The present invention relates to a plasma-generating device, comprising an anode, a cathode and at least one intermediate electrode, said intermediate electrode being arranged at least partly between said anode and said cathode, and said intermediate electrode and said anode forming at least a part of a plasma channel which has an opening in said anode. Further, the plasma-generating device comprises at least one coolant channel which is arranged with at least one outlet opening which is positioned beyond, in the direction from the cathode to the anode, said at least one intermediate electrode, and the channel direction of said coolant channel at said outlet opening has a directional component which is the same as that of the channel direction of the plasma channel at the opening thereof. The invention also concerns a plasma surgical device and use of such a plasma surgical device.

In some aspects, methods for controlling a plasma arc in a plasma torch of a plasma cutting system in a low operating current mode can include: receiving, by a computing device within the plasma power supply, a command to begin a plasma processing operation; generating a pilot arc command to generate a pilot arc within the plasma torch, the generating of the pilot arc command including directing an electrical signal and a gas flow to the plasma torch, the electrical signal being configured to generate the pilot arc at a current having a first arc amperage magnitude; and generating an operational arc command to facilitate a transition from the pilot arc to an operational plasma arc, the generating of the operational arc command including adjusting the current directed to the plasma torch to be a second arc amperage magnitude that is lower than the first arc amperage magnitude.

In some aspects, methods for controlling a pneumatic system in a plasma arc processing system can include: receiving, by a computing device, a command to begin a plasma processing operation; generating a valve command signal for a valve that includes an operational drive voltage of at least about 125% of a continuous duty cycle coil voltage rating of the valve to open the valve; and once open, adjusting the valve command signal to facilitate a steady state operation to: monitor a steady state operational duty cycle of the valve, the steady state operational duty cycle being determined by comparing the continuous duty cycle coil voltage rating of the valve to an actual operational drive voltage supplied to the valve, and control the operational drive voltage supplied to the valve to maintain a steady state operational duty cycle of the valve at less than about 60% during steady state operation.

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.

A process for producing a layer or a body built up of layers. A process gas which has a pressure of >10 bar is accelerated in a convergent-divergent nozzle and a coating material which is formed by particles and is composed of Mo, W, an Mo-based alloy or a W-based alloy is injected into the process gas. The particles are at least partly present as aggregates and/or agglomerates. It is possible to produce dense layers and components in this way. We also describe layers and components having a microstructure with cold-deformed grains having a high aspect ratio.

A nozzle assembly includes an upper portion defining an opening for receiving a gas and a longitudinally extending cylindrical body portion adjacent to the upper portion and defining a passageway for the gas. The nozzle assembly also includes a tip portion adjacent to the body portion, with the tip portion defining a throat channel. The throat channel includes a throat inlet region that focuses a flow of the gas. The throat inlet region is fluidly connected to the passageway via a throat inlet opening. The throat channel also includes an acceleration region that is disposed downstream of the throat inlet region and fluidly connected to the throat inlet region to compress the gas and accelerate the flow of the gas. The throat channel further includes an expansion region disposed downstream of the acceleration region and fluidly connected to the acceleration region to allow the gas to expand.