Abstract: A nozzle for a plasma arc cutting torch includes a substantially hollow, elongated body capable of receiving an electrode. The nozzle body defines a longitudinal axis and has a length along the axis from a first end of the nozzle body to a second end of the nozzle body. The nozzle also includes a plasma exit orifice disposed at the first end of the body. The first end of the nozzle body has a width and a ratio of the length of the nozzle body to the width of the nozzle body is greater than about 3.

Abstract: A nozzle or retaining cap for a plasma arc torch that includes a surface defining a conductive contact portion for exchanging heat with an adjacent torch component. The adjacent torch component can be a retaining cap, electrode or nozzle. The surface of the nozzle or retaining cap can also at least partially define a cooling channel having a curvilinear surface. A sealant portion can be positioned between the conductive contact portion and the cooling channel. The sealant portion can form or create a fluid barrier between the cooling channel and the conductive portion.

Abstract: A nozzle, retaining cap, or shield for a plasma arc torch that includes a surface defining a conductive contact portion for exchanging heat with an adjacent torch component. The adjacent torch component can be a retaining cap, electrode or nozzle. The surface of the nozzle, retaining cap, or shield can also at least partially define a cooling channel having a curvilinear surface. A sealant portion can be positioned between the conductive contact portion and the cooling channel. The sealant portion can form or create a fluid barrier between the cooling channel and the conductive portion.

Abstract: A liquid-cooled consumable cartridge for a plasma arc torch is provided. The cartridge includes (i) an electrode, (ii) a swirl ring with a first outer retaining feature and a second outer retaining feature on an exterior surface, where the electrode is secured to the swirl ring, and (iii) a nozzle with an inner retaining feature on an interior surface, where the inner retaining feature of the nozzle is mated with the first outer retaining feature of the swirl ring. The cartridge also includes a cartridge frame with an inner retaining feature on an interior surface and an outer retaining feature on an exterior surface. The inner retaining feature of the cartridge frame is mated with the second outer retaining feature of the swirl ring. The cartridge further includes a shield with an inner retaining feature on an interior surface mated with the outer retaining feature of the cartridge frame.

Abstract: A nozzle for a plasma arc torch is provided. The nozzle includes a substantially hollow, elongated nozzle body capable of receiving an electrode, the body defining a longitudinal axis, a distal end, and a proximal end. The nozzle also includes a swirl sleeve attachable to an interior surface of the nozzle body, the swirl sleeve configured to impart a swirling motion to a gas introduced to the nozzle. The nozzle additionally includes a nozzle tip connected to the proximal end of the nozzle body, a nozzle shield, and an insulator configured to connect the nozzle tip and the nozzle shield to electrically insulate the nozzle shield and the nozzle tip from one another while transferring thermal energy therebetween.

Abstract: A nozzle of a plasma arc torch is provided. The nozzle is configured to reduce fluid pressure surging in a nozzle plenum. The nozzle comprises a nozzle body having a proximal end and a distal end. The nozzle plenum is defined between the nozzle body and an electrode of the plasma arc torch. The nozzle includes a nozzle plenum gas inlet located at the proximal end of the nozzle body, a plasma gas exit orifice located at the distal end of the nozzle body, a plasma gas passageway fluidly connecting the nozzle plenum gas inlet to the plasma gas exit orifice, and an isolation chamber fluidly connected to the plasma gas passageway and the nozzle plenum. The isolation chamber is sized to receive a volume of substantially stagnant gas to reduce the fluid pressure surging in the nozzle plenum.

Abstract: A method of operating a plasma arc torch system is provided. A first plasma gas supply source, a second plasma gas supply source, and a control unit are provided. A first plasma gas composition is flowed through a first plasma gas flow path, and a plasma arc is generated using the first plasma gas composition. After arc generation, the plasma gas composition is changed to a second plasma gas composition, and the plasma gas flow path is changed to a second plasma gas flow path, wherein the second plasma gas flow path is different from the first plasma gas flow path. The plasma arc is sustained using the second plasma gas composition. The first and second plasma gas flow paths are both at least partially disposed within the plasma arc torch.

Abstract: A plasma arc torch which includes a torch body having a nozzle mounted relative to an electrode in the body to define a plasma chamber. The torch body includes a plasma flow path for directing a plasma gas to the plasma chamber in which a plasma arc is formed. The nozzle includes a hollow, body portion and a substantially solid, head portion defining an exit orifice. The torch also includes a shield attached to the torch body. The shield has a head portion and a body portion which defines a shield exit orifice that has an inlet and an outlet. The shield exit orifice is dimensioned such that the head portion of the nozzle extends, at least in part, to a position between the inlet and the outlet of the shield exit orifice. This configuration produces a substantially columnar flow of shield gas that does not substantially interfere with the plasma arc and prevents a substantial portion of splattered molten metal produced during marking or cutting of the workpiece from reaching the nozzle.