Systems and methods for an adjustable user interface for a wire feeder are provided. In some examples, welding power supplies, welding accessories, and/or welding wire feeders and welding wire feeder systems are equipped with one or more user interfaces adaptable to change position, orientation, or location, relative to a housing or support on which the user interface is secured. The adaptable user interfaces may be secured to a mount (e.g., an enclosure, a case, a surface, etc.) via one or more fasteners (e.g., screws, bolts, magnets, straps, snap-fit, detents, pins, etc.). For example, the fasteners may create a non-permanent joint between the user interface and the mount, such that the position, orientation, or location user interface may be adapted for a desired application.

Systems and methods are disclosed for integrated compressed air cooling for welding systems. In particular, the disclosed systems and methods may employ compressed air to implement one or more welding processes (e.g., a gouging or cutting processes), with the compressed air being conveyed through such welding systems. In some examples, the compressed air is routed within the welding system to provide cooling for one or more components therein. For instance, components such as power conversion circuitry may heat up during the welding process. Routing compressed air to or near the components will introduce relatively cool air to the environment. As the passing compressed air heats in response to interaction with the heated components, heat is drawn from the components and/or the nearby environment.

In a consumable electrode-type arc welding in which pulse welding and short-circuit welding are alternately repeated, a welding current is controlled such that a welding current immediately before shifting from the pulse welding to the short-circuit welding is lower than a base current in a pulse.

An example engine-driven power system includes: an engine; a generator configured to convert mechanical engine power to electrical power; first and second power subsystems configured to convert the mechanical or electrical power to first and second power outputs, wherein the first and second power subsystems are configurable to output the first and second power outputs simultaneously; an input device configured to control a load management priority, wherein the load management priority comprises at least one of an adjustable ranking, an adjustable balance, or bus voltage thresholds; and control circuitry configured to: control the first and second power subsystems to output the first and second power outputs based on first and second demands; and, in response to determining that a total demand exceeds a capacity, control the first or second power subsystems to reduce the power outputs or the demands based on the load management priority.

Power systems and enclosures having improved cooling air flow are disclosed. In some examples, a power system includes an enclosure, a first air inlet, a first air routing path, and a second air routing path. The first air inlet is at a first location on an exterior of the enclosure to permit intake of air from the exterior of the enclosure to an interior of the enclosure. The first air routing path is defined by the enclosure and directs air from the first air inlet through a welding-type power supply and a compressor. The second air routing path is separate from the first air routing path and defined by the enclosure. The second air routing path directs the air from the first air inlet or a second air inlet through at least one of an engine or a generator.

A welding or cutting system having a power supply with no user interface hardware or software for controlling the operation of the power supply, and a mobile communication device which contains an application allowing for control of the power supply. The mobile device is coupled to the power supply through either a wired or wireless connection.

A method and apparatus for welding is disclosed. The output is preferably a cyclical CV MIG output, and each cycle is divided into segments. An output parameter is sampled a plurality of times within one or more of the segments. The CV output is controlled within the at least one segment in response to the sampling. The parameter is output power, a resistance of the load, an output current, an output voltage, or functions thereof in various embodiments. The control loop is preferably a PI or PID loop. The loop may be applied only within a window. The set point may be taught or fixed. The system can be used to weld with a controlled arc length.

High-frequency transformers using solid wire for welding-type power supplies are disclosed. An example welding-type power supply transformer includes: a first coil assembly comprising a first plurality of turns of a first solid wire wrapped around a first bobbin to form a first single-layer primary winding, and a second plurality of turns of a second conductor over the first plurality of turns to form a first single-layer secondary winding; a second coil assembly comprising a third plurality of turns of a second solid wire wrapped around a second bobbin to form a second single-layer primary winding, and a fourth plurality of turns of the second conductor over the third plurality of turns to form a second single-layer secondary winding; and first and second cores disposed at least partially within the first and second bobbins.

An arc welding system includes a welding power supply. An auxiliary power supply supplies electrical energy to an auxiliary load. An engine-generator is connected to the welding power supply and auxiliary power supply. An engine starting battery is connected to the auxiliary power supply to supply electrical energy thereto during starting of the engine-generator. An auxiliary load sensor is configured to detect a presence of an electrical load on the auxiliary power supply. A speed sensor is configured to sense a speed of the engine-generator. A controller is configured to receive a signal indicating presence of the electrical load on the auxiliary power supply and a signal corresponding to speed of the engine-generator. When presence of the electrical load on the auxiliary power supply is detected, the controller starts the engine-generator, and after the engine-generator has reached a predetermined speed, switches the auxiliary power supply from the battery to the engine-generator.

The invention described herein generally pertains to a system and method for a welding device and, in particular, a hybrid welding device, that leverages a renewable energy source for a source of electrical current. The welding device can include one or more renewable energy kits that harvest renewable energy sources for performing a welding operation or a powering at least one of a device or component external to the welding device. The welding device includes renewable energy component that collects an input to convert to an electrical current that can be used as a replacement current, a supplemental current, or a complimentary current.