An example welding or cutting circuit includes: an input leg comprising a capacitor coupled between a high bus and a low bus; a buck converter coupled in parallel with the input leg, wherein the buck converter comprises a first transistor, a first diode, and an output electrically coupled to a node between the first transistor and the first diode, and wherein the buck converter is configured to convert input voltage to current in an inductor coupled to the output of the buck converter; and a steering leg coupled in parallel with the input leg, wherein the steering leg is configured to control a rate at which the current in the inductor decreases, and wherein a current detector is positioned at the output to monitor the current, the current detector providing current level indications to a hysteretic controller, the hysteretic controller providing signals to the first transistor that control the transistor to an on state or an off state to control the voltage applied to the inductor

A spark absorbing system for use with a cutting torch, comprises a cap having at least one spark opening therethrough and a spark capture unit coupled to the cap and positioned to capture sparks passing through the spark opening. The spark capture unit may comprise a tube extending from the cap and may include an outlet and a flow-reduction element positioned between the cap and the outlet and/or a spark accumulator between the cap and the spark capture unit. The flow-reduction element may comprise at least one baffle, screen or mesh. The spark absorbing system may further include a spark ramp extending from the cap opposite the spark capture unit and/or a shield, which may define a cutting space between the shield and the cap.

A spark absorbing system for use with a cutting torch, comprises a cap having at least one spark opening therethrough and a spark capture unit coupled to the cap and positioned to capture sparks passing through the spark opening. The spark capture unit may comprise a tube extending from the cap and may include an outlet and a flow-reduction element positioned between the cap and the outlet and/or a spark accumulator between the cap and the spark capture unit. The flow-reduction element may comprise at least one baffle, screen or mesh. The spark absorbing system may further include a spark ramp extending from the cap opposite the spark capture unit and/or a shield, which may define a cutting space between the shield and the cap.

A system and method are provided for using a welding or cutting system that uses a physical key to lock or unlock welding parameters or operations. The key can be used to lock, unlock, store and track welding or cutting information and can be customized as needed.

A system and method are provided for using a welding or cutting system that uses a physical key to lock or unlock welding parameters or operations. The key can be used to lock, unlock, store and track welding or cutting information and can be customized as needed.

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 inverter module, a power transformer, an SiC rectification and smoothing module and a non-contact arc initiation 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 initiation 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.

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 inverter module, a power transformer, an SiC rectification and smoothing module and a non-contact arc initiation 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 initiation 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.

Methods and apparatus for a material cutting system are provided. The system has a table for receiving a work piece. A cutting head cuts the work piece on the table and includes a positioning apparatus. The positioning apparatus moves the cutting head relative to the work piece at an angle relative to a planar surface of the work piece. The material cutting system also includes a computerized numeric controller (CNC) controlling the positioning apparatus. The CNC references a table of values within application software to find a material value and a work piece thickness value within the table to determine the angle from the perpendicular to produce a kerf edge that is formed at a particular angle to the work piece planar surface.

Methods and apparatus for a material cutting system are provided. The system has a table for receiving a work piece. A cutting head cuts the work piece on the table and includes a positioning apparatus. The positioning apparatus moves the cutting head relative to the work piece at an angle relative to a planar surface of the work piece. The material cutting system also includes a computerized numeric controller (CNC) controlling the positioning apparatus. The CNC references a table of values within application software to find a material value and a work piece thickness value within the table to determine the angle from the perpendicular to produce a kerf edge that is formed at a particular angle to the work piece planar surface.

A welding or cutting device includes a first transistor coupled between a first node and a second node. The first transistor controls current and voltage provided to an inductor during a welding or cutting operation. The welding or cutting device also includes a first diode coupled in series with the first transistor between the second node and a third node, and a second diode coupled in parallel with the first transistor and the first diode between the first node and a fourth node. Additionally, the welding or cutting device includes a second transistor coupled in series with the second diode and in parallel with the first transistor and the first diode between the fourth node and the third node. The second transistor controls a voltage applied to a transistor during a freewheeling operation of the inductor. Further, the welding or cutting device includes the inductor arranged between the second node and the fourth node and coupled to a first terminal of an output and a second terminal of the output coupled to the fourth node. Moreover, the welding or cutting device includes a bus capacitor coupled in parallel with the first transistor and the first diode between the third node and the first node.