A welding-type power system that includes an engine and an electric generator driven by the engine. A power bus configured to connect a power output of the electric generator to one or more of a welding-type output, a power storage device, and a switched mode power supply. A plurality of sensors are configured to monitor a plurality of parameters associated with power demand to and from the power bus and generate a signal indicative of the power demand to and from the power bus based on the monitored plurality of parameters. A controller is configured to receive the signal from the plurality of sensors, the controller to control the engine speed in response to the signal or the power demand.

A welding system includes an engine-driven welder generator that produces welding power. A welding torch receives the welding power and applies it to a stick electrode to initiate and maintain a welding arc. A parameter of the welding power, such as voltage, is monitored, such as to determine whether spikes occur during a short time after arc initiation. Based upon the monitored parameter, the engine speed is controlled. The engine speed may be increased or maintained at an elevated level if the monitored parameter indicates that particular types of electrode are being used, such as XX10 or cellulose electrodes.

A system and method for replaceable machine-mounted male input power connections includes a power connection unit that is at least partially arranged within a housing and configured to transfer power received from a power source to drive a welding process. The power connection unit includes an input configured to receive power from the power source, an output configured to deliver the power received at the input to drive the welding process, and a bus system, configured to connect the input and the output. The power connection unit also includes a male connector having a conductive post extending to a threaded cylindrical shaft. The male conductor forms at least a portion of the input or the output and extends from the housing through a coupling assembly. The coupling assembly includes a correspondingly threaded portion configured to engage the threaded cylindrical shaft of the male connector to the bus system.

Welding-type systems and user interfaces having a color display for displaying physical setup instructions are disclosed. Example interface devices include a process selection input device, a display device, a memory, and a processor. The memory stores weld connection setup graphics and physical welding connections. Each of the plurality of weld connection setup graphics is a graphic of a perspective view of a power supply. The processor, in response to identifying a selected welding process type via the welding process selection input device, displays one of the plurality of the weld connection setup graphics via the display device. The processor detects a physical welding connection made at the power supply, determines, based on the detected physical welding connection, that the detected physical welding connection is incorrect for the selected welding process type, and displays an alert on the display device to indicate an error in the detected physical welding connection.

Control panels for welding systems are disclosed. An example power system for a vehicle includes a generator to generate electrical power and to be installed on the vehicle; a first case component configured to be attached to a surface of the vehicle; and a second case component configured to be attached to the first case component to form an enclosure, the second case component comprising: a user control device configured to receive a user input for controlling an output of the generator; and an electrical output configured to output at least a portion of the electrical power generated by the generator.

A stud welding process may be performed by a power supply that is adapted for other welding processes, such as MIG, TIG, and so forth. A stud welding gun may receive studs preloaded in a magazine or other support. Studs are charged into the chuck of a stud welding gun and positioned where desired over a surface. An extension, such as a wire-type electrode may extend from the stud and aid in establishing the welding arc. The stud may be shielded by a nozzle or other shield to obviate the need for ceramic ferrules. Orientation of the stud welding gun may be detected, displayed and used as a basis for initiating and completing the stud welding process once the gun and/or stud is properly positioned.

A hybrid vehicle including a welder that is adapted to be powered off a direct current (DC) bus generated by the electronics of the hybrid vehicle is provided. A variety of exemplary placements of the welder on or in the hybrid vehicle are provided. Additionally, a parallel hybrid configuration, a series hybrid configuration, and a series-parallel configuration including welding converter circuitry that is adapted to utilize the DC bus from the hybrid vehicle to generate welding power are provided.

Embodiments described herein include wireless control of a welding power supply via portable electronic devices, such as dedicated original equipment manufacturer (OEM) welding remote devices, cellular radio telephones, satellite radio telephones, laptops computers, tablet computers, and so forth. In particular, operating parameters and statuses of the welding power supply may be modified by the portable electronic device, as well as be displayed on the portable electronic device. A pairing procedure may be used to pair the welding power supply and the portable electronic device in a wireless communication network. Furthermore, in certain embodiments, a method of providing location services for the welding power supply includes utilizing location data for the portable electronic device controlling the welding power supply as an approximation for the location of the welding power supply.

The subject innovation relates to engine driven welding systems and methods regulating an environmentally controlled electrode compartment within storage constraints to maintain electrode integrity regardless of environmental factors outside the container. Various sensors and controllers which directly or indirectly provide input to the engine of the engine driven welder are used to facilitate such regulation, which is conducted at least in part using the engine itself.

Systems and methods are disclosed for automatically activating or deactivating a gouging torch. In particular, the disclosed systems and methods activate and/or deactivate a gouging torch based on a valve operation selection. For example, for welding power supplies and/or welding wire feeders configured to operate both wire welding processes as well as gouging, a valve can be integrated with a gouging torch, which can be adjusted to allow or arrest the flow of compressed air to the gouging torch. In response, the welding power source and/or welding wire feeder automatically changes one or more output characteristics, to switch between a wire welding process and a gouging process without requiring the operator to interact with either the welding power source or welding wire feeder.