Patent ID: 7820935
Filing Date: 2010-10-26
Classification: H05H

Abstract:
1. A burner comprising, coaxially disposed in a housing, a tubular electrode, a nozzle having an axial through hole, a removable rod-shaped electrode arranged in a rod-shaped electrode holder coaxially within the tubular electrode and at a gap with respect to said electrode and to the nozzle to enable the formation of a discharge chamber and to enable the axial reciprocating movement, a dielectric tube mounted on the electrode holder, an element for the contact excitation of an electric arc between the nozzle and the rod-shaped electrode, said element being made in the form of an interrupting electric contact and including a mechanism for the axial movement of the rod-shaped electrode, said mechanism having a lead screw, a lead nut, a return spring, a slider and a button, an element for vapour generation and for feeding a plasma-forming medium in the form of vapour of a liquid working medium into the discharge chamber, said element including a reservoir in the form of a thin-wall shell having an end-face wall, a flange and a connection pipe for supplying the liquid working medium, which reservoir being coaxially coupled to the housing and being filled with a liquid-absorbing material to enable the liquid-absorbing material to contact with the tubular electrode and to enable communication of the reservoir with the discharge chamber, a vortex stabilization element of the electric arc, an element cooling the nozzle and the rod-shaped electrode, an element for centering the rod-shaped electrode with respect to the through hole of the nozzle, current leads for electrical connection of terminals of an autonomous electric current source, and a protection enclosure, the end-face wall is made with a sealed central opening, the flange is made in the form of a connection fitting and is provided with a partition having a central opening, in which opening the tubular electrode is positioned to enable the formation of a heating element that comprises an evaporator and a vapour superheater, both being separated by the partition, the evaporator disposed in the reservoir has a length within the range of 1.8-3.0 of its outer diameter and is provided, on its surface, with grooves for discharging vapour into a collector out of an annular recess on a surface of the vapour superheater arranged outside the reservoir and also with a capillary-porous shell made of a material of high thermal conductivity and arranged to enable its one side to contact with a surface of the evaporator and its other side to contact with the liquid-absorbing material of low thermal conductivity, the housing is made in the form of a sleeve, one of whose ends has a thread to be connected to the flange to enable pressing the nozzle and the tubular electrode against the partition, the electric arc vortex stabilization element is made in the form of a swirler being a part of the vapour superheater, said part being adjacent to the nozzle, and comprises tangential channels provided in the swirler and disposed in two planes perpendicular to the axis, a distance between said channels being 0.5-1.3 of a maximum value of a diameter of the discharge chamber's inner cavity, bores along the inner diameter are made in the swirler and the vapour superheater at both sides of their connection point, the dielectric tube is made with an inner cylindrical surface and an outer single-step cylindrical surface to form a cylindrical jut, and is arranged to enable mutual centering of the swirler, the tubular electrode and the dielectric tube with respect to the cylindrical jut, and projects in the reservoir beyond an end-face of the tubular electrode at least to a distance equal to 0.5 of its outer diameter, the dielectric tube end-face that faces the hole of the nozzle is positioned to form an end-face of the discharge chamber which is of the confuser type and has a length within the range of 0.5-1.8 of the maximum diameter value of its inner cavity, the lead screw is fixedly positioned along the axis of the rod-shaped electrode in the end-face wall and is made with a central single-step cylindrical opening to form a cavity having an end-face annular support surface that interacts with the return spring, and having a radial slot along an axis of the lead screw, wherein a length of the slot corresponds to a travel value of the reciprocating movement of the rod-shaped electrode, the spring-loaded slider is made in the form of a cylinder having a radial hole and is disposed in the cavity of the lead screw with one of the end-faces being supported by the return spring and to be capable of the axial reciprocating movement limited by the current lead shaped as a pin positioned in the slider's radial hole to be capable of fixation and disposed in the slot of the lead screw, the other slider's end-face projects out of the cavity of the lead screw, the lead nut is coupled, by a thread, to the lead screw to enable the interaction by its annular end-face support surface with the pin-shaped current lead that projects radially from the slot of the lead screw, the slider's end-face projecting from the cavity of the lead screw is provided with the button extending from the lead nut's central hole so that to be capable of the axial reciprocating movement, the slider is connected to the electrode holder that is made at the side of connection with the rod-shaped electrode to have a diameter within the range of 1.01-1.25 of a diameter of the rod-shaped electrode, and to have a developed heat-exchange surface along the length at least between the dielectric tube end-face in the reservoir and the end-face wall, such that to enable centering of the lead screw's cavity and the dielectric tube's inner cylindrical surface along the cylindrical surface, wherein the diameter of the rod-shaped electrode is within the range of 0.27-0.83 of a maximum diameter value of the discharge chamber's inner cavity, a lateral dimension of the reservoir in the evaporator's zone is 1.7-3.2 of the evaporator's outer diameter, a length of the reservoir is selected within the range of 1.5-3.5 of the length of the evaporator, and a ratio of the total cross section area of the grooves on the evaporator's surface to the total area of pass-through sections of the tangential channels is 0.7-1.5.