A system includes an engine configured to drive a generator to produce a first power output, and a first inverter communicatively coupled to the generator. The first inverter is configured to convert the first power output into a second power output. The system includes a second inverter communicatively coupled to the generator. The second inverter is configured to convert the first power output into a third power output. The third power output includes a welding power output.

An engine-driven welding power supply, comprising a frame, an engine attached to the frame, and a generator attached to the frame. The generator is driven by the engine and configured to output electrical power via an electrical receptacle. Weld power conversion circuitry is integrally attached to the frame and configured to output welding-type power. A power conductor configured to provide input power to the weld conversion circuitry is configured to be manually coupled to the electrical receptacle or to an external source of electrical power. The weld power conversion circuitry is configured to convert the input power received via the power conductor to welding-type power.

A welding system includes a frame having a first sliding track and a second sliding track. The welding system also includes a cover piece having a first set of tabs configured to slide within the first sliding track, and a second set of tabs configured to slide within the second sliding track. The first and second sets of tabs are disposed on opposite sides of the cover piece. The cover piece includes an indention configured to mate with a detent protruding from a fan louver of the frame when the cover piece is slid into an open position. In addition, the welding system includes a plurality of electrical connections. The cover piece substantially covers the plurality of electrical connections when the cover piece is slid into a closed position within the sliding tracks, and the plurality of electrical connections are entirely exposed when the cover piece is slid into the open position within the sliding tracks.

A welding system includes an enclosure frame. The welding system also includes a side panel having a tab extending along a bottom edge of the side panel. The tab is configured to mate with a complementary slot in the enclosure frame.

A welding system includes power conversion circuitry configured to convert input power to weld power and a first housing surface. The first housing surface includes a first mating geometry configured to mate with a first complementary geometry of a first modular surface of a first modular component of the welding system.

Apparatus and methods are disclosed of a welding-type system includes a welding-type power supply configured to provide welding-type power. A reel located within a housing of the welding-type power supply. A welding-type cable, the reel configured to wind the welding-type cable to reduce a length of the welding-type cable extending from the housing, and to unwind to increase a length of the welding-type cable extending from the housing at least partially wound around the reel when stored. The welding-type cable includes a first end secured to the reel and electrically connected to the welding-type power supply and a second end configured to provide the welding-type power to at least one welding-type tool.

A welding system includes power conversion circuitry configured to convert input power to weld power and a first housing surface. The first housing surface includes a first mating geometry configured to mate with a first complementary geometry of a first modular surface of a first modular component of the welding system.

A system includes an engine configured to drive a generator to produce a first power output, and a first inverter communicatively coupled to the generator. The first inverter is configured to convert the first power output into a second power output. The system includes a second inverter communicatively coupled to the generator. The second inverter is configured to convert the first power output into a third power output. The third power output includes a welding power output.

The invention relates to a welding assembly for the permanent joining of a first tubular component with a second component along a two- or three-dimensional intersection curve, along which both components contact, comprising a securing assembly for detachably securely joining on a tubular end of the first component facing away from the intersection curve, a manipulator unit mounted directly or indirectly on the securing assembly such that it can pivot about a tube longitudinal axis assigned to the first component. The manipulator unit has a freely positionable manipulator end, with a welding tool attached to the freely positionable manipulator end. The securing assembly comprises a clamping module that can at least partially be introduced into the tubular end of the first component on the end side and in an axial manner. The clamping module is detachably securely to a tube inner wall of the first tubular component, as well as a carrier ring module which is rotatably attached to the clamping module, which axially extends beyond the tubular end of the first tubular component.

A system includes an engine configured to drive a generator to produce a first power output, and a first inverter communicatively coupled to the generator. The first inverter is configured to convert the first power output into a second power output. The system includes a second inverter communicatively coupled to the generator. The second inverter is configured to convert the first power output into a third power output. The third power output includes a welding power output.