In some aspects, material processing head can include a body; an antenna disposed within the body; a first tag, associated with a first consumable component, disposed within a flux communication zone of the body at a first distance from the antenna, the first tag having a first resonant frequency; and a second tag, associated with a second consumable component, disposed within the flux communication zone of the body at a second distance from the antenna, the second tag having a second resonant frequency that is different than the first resonant frequency, where the first and second resonant frequencies are tuned based upon at least one of: i) a difference between the first distance and the second distance; or ii) a characteristic (e.g., shape) of the flux communication zone in which the first tag and/or the second tag is disposed.

A multi-function machine is provided. In one embodiment, the multi-function machine includes a generator driven by an engine for generating electrical power. The multi-function machine also includes a welding power supply electrically powered by the generator to provide an arc gouging output during an arc gouging process when the multi-function machine is in an arc gouging mode. The multi-function machine further includes an air compressor system driven by the generator to provide a compressed air output to support the arc gouging process. The multi-function machine also includes a controller operatively connected to the welding power supply and the air compressor system. The air compressor system is commanded by the controller to activate to provide the compressed air output when the arc gouging mode is selected and/or change a characteristic of the compressed air output when an arc gouging set point of the arc gouging mode is changed.

A power supply to provide welding power. The power supply may include a first printed circuit board (PCB) disposed on a primary side of the power supply; a first set of components mounted on the first PCB; a second PCB disposed on a secondary side of the power supply; a second set of components mounted on the second PCB; a transformer stage coupled to the first PCB and to the second PCB, wherein the first PCB and the second PCB are independently detachable from the power supply.

A power supply to provide welding power. The power supply may include a first printed circuit board (PCB) disposed on a primary side of the power supply; a first set of components mounted on the first PCB; a second PCB disposed on a secondary side of the power supply; a second set of components mounted on the second PCB; a transformer stage coupled to the first PCB and to the second PCB, wherein the first PCB and the second PCB are independently detachable from the power supply.

A liquid coolant tube for a plasma arc cutting torch including a hollow elongated inner body shaped to translate within a hollow elongated outer body. The hollow elongated outer body of the liquid coolant tube is shaped to fixedly connect to the plasma arc cutting torch and includes a set of electrode guides. An external surface of the hollow elongated outer body and the set of electrode guides partially define a set of coolant flow channels between the set of electrode guides. The set of electrode guides are shaped to facilitate alignment of an electrode within the plasma arc cutting torch.

An electromagnetic component assembly disposed in a power source of a welding or cutting system. The electromagnetic component assembly includes a core and a tubular winding. The tubular winding is placed near or around the core and conducts a current for an electromagnetic operation. The tubular winding includes a passageway for a process fluid, an inlet, at one end of the passageway, that receives the process fluid, and an outlet, at another end of the passageway, that directs the process fluid downstream toward a torch assembly. The passageway enhances cooling of the electromagnetic component assembly as the process fluid travels through the passageway from the inlet to the outlet.

Arc saw blades and systems and methods for segmenting components utilizing improved arc saw blades.

A method for profile machining comprises: providing an electrode having an electrode axis, a free axial end with an end face, and a peripheral surface other than the end face; energizing the electrode and a workpiece having a thickness, with one of the workpiece and the electrode as an anode and the other as a cathode; and machining the workpiece with the peripheral surface of the electrode, during which the peripheral surface and the electrode axis of the electrode are across the workpiece in a thickness direction thereof. In addition, an embodiment of present invention relates to a component machined by the method.

A method for profile machining comprises: providing an electrode having an electrode axis, a free axial end with an end face, and a peripheral surface other than the end face; energizing the electrode and a workpiece having a thickness, with one of the workpiece and the electrode as an anode and the other as a cathode; and machining the workpiece with the peripheral surface of the electrode, during which the peripheral surface and the electrode axis of the electrode are across the workpiece in a thickness direction thereof. In addition, an embodiment of present invention relates to a component machined by the method.

Known methods for the mechanical thermal cutting of a workpiece using a plasma cutting torch include the steps of: a) igniting a plasma jet, b) producing a lead-in cut into a metallic, strip- or plate-type semi-finished product using the plasma jet and c) cutting a contour into the semi-finished product by guiding the plasma jet along a predefined contour line at a cutting speed in a cutting direction. Provided herein is such a method which further includes, after cutting the contour according to step c), guiding the plasma jet in the opposite direction to the cutting direction along at least a portion of the cut contour at a return speed, in order to achieve a high cut quality and high dimensional precision.