RU2313727C1 - Infra-red irradiation gas burner - Google Patents

Abstract

FIELD: gas burners for heating devices of different designation used in different branches of technology and industry and using heat of combusted gases.

SUBSTANCE: changeable IR-irradiation gas burner includes housing in the form of carcass of non-detachably joined one to other upper and lower tubular members with mutually communicating through cavities. In carcass seats for main and additional sections are formed. In seat of each section burner nozzle is arranged. Seats of carcass are connected through diffusers of mixers with ejector in zone for dispensing gas-air mixture. Each burner nozzle is in the form of gas permeable plate made of fiber members placed onto latticed carcass and made of refractory and heat resistant material for forming open three-dimensional porosity in the form of through labyrinth ducts. Gas jet is mounted on gas supplying branch pipe and it is embraced by front portion of ejector. Front portion (along feed direction of natural gas) of ejector is provided with air intake and with air supply regulator. On lower tubular members of carcass along their perimeter, embracing ejector and fluid-tight air conduit in the form of detachable casing connected with atmosphere air are mounted. Cavity of detachable casing is communicated with air intake of ejector and with through cavities of upper and lower tubular members of carcass.

EFFECT: improved design of gas burner.

3 cl, 3 dwg

Description

The invention relates to gas burners for heating devices for various purposes, used in various fields of technology and industry and using the heat of combusted gases.

It is known from US patent No. 5.326.631, CL. F23D 14/12, 1993, a device for converting the combustion energy of hydrocarbons in the gaseous phase into infrared energy, comprising a matrix of sintered metal and ceramic fibers with a bonding agent, forming a porous structure.

The disadvantages of the above technical solution are the small range of stable operation and the small regulation range, due to the danger of flame penetration at the periphery of the matrix (where the air-gas mixture velocity is minimal) while lowering the initial pressure of hydrocarbons in the gaseous phase and changing operating modes.

Closest in its technical essence to the proposed radiation gas burner of infrared radiation is known from the patent of the Russian Federation No. 2193731, cl. ⁶ F23D 14/12, 2002, an infrared radiation gas burner containing at least one interchangeable burner nozzle in the form of a supporting grid frame and a layer of fibers of heat-resistant and heat-resistant material with open volume porosity in the form of through labyrinths channels, placed in its enclosure, connected to a gas nozzle mounted on the inlet pipe through the last ejector enclosing the latter with an air intake having an air supply regulator, and a gas-air mixer mixture, in the diffuser of which there is a gas-air divider convex towards the oncoming jet.

The disadvantages of the above infrared radiation gas burner are its low specific heat and energy characteristics, its unstable operation in heat-stressed units with limited possibilities of heat removal from the burner structural elements, which initiates overheating of the burner elements and the effect of flamethrough.

The objectives of the invention are to increase the efficiency, reduce heat loss, intensify heat transfer processes and increase reliability.

The solution of these problems is achieved by the fact that the radiation gas burner of infrared radiation, containing at least one replaceable burner nozzle in the form of a supporting grid frame and a layer of fibers of heat-resistant and heat-resistant material with open volume porosity in the form of through labyrinth channels, placed in its enclosing body connected to a gas nozzle mounted on the inlet pipe through the last ejector enclosing the latter with an air intake having a flow regulator air, and a gas-air mixer, in the diffuser of which a gas-air divider is convex towards the incoming jet, it is equipped with an air blower with an air duct in the form of a housing with an ejector of a removable trough-like casing, and made of a series of main and additional sections arranged in series, the housing in the form formed from the upper and lower tubular elements inseparably connected to each other with through channels of the frame with sockets communicating with each other, in each of which a removable burner nozzle of one of the sections, arranged with a fringing, is placed, carrying a lattice frame of each of the mentioned nozzles - from interwoven and forming cell elements with a profiled cross section, the cavity of the trough-like removable casing communicating with the ejector intake and through channels of the tubular frame elements, and the thickness H of each said nozzle is 0.05-0.20 of its length L, while the dimension d of the profiled cross section of the elements forming the supporting lattices th frames of said nozzles, and the size h of each last cell scaffolds are respectively 0.2-1.0 and 0.01-0.1 thickness H of the previously mentioned nozzles.

In addition, the radiation gas burner of infrared radiation can be made cooled, and the fringing of each replaceable burner nozzle from the shells covering the latter around the perimeter and connected with each other by an integral connection of the upper and lower shells with a Z-shaped cross-section, and the height t of the edging is 0.8 -0.9 thickness H replaceable burner nozzle.

The invention is illustrated by drawings: where in Fig.1 schematically shows a General view of a burner with a radiation gas burner of infrared radiation in section; figure 2 is a cross section of figure 1; figure 3 schematically shows a General view of the burner nozzle in section; figure 4 is a transverse section of figure 3 on an enlarged scale.

The infrared radiation gas burner consists of a casing in the form of a rectangular frame 1 of the upper 2 and lower 3 tubular elements indivisibly connected to each other with communicating through cavities 4. In the rectangular frame 1, sockets 5 are arranged in series of the main and additional sections. In the nest 5 of each section, a replaceable burner nozzle is placed 6. The nests 5 of the rectangular frame 1 are connected by means of mixers, in the sockets of the diffusers 7 of which are convex dividers 8, which are convex towards the incoming jets of the air-gas mixture, hermetically with the ejector 9 at the gas-air distribution section. Each replaceable burner nozzle 6 is made in the form of a rectangular gas-permeable plate made of elements 11 with profiled cross-section laid on a lattice frame 10 made of interlaced and forming cells, and connected in a single fiber 12 from heat-resistant and heat-resistant material with the formation of open volume porosity in the form of through labyrinths channels 13. A gas nozzle 14 is installed on the gas inlet pipe 15 and is covered by the front part of the ejector 9 for supplying natural gas 9. The front one along the natural gas supply the part of the ejector 9, intended for the formation of the gas-air mixture, is equipped with an air intake 16 and a regulator 17 for supplying atmospheric air. On the lower tubular 2 elements of the rectangular frame 1, a permeable ejector 9 and a sealed air duct connected to a supercharger 18 of atmospheric air are installed in the form of a removable trough-shaped casing 19. The cavity 20 of the trough-like removable casing 19 communicates with the air intake 16 of the ejector 9 and the through cavities 4 of the upper 2 and the lower 3 tubular elements of the rectangular frame 1. The thickness H of each mentioned nozzle 6 is 0.05-0.20 of its length L. The dimension d of the profiled cross section of the elements 11 forming no uschie latticed frames 10 of said nozzles 6 and the size of each cell 10 h last grid bodies are respectively 0.2-1.0 and 0.01-0.1 thickness H of the previously mentioned nozzles 6.

The replaceable radiation gas burner of infrared radiation operates as follows. The atmospheric air blower 18 is turned on and natural gas is supplied from the gas supply pipe 15 of the manifold to the gas nozzle 14. A gas jet flowing out of the latter ejects atmospheric air coming from the atmospheric air blower 18 through a sealed duct in the form of a cavity 20 formed between the rectangular frame 1 and a trough-like removable casing 19, and directs it through the air intake 16 into the ejector 9 to form a gas-air mixture. The gas-air mixture formed in the ejector 9 enters through the channels 21 of the distribution section of the gas-air mixture of the ejector 9 into the bells of the diffusers 7 of the main and additional sections, where the velocity field along the cross section of the gas-air mixture stream is leveled, and the convex divider 8 distributes the gas-air mixture stream evenly over the area of the burner nozzle 6, located in the slot 5 of the rectangular frame 1. In the socket of the diffuser 7 of the mixer of each section also provides the restoration of the pressure of the gas-air mixture necessary to overcome resistance when it flows through the labyrinth channels 13 of the gas-permeable plate of the replaceable burner nozzle 6. In the front part along the direction of the jet of gas-air mixture through the labyrinth channels 11 of the gas-permeable plate of the replaceable burner nozzle 6, the mixing and heating of the gas-air mixture to the ignition temperature ends. As a result of combustion of the gas-air mixture in the volume of through labyrinth channels 11 in the near-surface zone with a height of 1.5-2.0 mm of the front part (in the direction of the gas-air mixture) of the replaceable burner nozzle 6, the surface layer of fibers 12 is heated to a temperature of 950-1050 ° С.

Replacement of a failed replaceable burner nozzle 6 is carried out by removing it from the slot 5 of the rectangular frame and replacing it with a replaceable burner nozzle 6, suitable for operation.

Claims (3)

1. Radiation gas burner of infrared radiation, containing at least one interchangeable burner nozzle from a combined supporting grid frame and a layer of fibers made of heat-resistant and heat-resistant material with open volume porosity in the form of through labyrinth channels, placed in its enclosure, connected to a gas nozzle mounted on the inlet pipe through the last ejector enclosing the last with an air intake having an air supply regulator and a gas-air mixture mixer, in differential the pattern of which is placed a gas-air divider facing the bulge towards the oncoming jet, characterized in that it is equipped with an air blower with an air duct in the form of a removable trough-shaped casing enclosing the housing with an ejector and made of a series of main and additional sections arranged in series, the housing - in the form of one formed from inseparably connected with each other of the upper and lower tubular elements with through communicating with each other channels of the frame with sockets, in each of which is placed a removable burner nozzle of one of the sections made with a fringing, carrying a lattice frame of each of the mentioned nozzles from interwoven and forming cell elements with a profiled cross section, the cavity of the trough-like removable casing communicating with the ejector air intake and through channels of the tubular elements of the frame, and the thickness H of each said the nozzle is 0.05-0.20 of its length L, while the size d of the profiled cross section of the elements forming the supporting lattice frames mentioned asadkov and size h of each last cell scaffolds are respectively 0.2-1.0 and 0.01-0.1 thickness H of the previously mentioned nozzles. 2. The burner according to claim 1, characterized in that the edging of each interchangeable burner nozzle is made of covering the latter around the perimeter and connected to each other by an integral connection of the upper and lower shells with a Z-shaped cross section, and the height t of the edging is 0.8- 0.9 thickness H replaceable burner nozzle. 3. The burner according to claim 1, characterized in that it is made cooled.

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