stored welding wire to the welding torch; a first feeding part that feeds the welding wire at the wire feeding source to the intermediate wire feeding source; a second feeding part that feeds the welding wire stored in the intermediate wire feeding source to the welding torch; and a feed control unit that controls speed of feeding the welding wire by each of the first feeding part and the second feeding part.

A method and apparatus for providing a welding-type power includes a housing with an auxiliary power mount, and a welding type power circuit. A controller, a control power circuit, and an auxiliary power module are disposed in the housing. The auxiliary power module/circuit is mounted to the auxiliary power mount. A standard power receptacle is connected to the auxiliary power module. At least one wiring harness connects the welding type power circuit to the auxiliary power module/circuit, which is the only electrical connection between the auxiliary power circuit and the welding type power circuit. The auxiliary power is electrically isolated from the input power and the welding type power.

Embodiments of modular-based power supply systems to support welding or cutting operations are disclosed. One embodiment includes a module rack having multiple slots configured to accept electrical input power from a single power drop within a welding or cutting environment. Multiple power supply modules are provided that are configured to be inserted into and withdrawn from the multiple slots. Each power supply module is configured to accept an electrical AC input derived from the electrical input power and provide an electrical DC output. The module rack is configured to support reconfigurable parallel electrical connections of subsets of the power supply modules. Each subset is configured to electrically connect to an output power supply stage to provide a dynamic waveform-controlled welding or cutting electrical signal to support generation of a single arc between an electrode and a workpiece.

Systems and methods for a welding-type power supply to provide both a welding output voltage and a battery charging output voltage. The power supply includes a first contactor associated with a first circuit to provide the welding output voltage, and a second contactor associated with a second circuit to provide the battery charging output voltage. An auxiliary switch is operatively coupled to the second contactor, to prevent the first circuit from closing when the second contactor is closed to prevent transmission of the welding output voltage to the second circuit.

Example systems to enable multiple welding-type power supplies to be concurrently set up for operation on a same workpiece include: a work lead splitter configured to couple respective work lead terminals of the multiple welding-type power supplies to a same work clamp; and a power splitter configured to couple respective input power terminals of the multiple welding-type power supplies to a same source of input power.

A power supply system includes multiple power supply devices including a first power supply device and a second power supply device that are connected in common to a load. The first power supply device calculates control information for controlling voltage or current to be output to the load and controls the output to the load based on the calculated control information while transmitting the control information to the second power supply device. The second power supply device receives the control information and controls the output to the load based on the received control information while detecting current to be output from its own device to the load and transmitting current information to the first power supply device. The first power supply device receives the current information transmitted from the second power supply device and calculates control information based on the received current information and the current and voltage detected by its own device.