An output control for a welding-type power supply includes a first contactor associated with a first weld output range. A second contactor associated with a second weld output range. An input device configured to select a weld output value from the first weld output range and the second weld output range. A control circuit configured to control the first contactor and the second contactor based on a selected weld output value, and adjust a weld output based on the selected weld output value of the input device.

A method and apparatus for providing a welding type power using a welding power circuit having a control input and a welding type power output, a feedback circuit and a controller connected to the control input and the feedback circuit is disclosed. The controller includes a parameter setting module and/or a process selection module that are connected to and responsive to at least one of the feedback circuit. The a process selection module can be responsive to the parameter setting module.

An arc welding device is provided with including: a wire feed motor; a rocker arm attached freely rotatably to an output shaft of the wire feed motor; a pair of wire feed rollers attached to the rocker arm; a rotation transmitting mechanism for transmitting the rotation of the wire feed motor to the wire feed roller; a rocker drive unit; and a welding power supply unit. The wire feed roller has inserted therein welding wire disposed along the rocking direction of the rocker arm. The welding wire is fed towards a torch tip by the wire feed roller, and arcing and shorting can be repeated with forward and backward movement by the rocker arm in the direction of the wire feed.

An output control for a welding-type power supply includes a first contactor associated with a first weld output range. A second contactor associated with a second weld output range. An input device configured to select a weld output value from the first weld output range and the second weld output range. A control circuit configured to control the first contactor and the second contactor based on a selected weld output value, and adjust a weld output based on the selected weld output value of the input device.

The present invention provides an SiC inverted plasma cutting power supply, which is characterized in that: the SiC inverted plasma cutting power supply comprises a main circuit and a closed-loop control circuit; the main circuit comprises a sequentially connected noise suppression module, a power-frequency rectification and filtering module, an SiC inverted commutation module, a power transformer, an SiC rectification and smoothing module and a non-contact arc striking module, wherein the noise suppression module is connected to an alternating-current input power supply, and the SiC rectification and smoothing module and the non-contact arc striking module are respectively connected to a load; the closed-loop control circuit comprises a man-machine interaction module, a DSC controller, a failure diagnosis and protection module, an SiC high-frequency drive module and a load electrical signal detection module. The power supply has high inverting frequency, small size, light weight, lower raw material consumption, high energy efficiency, an obvious energy saving effect and excellent dynamic characteristics, and can be applied on both a low-power occasion and medium and high power cutting occasions in a stable and reliable manner.

In thin sheet welding, when a heat input amount relative to a sheet thickness is too large, a welding defect such as a deviation from aim due to occurrence of a strain or burn through may easily occur. When a welding current is decreased to reduce the heat input amount, there is an issue in which an arc tends to become unstable. In arc welding in which short-circuit and arcing are repeated, first heat input period (Th) and second heat input period (Tc) having a heat input amount less than that of first heat input period (Th) are periodically repeated and a welding current during an arc period in second heat input period (Tc) is decreased to extinguish the arc. This reduces the heat input amount into a welding object and suppresses burn through or a strain upon welding, while making the arc stable.

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.

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.

In thin sheet welding, when a heat input amount relative to a sheet thickness is too large, a welding defect such as a deviation from aim due to occurrence of a strain or burn through may easily occur. When a welding current is decreased to reduce the heat input amount, there is an issue in which an arc tends to become unstable. In arc welding that repeats short-circuit and arcing, first heat input period (Th) and second heat input period (Tc) having a heat input amount less than that of first heat input period (Th) are periodically repeated. This reduces the heat input amount into a welding object and suppresses burn through and a strain upon welding while making the arc stable.

Embodiments of systems and methods to relate welding wire to a welding power source are disclosed. One embodiment is a wire docking station for use in a welding environment. The wire docking station includes a loading platform configured to accept a replaceable source of consumable welding wire, and a scale configured to generate a weight status of the source of consumable welding wire when docked with the loading platform. The wire docking station also includes a communication module and a contact mechanism configured to form an electrical connection between the source of consumable welding wire and the communication module. The communication module includes a transmitter configured to transmit docking station data as current draw pulses to a welding power source over the consumable welding wire of the source of consumable welding wire.