An apparatus for the destruction of a precursor material includes a steam plasma reactor having a high temperature zone and a combustion zone. The high temperature zone is adapted for hydrolyzing the precursor material, whereas the combustion zone is adapted to effect medium temperature oxidation of the reactant stream where combustion oxygen or air is injected. A quenching unit is provided at an exit end of the reactor for quenching a resulting gas stream to avoid the formation of unwanted by-products.

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.

A multi-electrode plasma torch (10) a rear electrode (100), a front electrode (200), and a plurality of electrode plates (300) disposed between the rear electrode and front electrode. Among the plurality of electrode plates is an auxiliary electrode plate (400), adjacent to the rear electrode and with a polarity opposite to a polarity of the rear electrode. A power supply unit (500) is connected between the rear electrode and the auxiliary electrode plate for supplying power.

A plasma spraying device includes a torch head which has a plasma channel that extends between a cathode and an anode. The plasma channel is bounded by a plurality of neutrodes which are electrically insulated from each other. A gap extends between the frontmost neutrode and the anode, which gap is divided into at least two sections. There is a radial distance and an axial distance between the two sections. An insulating disk is arranged in each of the two sections.

The present invention is directed at a plasma torch and methods of plasma spraying wherein the delivery of plasma and spray material occurs at extended locations from the anode arc root attachment. Relatively high specific power and relatively high enthalpy plasmas are employed along with a plasma extension module to deliver a plasma spray at a remote location with a minimum enthalpy value.

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.

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.

Systems, devices, and methods generating a plasma flow are disclosed. A method may include applying energy that alternates between being at a base level for a first duration and at a pulse level for a second duration according to a controlled pattern, generating a plasma flow having a directional axis, and discharging the plasma flow alternating between a base configuration and a pulse configuration according to the controlled pattern. The plasma flow in the base configuration may have (1) a first temperature at the outlet and (2) a first flow front that advances along the directional axis. The plasma flow in the pulse configuration may have (1) a second temperature at the outlet that is greater than the first temperature and (2) a second flow front that advances along the directional axis at a speed greater than the first flow front.

The present disclosure discloses a thermal plasma treatment method for sulfur hexafluoride (SF.sub.6) degradation. In the thermal plasma treatment method for SF.sub.6 degradation, Ar is input into a thermal plasma generator as a carrier gas; annular electrodes are electrically connected to a direct current power supply to generate an arc plasma region in the presence of the carrier gas Ar; to-be-reacted SF.sub.6 and to-be-reacted H.sub.2 in a predetermined ratio are input into the arc plasma region to generate hydrogen radicals as well as fluorine radicals, and the hydrogen radicals and the fluorine radicals are bonded with each other to generate HF to inhibit the self-recovery reaction of SF.sub.6; and final products include HF and elemental S.

A high velocity plasma spray method and apparatus with relatively high plasma pressures of 3 bars or above. The preferable range of plasma pressure is 3 bars to 10 bars and a plasma enthalpy of preferably 10 KJ/g or above. The preferable enthalpy range is above 10 KJ/g and up to 20 KJ/g and the preferred specific power (?) is in the range of 16 KJ/g to 33 KJ/g.