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.

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 method of keeping a scriber tip clear of ablated material that uses an ablation scriber head constructed in accordance with the teachings of the method. The ablation scriber head directs pressurized gas at the scriber tip to keep the scriber tip clear of ablated material. It is preferred that the pressurized gas contains an oxidizing agent which oxidizes the ablated material.

A method of keeping a scriber tip clear of ablated material that uses an ablation scriber head constructed in accordance with the teachings of the method. The ablation scriber head directs pressurized gas at the scriber tip to keep the scriber tip clear of ablated material. It is preferred that the pressurized gas contains an oxidizing agent which oxidizes the ablated material.

A method for determining operating parameters to process a workpiece using a manufacturing processing system including a plasma arc gouging torch. The method includes positioning a plasma arc gouging torch at a location relative to a workpiece and determining a start point and an end point for each gouging path based on the location and a gouge profile. The method further includes using the gouging profile to determine first operating parameters for the plasma arc gouging torch for a first gouging path and determining second operating parameters for the plasma arc gouging torch for a second gouging path based on the gouge profile and the first gouging path. The second operating parameters include at least one of a second torch speed or a torch offset. The method also includes using at least one of the first or second operating parameters to process the workpiece with the plasma arc gouging torch.

A method for determining operating parameters to process a workpiece using a manufacturing processing system including a plasma arc gouging torch. The method includes positioning a plasma arc gouging torch at a location relative to a workpiece and determining a start point and an end point for each gouging path based on the location and a gouge profile. The method further includes using the gouging profile to determine first operating parameters for the plasma arc gouging torch for a first gouging path and determining second operating parameters for the plasma arc gouging torch for a second gouging path based on the gouge profile and the first gouging path. The second operating parameters include at least one of a second torch speed or a torch offset. The method also includes using at least one of the first or second operating parameters to process the workpiece with the plasma arc gouging torch.

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.

The present disclosure relates to aluminum production, more particularly, to a method of breaking an electrolyte crust in reduction cells of all types. According to a disclosed method for breaking electrolyte crust by means of separation cutting in a reduction cell for production of aluminum, the crust is cut and broken by means of the thermal melting of a crust material with a high-speed high-temperature concentrated flow of thermal plasma jet heat energy, for which a directed thermal plasma jet is generated and moved above the electrolyte crust along a predetermined path, a formed molten material is continuously removed from a zone of the thermal plasma jet impact to create in the electrolyte crust a slit with the thermal plasma jet, wherein the slit is enough for of crust continuous separation cutting and breaking. The technical effect in the addressing the mentioned object, reduction of the amount of broken electrolyte crust, avoiding the formation of electrolyte crust pieces during the breakage process and, consequently, reduction of power consumption for heating-up the covering material consisting of a mixture of alumina and crushed electrolyte used to form an electrolyte crust.