RU2262637C1 - Heat-insulated multi-regime gas burner - Google Patents

Abstract

FIELD: combustion.

SUBSTANCE: burner comprises housing with valve, ring gas collector coaxial to the housing and provided with one set of detachable nozzles directed at an acute angle to the axis of the burner , pipeline for gas supply, air duct that is defined by the ring gas collector and receives controllable swirler, protecting shield mounted upstream of the gas collector from the side of the furnace with a spaced relation to it, and diaphragm made in block with the face of the gas collector that faces the furnace. The axial space S₁ between the shield and collector and radial space S₂ between the diaphragm and housing are equal to half radial space S₀ between the collector and housing and radial space S₃ between the shield and housing S₀. The radial rotatable blades of the swirler are secured to the hollow axle screwed in the carrier at the front edge of the blades parallel to the axis of their rotation mating to the ring collar in the central threaded bushing of the valve. The direction of rotation of the blades is opposite to the direction of the screw line.

EFFECT: enhanced efficiency.

4 dwg

Description

The invention relates to injection-type devices intended for the combustion of gaseous fuels, and can be used in furnaces and other heat engineering devices for various purposes.

Known atmospheric injection burner, comprising two coaxially arranged gas chambers with axial nozzles and an embrasure, in the inlet confuser of which they are located so that the plane of the gas outlet nozzles of the central gas chamber is located in the plane of the entrance window of the embrasure in its narrow part, and the plane of the gas outlet nozzles is external the gas chamber, made in the form of Loval nozzles, is located behind the pinch of the embrasure in its wide part, but does not extend to the surface of the cone of the expanding part of the embrasure, the entrance surface which area is made in the form of an element of the surface of the body of Coanda. In addition, the ratio of the diameters of the outer and central gas chambers is maintained in the range of 0.8-0.9. In the central part of the burner, a blade air swirl is installed (Patent RU No. 94005782 A1, class in accordance with MKI 6 F 23 D 14/02, dated 02.17.1994).

The disadvantage of this invention is the inability to use heat-resistant natural gases as fuel. This is explained by the fact that coaxially located gas chambers are heated up to the pyrolysis temperature of the gas and above due to the heat exchange by radiation under the direct influence of the radiation energy of the flame of a burning gas, and heat-unstable gas is heated and decomposes with the formation of soot, which clogs the channels and nozzles. To clean the nozzles, it is necessary to dismantle the burner, which is only possible when the furnace stops working.

Known gas-oil burner containing a housing with a central fuel oil nozzle, an air flow regulator and an annular gas manifold with nozzles arranged coaxially to the axis of the burner, mixers that are mounted directly on the nozzles, the ratio of the diameter of the circle through which the axis of the nozzles to the caliber of the burner is 0.7 -0.8 (Patent RU No. 94025341 A1, class according to MKI 6 F 23 D 17/00, dated 06/07/1994).

The disadvantage of this invention is the inability to use heat-resistant natural gases as fuel. This is explained by the fact that, due to the radiant heat exchange, when the direct gas radiation energy of the flame of the burning gas is used, the annular gas collector heats up to the pyrolysis temperature of the gas and above, and the heat-unstable gas decomposes and forms soot, which clogs the channels and nozzles, which can only be cleaned when removing the burner and stopping the furnace.

The closest in technical essence and the achieved technical results to the claimed invention is a GP-2 burner (TU-26-02-68-78, catalog: "Burners for tube furnaces" ZINTIKHIMNEFTEMASH, Moscow, 1985), comprising a housing with a fan shutter , an annular gas collector coaxial to it with two rows of nozzles, a coaxial axis of the burner, an air duct with a fluid nozzle, a swirl and a damper installed inside it, and gas supply pipelines.

The disadvantage of this invention is the inability to use heat-resistant natural gases as fuel. This is explained by the fact that due to the radiant heat exchange under the direct influence of the radiation energy of the flame of a burning gas, a coaxially located gas collector is heated to a pyrolysis temperature of gas and above, while heating and decomposition of heat-unstable gas occurs with the formation of soot, which clogs the channels and nozzles, which can be cleaned only when dismantling the burner and stopping the furnace.

The technical task of this invention is the creation of a gas burner multimode heat-protected GMT-1, the design of which allows the use of heat-resistant fuel gas, adjust the burner to the desired mode when the gas load changes, improve the quality of fuel gas combustion, adjust the flame length, replace and clean nozzles without stopping furnace operation and dismantling of the burner.

The stated task of a gas multi-mode heat-protected gas burner ГМТ-1, comprising a housing with a fan shutter, an annular gas collector coaxial to it with one row of replaceable nozzles, the channels of which are directed at an acute angle to the axis of the burner, a gas supply pipe, an air duct formed by the central channel of the gas manifold , and a controlled swirler in it, is solved according to the invention in that the burner includes a protective screen mounted in front of the gas manifold from the furnace side with axial clearance, a diaphragm, complements integrally with an end face of the gas manifold facing the furnace, wherein an axial gap S ₁ between the screen and the reservoir, the radial clearance S ₂ between the diaphragm and the housing are equal to half the radial S ₀ of the gap between the collector and the housing, and the radial clearance S ₃ between the shield and the housing is equal to S ₀ , in addition, the radial swirl blades of the swirl are fixed on the hollow axis screwed into the central threaded sleeve of the fan damper on the thread, and the rod leash at the leading edge of the blades parallel to the axis of their rotation is mated to the annular point of the central threaded sleeve of the fan damper, and the direction of rotation of the blades is back to the direction of the helical thread of the hollow axis.

The invention is illustrated by drawings: figure 1 is a General view of the burner, figure 2 is a section aa perpendicular to the axis of the rotary blade of the controlled swirl, figure 3 and 4 is a diagram of the application of forces when turning the blade.

The multimode heat-insulated gas burner ГМТ-1 contains: a housing 1 with a fan shutter 2, an annular gas collector 3, a coaxial to the housing 1, a controlled swirler 4, a gas supply pipe 5, a spare pipe 6 with a plug 7.

In the annular gas manifold 3, replaceable nozzles 8 are installed, the walls of which are perforated, the channels 9 of which are directed at an acute angle to the axis of the burner. In front of the gas manifold 3 from the furnace side with an axial clearance S _1, a protective screen 11 is installed on the distance struts 10. The channels 9 of the replaceable nozzles 8 are directed into the openings 12 of the protective screen 11. At the same time, a diaphragm 13 is made along with the end of the gas manifold 3 facing the furnace. Between the housing 1 and the outer diameter of the diaphragm 13 there is a gap S ₂ . Between the housing 1 and the outer diameter of the shield 11 there is a radial clearance S ₃ . The gaps S ₁ and S ₂ are equal in size to half the radial clearance S ₀ between the annular gas manifold 3 and the housing 1, and the gap S ₃ = S ₀ .

The controlled swirl 4 includes rotary blades 14, having shelves upper 15 and lower 16, mounted for rotation on radial axes 17, which in turn are fixedly mounted in the hollow axis 18, screwed onto the thread in the Central threaded sleeve 19 of the fan shutter 2. Hollow the axis 18 is fixed in the threaded sleeve 19 with a lock nut 20. To rotate the axis 18, there are end grooves 21. At the front edge 22 of the blade 14, on the lower shelf 16, a cylindrical leash 23 fixedly connected to the annular groove 24 of the central p the threaded sleeve 19 of the fan damper 2. Replaceable nozzles 8 are installed in the coaxial grooves of the gas manifold 3 and secured with plugs 25. The nozzle 8 is sealed with o-rings 26, 27. To ensure reliable operation of the seals 27, elastic elements are introduced between the end of the nozzle 8 and the plug 25 28. The angular position of the nozzle 8 relative to its axis is fixed by special devices of the protrusion-groove type, which are not conventionally shown in the drawing. The burner is attached to the front skin 29 of the embrasure 30 of the furnace.

Burner gas multimode heat-protected GMT-1 operates as follows.

Air due to the ejecting action of gas jets from the channels 9 of the nozzles 8 enters through the fan shutter 2 into the burner, flowing around the annular gas manifold 3 through the gap S ₀ between the annular gas manifold 3 and the housing 1, and is mixed with gas through the central channel 31 of the manifold 3, which burns in a flame. The air flowing in the gap S ₀ serves not only to fuel the combustion of gas, but also to protect the walls of the embrasure 30 from the effects of a burner flame. The air flow passing through the central channel 31 of the manifold 3 is swirled by a controlled swirl 4 and enters into aerodynamic interaction with gas jets from the channels 9 of the nozzles 8, is mixed with them, forming a gas-air mixture. The direction of the channels 9 of the nozzles 8 at an acute angle to the axis of the burner is due to the desire to improve the mixing of gas with air. The intensity of mixing gas with air is determined by the magnitude of the swirl of the air flow controlled by the swirl 4 and determines the length of the flame of the burner. This is explained as follows: the magnitude of the swirl of the air flow in the central channel 31 of the manifold 3 determines the intensity of mixing gas with air, the moment of formation of the gas-air mixture and its ignition. The magnitude of the swirling air flow in the Central channel 31 is determined by the angle of rotation of the blades 14, which can be changed by rotation of the hollow axis 18, while the leash 23 in cooperation with the annular groove 24 of the Central threaded sleeve 19 of the shutter 2 rotates the blade 4. Thus, the burner can be adjusted at different lengths of the flame. By changing interchangeable nozzles 8 with different diameters of the channels 9, it is possible to regulate the gas flow rate, and the fan damper 2 - air flow rate. This ensures that the burner is set to the mode when the gas load changes.

The design of the burner allows you to change the replaceable nozzle 8 through the holes in the fan shutter 2, without dismantling the burner and, moreover, without stopping the operation of the furnace. The cavity 32 of the hollow axis 18 can be used to observe the flame of the burner, ignite the gas-air mixture and place an additional liquid burner.

The direction of the thread of the hollow axis 18 is right, and the direction of rotation of the blades 14 (if we draw an analogy with the thread) is left, i.e. the direction of the thread is right + δ, and the direction of rotation of the blades 24 is the reverse left -δ.

If we consider the interaction of forces when turning the blades 14 (see figure 2, 3, 4), then we can note the following.

When screwing the hollow axis 18 into the Central threaded sleeve 19, the wall of the annular groove 24 of the sleeve 19 presses on the leash 23 of the blade 14 and rotates it in the direction of increasing angle δ (see figure 3). The normal force P and the friction force F from the interaction of the leash 23 and the groove 24 rotate the blade 14, increasing the angle δ of its installation, the resulting two forces P and F - R are applied to the blade with a large shoulder l ₁ . If the direction of the threads of the hollow axis 18 coincides with the direction of rotation of the blades 14, the resulting two forces P and F ¹ - R ^{1 are} directed to the axis of rotation, i.e. the blade is jammed in the extreme position. A similar picture develops when the hollow axis 18 is inverted, i.e. while reducing the angle δ of the installation of the blades 14, in the extreme position.

The thermal protection of the burner is the thermal protection of the annular gas manifold 3 from radiant heat exchange with a flame of a burning gas.

Air flowing between the manifold 3 and the housing 1 through the gap S ₀ is throttled through the gap S ₂ and flows into the gap S ₃ , while air is ejected from the gap S ₁ between the collector 3 and the screen 11. A part of the air from the air flow of the central channel 31 behind the centrifugal forces flow in the gap S ₁ to the periphery, enhancing the ejection effect of the air stream from the gap S ₂ into the gap S ₃ , in addition, the gas stream from the replaceable nozzles 8, flowing through the openings 12 in the screen 11, draws in ambient air, thereby intensifying cooling the nozzle heads 8. So m substantially annular gas manifold 3 from all sides by air, and the inside - the gas and the screen 11 is protected from direct exposure to the flame of burning gas rays that it creates a reliable thermal protection against radiative heat transfer.

A practical embodiment of the invention is a multi-mode heat-protected gas burner ГМТ-1, made in metal and tested in operation, with the following characteristics:

1. Caliber burner D ₁ 309 mm 2. The ratio between the diameter of the circle, on which are located the axis of the nozzle of the burner, and caliber d _to / D _g 0.8 3. Thermal power 0.5-2.5 MW 4. Productivity when burning gas with calorific value 36 MJ / m ³ 50-250 m ³ / h 5. Gas pressure in front of the burner 10-200 kPa 6. Pressure in the combustion chamber of the furnace at nozzle level minus 0.5-6 gaPa 7. The coefficient of excess air 1.01-1.1 8. The range of working regulation of gas flow 50-250 m ³ / h 9. The diameters of the flow cross sections of interchangeable nozzles 2.4; 3; 3.7; 4.5; 6 mm 10. Overall dimensions 410 × 180 mm 11. Mass, no more 19 kg

Using this invention, it will be possible to create a multimode heat-protected gas burner, the design of which allows using heat-resistant gas as fuel, adjusting the burner to the required mode and replacing and cleaning nozzles without stopping the furnace, and improving the quality of fuel gas combustion.

Claims (1)

A multi-mode heat-resistant gas burner containing a housing with a fan shutter, an annular gas collector coaxial to it with one row of replaceable nozzles, the channels of which are directed at an acute angle to the burner axis, a gas supply pipe, an air duct formed by the central channel of the annular gas manifold and a controlled swirl in it characterized in that it includes a protective screen mounted in front of the gas manifold from the furnace side with axial clearance, a diaphragm made integral with the end of the gas manifold ra, facing the furnace, wherein the axial clearance S1 between the screen and the manifold, the radial clearance S2 between the diaphragm and the casing are equal to half the radial clearance So between the collector and the casing, and the radial clearance S3 between the screen and the casing is So, in addition, the radial rotary vanes the swirlers are mounted on a hollow axis screwed onto the thread in the central threaded sleeve of the fan flap, and the rod lead at the leading edge of the blades parallel to the axis of rotation, mates with the annular groove of the central threaded sleeve of the fan elephants, and the direction of rotation of the blades back to the direction of the helix of the thread of the hollow axis.

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