JP2564512Y2 - Swirl combustor - Google Patents

Description

[Detailed description of the invention]

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a swirl type combustor provided in a combustion device such as a hot water heater of a general household.

[0002]

2. Description of the Related Art Various proposals have been made for a combustor equipped in a combustion apparatus, for example, Japanese Utility Model Publication No. 55-14897.

[0003] In general, as fuel for a combustion device such as a water heater used at home, a gas supply pressure of a low pressure of 200 mm water column or a low calorie city gas or natural gas of 100 mm water column is used. It is difficult to mix low-pressure gas sufficiently with air, and the technology for efficient combustion at a high turndown ratio (ratio of maximum combustion amount to minimum combustion amount) of 10 or more has not yet been sufficiently established.

[0004] Recently, nitrogen oxides in exhaust gas generated in a household combustion device (this oxide has the chemical formula NO _X
However, there is a demand for a combustor that suppresses the generation of odor and realizes clean combustion without pollution. However, at present, a combustor with satisfactory performance has not yet been realized.

[0005]

[Problems to be solved by the present invention] The present invention has been made to solve the above-mentioned conventional problems.
Even when the low-pressure gas used in household combustion equipment is burned, the turndown ratio is as high as 10 or more, and it has a stable flame holding property and adheres to the inner surface of the combustion chamber wall that is air-cooled from the outside. It is an object of the present invention to provide a swirling combustor that can form a flame, suppress a rise in the temperature of the flame, promote recirculation of an unburned mixture, and realize clean combustion.

[0006]

The present invention is configured as follows to achieve the above object. That is, in the present invention, the outside of the cylindrical combustion chamber is formed as an air chamber provided with a fan, and an air introduction chamber communicating with the air chamber is connected to the lower part of the cylindrical combustion chamber, and the side of the air introduction chamber is connected to the side. A primary air swirler is provided for injecting primary air from the circumferential direction to impart swirling, and a combustion gas supply pipe is inserted and arranged in the air introduction chamber from the bottom side of the chamber so as to be coaxial with the central axis of the air introduction chamber. , provided with a baffle plate in the upper portion of the fuel gas supply pipe, a plurality of nozzles nozzle holes for ejecting radially from the peripheral surface of the fuel gas supply pipe to a position directly below the baffle plate is provided, the outer periphery of the baffle plate and the Inside the air introduction chamber
Between the peripheral surface and the primary air swirler, the primary air
Mixing of primary air and fuel gas mixed by swirling flow
While swirling air from the air introduction chamber,
An air-fuel mixture ejection gap is provided along the inner peripheral surface, and a secondary air introduction slit for introducing secondary air is provided on a side wall of the cylindrical combustion chamber.

The secondary air introduction slit is provided with a secondary air swirler that imparts a swirl in the same direction as the primary air swirler. The secondary air swirler is provided on the wall near the outlet of the cylindrical combustion chamber at the center axis of the combustion chamber. A tertiary air introduction hole for forming a heading flow is provided, and a resonance silencer chamber protruding toward the air chamber is provided on the upper side wall surface of the cylindrical combustion chamber, and the resonance silencer chamber and the combustion chamber are communicated by a communication hole. In addition, the nozzle orifices provided immediately below the baffle plate are arranged in a multi-stage arrangement of two or more stages, which is also a characteristic configuration of the present invention.

Further, in the multi-stage structure of the nozzle orifice, the air in the air chamber rises along the outer periphery of the fuel gas supply pipe to the root side of the path where the fuel gas supply pipe projects from the air chamber side to the air introduction chamber. A narrow air passage is provided, and a fuel gas chamber is formed on the outlet side of the air passage,
A part of the fuel gas is connected by connecting a branch pipe to the fuel supply pipe in each of the above-described configurations. And the divided fuel gas is introduced into the secondary air introduction slit.Furthermore, the primary air passing through the primary air swirler is 1.5 to 3.
The configuration that can be given five turns is also a characteristic configuration of the present invention.

[0009]

In the configuration of the present invention, the primary air supplied from the air chamber is swirled when passing through the primary air swirler, and flows at a right angle to the fuel gas which flows with centrifugal force and is ejected from the nozzle orifice. By colliding and dividing the fuel gas, the air and fuel gas are uniformly mixed, and the air-fuel mixture spreads in a layered manner on the wall of the combustion chamber from the lower surface of the baffle plate by centrifugal force, so-called free vortex zone Fuel is always supplied inside. Then, a boundary surface is formed with the forced vortex, which is a recirculation flow zone, and a hanging bell-shaped hollow flame is formed on the free vortex side to perform wall-adhered combustion.

At the time of the adhering combustion on the wall surface, secondary air enters the combustion chamber from the secondary air introduction slit due to a pressure difference between the secondary air and the air chamber, and supplies insufficient oxygen while maintaining the boundary layer of the air-fuel mixture stably. The combustion of the unburned air-fuel mixture is promoted. At this time, the unburned gas is swirled and the residence time is prolonged due to the dispersed introduction of air, and it is possible to avoid rapid combustion completion. coupled with the cooling effect of the flame produced by the following air, CO of unburned, a clean combustion with reduced NO _X both to the low level is performed.

[0011]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 shows a schematic configuration of a first embodiment of the swirl combustor according to the present invention. In the figure, an air introduction chamber 4 having a hanging wall 3 is connected to a lower portion of a cylindrical combustion chamber 1 via a tapered portion 2. A primary air swirler 5 (turning blade) is provided on a side surface of the air introduction chamber 4. A secondary air introduction slit 6 for introducing secondary air is provided in the upper and lower substantially middle wall surfaces of the cylindrical combustion chamber 1. These cylindrical combustion chamber 1, air introduction chamber 4,
The primary air swirler 5 is surrounded by an outer air chamber 7. An air supply fan 8 is provided below the air chamber 7. The speed of introduction of the primary air is controlled by the number of revolutions per unit time of the fan 8, and the number of revolutions until the primary air leaves the combustion chamber is determined by the speed of the primary air and the angle of revolution of the primary air swirler 5. This is different, and in this embodiment, various conditions are set so as to give 1.5 to 3.5 turns as shown in FIG.

The air chamber 7 is provided with a fuel gas supply pipe from outside.
The upper end of the fuel gas supply pipe 10 penetrates the air chamber 7 and is inserted into the air introduction chamber 4 so as to be coaxial with the central axis of the cylindrical combustion chamber 1. Gas supply pipe
A baffle plate 11 having a larger diameter than the outer diameter of the supply pipe 10 is provided at an upper end of the supply pipe 10 , and an outer periphery of the baffle plate 11 is provided.
An air-fuel mixture ejection gap is formed between the air-introducing chamber 4 and the inner peripheral surface.
A gap 9 is formed . Fuel gas is radially ejected from the outer peripheral surface of the fuel gas supply pipe 10 directly below the baffle plate 11 in a substantially horizontal lateral direction of the air introduction chamber 4 (in a radial direction of the fuel gas supply pipe 10 or in a direction similar to the radial direction). A plurality of nozzle orifices 12 are provided.

The first embodiment is constructed as described above. Next, the combustion operation will be described. When the fuel gas is supplied from the fuel gas supply pipe 10, the fuel gas is radially ejected from the nozzle orifice 12 into the air introduction chamber 4 in a horizontal and horizontal direction. On the other hand, the fan 8 is rotated on the air chamber 7 side, and primary air from the air chamber 7 passes through the primary air swirler 5 and enters the air introduction chamber 4. When passing through the primary air swirler 5, the primary air is swirled as shown in FIG. 4 and collides at right angles with the fuel gas ejected from the nozzle orifice 12, and separates the fuel gas to separate the fuel gas and air. And uniform mixing and stirring are performed. Then, as shown in FIG. 3, the mixture of the air and the fuel gas is
Through the gap 9 between the peripheral end face and the air introducing chamber 4 of the baffle plate 11 along the the bottom surface, handed while along the tapered portion 2
The rotating cylindrical combustion chamber 1 spreads in layers over the entire wall surface. That is, by the swirling of the primary air, as shown in FIG. 2, the central region of the cylindrical combustion chamber 1 becomes a forced vortex zone starting from the baffle plate 11 at the bottom, and a free vortex zone is formed outside the zone. The air-fuel mixture enters the zone of the free vortex, burns there, and adheres to the wall by the Coanda effect while performing volume thermal expansion, forming a hanging bell-shaped hollow flame as shown in FIG. It is done. The relationship between the internal pressure in the combustion chamber 1 and the tangential velocity of the vortex is expressed as shown in FIG. 14, where the radius r from the center of the combustion chamber and the tangential velocity u of the vortex at that position are represented by: And the range where u is proportional to the radius r gives the boundary between the free vortex and the forced vortex.

In the combustion on the wall, FIG. 3 and FIG.
As shown in the figure, carbon monoxide, combustion exhaust gas, and air, which are unburned gases, are discharged outside the combustor while turning 1.5 to 3.5 times in the free vortex zone, and a part of the combustion gas and the secondary Part of the air is drawn back into the forced vortex and self-recirculates, increasing the residence time in the combustion chamber 1 and re-supplying hot exhaust gas upstream of the combustion zone for combustion. No stabilization and NO _X reduction in, together with the secondary air from the secondary air introducing slit 6 side enters the combustion chamber, is promoted combustion of unburned gases, unburned gas is almost perfectly burn out.

Further, since the wall surface of the combustion chamber is in contact with the air chamber 7, there is a forced cooling action by the combustion air from the air chamber side, and the secondary air is taken in from the secondary air introduction slit 6. In combination with the cooling effect of the above, the temperature of the flame of the wall-adhered combustion is lowered, and the generation of nitrogen oxides is suppressed.

Due to the cooling action of the flame adhering to the wall and the almost perfect burning out action of the unburned gas, the exhaust side of the combustion chamber 1 becomes exhaust gas in which almost no nitrogen oxides or unburned gas is present. Clean burning without worry is achieved.

The degree of this clean combustion is shown in FIGS.
About in exhaust gas O ₂ = 0% converted NO _X value as shown in 40pp
Excellent combustion performance of about 0.0005 in m ₂ and CO / CO ₂ value (value of the ratio of carbon monoxide gas to carbon dioxide gas) could be exhibited.

Further, as described above, the flame adheres to and burns on the wall of the combustion chamber, thereby promoting heat dissipation of the flame to suppress a rise in the temperature of the flame. Since the exhaust gas is returned to the baffle plate 11, which is the source of fire, reliable flame holding can be performed.
Combustion with a high turndown ratio of 5: 1 was realized.

Furthermore, by installing the baffle plate 11 at the outlet of the air introduction chamber at the bottom of the swirling combustion chamber where the boundary between the forced vortex and the free vortex tends to be unclear, the mixture of The destination becomes the free vortex zone as it is. That is, by using the bluff body effect of the baffle plate to clarify the starting point of the forced vortex, the region of the exhaust gas recirculation zone is less likely to fluctuate. The boundary layer can maintain a stable boundary layer with almost no change due to the intensity of fuel gas injection and fluctuations in the supply pressure of the primary air. It is possible to form a stable flame which is not affected by the supply pressure.

Further, some vortex vortices 19 are generated at the edge of the upper surface of the baffle plate 11, and as described above, the unburned gas having a considerably high temperature is recirculated on the upper surface of the baffle plate 11. Since the cooling of the baffle plate is prevented, even in a low-load combustion state in which the fuel gas is reduced, reliable flame holding is performed.
It is possible to form stable combustion without flame extinguishing due to the flame holding effect.

FIG. 6 shows a second embodiment of the present invention. The difference between the second embodiment and the first embodiment is that a secondary air swirler 13 for turning secondary air in the same direction as the primary air is provided in the secondary air introduction slit 6. The other configuration is the same as that of the first embodiment. By providing the secondary air swirler 13, the secondary air to be introduced into the combustion chamber 1 can be smoothly swirled in the same direction as the primary air and introduced, and the mixture of the air-fuel mixture spreading in layers on the wall surface of the combustion chamber can be obtained. Without disturbing the distribution pattern, the swirling force is maintained up to the vicinity of the exit of the combustion chamber, and stable combustion on the wall surface can be performed.

FIG. 7 shows a third embodiment of the present invention. This third embodiment is different from the first embodiment or the second embodiment.
The tertiary air introduction hole 14 is provided on the wall surface near the outlet of the cylindrical combustion chamber 1 in the third embodiment. The tertiary air introduction hole 14 is a hole for introducing the air in the air chamber 7 in the direction of the central axis of the combustion chamber 1 without turning. By providing the tertiary air introduction hole 14, when unburned gas remains in the exhaust gas, combustion can be completed by the air introduced from the tertiary air introduction hole 14, and the outlet from the bottom side of the combustion chamber. Dispersion combustion is performed in a wide range toward the side, and the temperature of the flame is lowered to a lower level, whereby the generation of nitrogen oxides can be more effectively prevented.

FIG. 8 shows a fourth embodiment of the present invention. In the fourth embodiment, a resonance silencing chamber 15 is provided around the upper side wall of the cylindrical combustion chamber 1 of the first embodiment or the second embodiment so as to protrude toward the air chamber 7 side. A communication hole 16 is formed at a plurality of circumferential locations on the wall on one side to communicate the inside of the combustion chamber 1 with the inside of the resonance silencing chamber 15, and the noise generated at the bottom side of the cylindrical combustion chamber 1 is generated by the principle of the Helmholtz resonance box. Mute using
It is designed to perform quiet combustion. In the fourth embodiment, in the case where a tertiary air introduction hole is provided on the wall surface of the cylindrical combustion chamber 1, it is provided on the wall surface of the combustion chamber below the resonance silencer 15 in the same manner as in the third embodiment. Become.

FIG. 9 shows a fifth embodiment of the present invention. In the fifth embodiment, the nozzle orifices provided in the fuel gas supply pipe 10 immediately below the baffle plate 11 are formed in multiple stages, in this embodiment, three stages, and the bottom surface side of the air introduction chamber 4 is hollowed out. Small, that is, the fuel gas supply pipe
A fuel gas chamber 17 having a narrow gap with respect to 10 is formed, and the second stage nozzle orifice 12a and the third stage nozzle orifice 12b are buried in the fuel gas chamber 17 as viewed from the baffle plate 11 side. I have. And, for example, a slit is provided on the bottom wall side of the fuel gas chamber 17 along the fuel gas supply pipe 10, and a swirler is provided in the slit as necessary,
Air passage 18 having a smaller gap than fuel gas chamber 17
The air passage 18 communicates with the air chamber 7.

If necessary, a secondary air introducing slit 6 is provided in a substantially middle side wall of the cylindrical combustion chamber 1, and a secondary air swirler 13 is provided in the secondary air introducing slit 6 as necessary. Is provided. Further, as required, a tertiary air inlet 14 as in the third embodiment, a resonance silencer 15 as in the fourth embodiment, and the like are provided on the upper side of the side wall of the combustion chamber 1.

In the fifth embodiment, as shown in FIG. 10 (in the example of FIG. 10, a tertiary air introduction hole is formed in the side wall of the combustion chamber 1).
14 is shown), the fuel gas supplied through the fuel gas supply pipe 10 is ejected from each of the first, second, and third nozzle outlets 12, 12a, and 12b. Tier and third
The fuel gas ejected from the nozzle outlets 12a and 12b of the stage collides with the opposed wall surface of the fuel gas chamber 17, and the colliding fuel gas is dispersed in all directions. And this dispersed fuel gas,
The air rising from the air chamber 7 through the air passage 18 mixes with the air and enters the air introduction chamber 4. Moreover, the air introducing chamber 4 the fuel gas from the nozzle injection port 12 of Me 1 stage ejected into the air introducing chamber 4, the fuel gas the jet, as shown in FIG. 4, turning through the primary air swirler 5 Colliding with the primary air provided at right angles and mixing, and the swirling air and the fuel gas ejected from each nozzle orifice 12, 12a, 12b come together to form a premixed, uniform mixture that is closer to premixing. The mixed air-fuel mixture enters the zone in the free vortex and the combustion chamber 1
It spreads in layers over the entire inner wall surface, and a stable bell-shaped hollow flame is formed. In addition, a small pilot flame can be formed in the fuel gas chamber 17 by adjusting the amount of air flowing from the air passage 18, and the turndown width can be further increased by the pilot flame.

In the fifth embodiment, the fuel gas discharged from the second and third stage nozzle orifices 12a and 12b is supplied to the air passage 18
Is mixed with the air rising through the first stage, and furthermore, the fuel gas ejected from the first stage nozzle orifice 12 collides and mixes with the primary air at a right angle, so that the fuel gas and the air are perfectly mixed. Will be. The fuel gas ejected from the second and third stage nozzle orifices 12a, 12b collides with the wall surface of the fuel gas chamber 17, the ejection speed is reduced, and the fuel gas rises into the air introduction chamber 4, so that the air passage is increased. By adjusting the amount of inflow air from 18, a small pilot flame can be formed in the fuel gas chamber 17 (this pilot flame is not blown out because the rising air is weak).
The flame holding effect can be enhanced by the seed fire, and the turndown width can be further increased.

In this embodiment, as in the previous embodiments, the primary air entering the air introduction chamber 4 from the air chamber 7 through the primary air swirler 5 is swirled to enter the cylindrical combustion chamber 1. As a result, the central region of the cylindrical combustion chamber 1 becomes a zone of a forced vortex, the outside thereof forms a zone of a free vortex, and a mixture of fuel gas and air enters the zone of the free vortex from the baffle plate as a starting point. A stable boundary layer of the air-fuel mixture spreads in layers over the entire inner wall surface of 1. The effective cooling of the flame and the self-recirculation of unburned gas 1.5 to 3.5 times are effectively achieved by the combustion of the hollow flame on the wall. This results in a clean combustion with very little nitrogen oxides and a very low ratio of carbon monoxide to carbon dioxide.

FIG. 11 shows a sixth embodiment of the present invention. In the sixth embodiment, the fuel gas supply pipe 10 is branched, and a part of the fuel gas is guided by the branch pipe 20 to the secondary air introduction slit 6 side. To form a flame on the wall.

In the sixth embodiment, since the fuel gas is partially branched, the amount of gas ejected from the nozzle orifice 12 can be reduced, and the noise during combustion can be reduced accordingly. . Also, by dispersing and forming the flame,
The temperature of the flame can be lowered, and the generation of nitrogen oxides can be further suppressed.

The present invention is not limited to the above embodiments but can take various embodiments.

[0032]

[Effect of the Invention] The present invention is based on the baffle plate
An air-fuel mixture ejection gap was provided between the air-introducing chamber and the inner peripheral surface.
The air swirling flow of the primary air by the primary air swirler
It is possible to blow out from the entrance along the inner peripheral surface of the cylindrical combustion chamber.
Can, by this, the central portion of the cylindrical combustion chamber can form a zone of forced vortex, also it can form a zone of free vortex in the same room wall side, forced vortex zone and free vortex zone
The boundary of the free vortex zone can be clearly defined
Mixture of primary air and fuel gas through the mixture
It is possible to insert it securely,
A bell-shaped hollow flame that is distributed in layers over the entire inner wall surface of the cylindrical combustion chamber, that is, stably burns on the wall
It becomes possible. In this way, the combustion on the wall
Therefore , the heat dissipation of the flame is promoted, and the increase in the flame temperature is suppressed, so that the generation of nitrogen oxides can be extremely reduced.

As described above, the outside of the baffle plate
An air-fuel mixture ejection gap is provided between the circumference and the inner peripheral surface of the air introduction chamber.
Therefore, the mixture of fuel gas and primary air ejected from the nozzle orifice is swirled and injected from the air introduction chamber.
Injecting along the inner peripheral surface of the cylindrical combustion chamber through the outlet gap
As a result, a backflow region in which 1.5 to 3.5 swirls occur in the combustion chamber is generated, and self-recirculation of unburned gas occurs, so that the gas temperature near the ignition point of the combustion gas is kept high and maintained. Flammability is enhanced to stabilize combustion, and at the same time, sufficient residence time in the combustion chamber required for reduction of carbon monoxide is given, so that carbon monoxide gas emissions can be reduced. In addition, low-pollution, clean combustion can be performed in combination with the effect of reducing the generation of nitrogen oxides.

Further, by performing self-recirculation of the unburned gas and spreading the air-fuel mixture in layers over the entire inner wall surface of the combustion chamber and performing wall-adhered combustion, combustion having a high turndown ratio of 10 or more can be obtained. Fuel gas with different calorific value and burning rate, especially
Clean combustion with very little carbon monoxide and nitrogen oxides is possible even with low-pressure fuel gas used in household combustion equipment.

Further, in the present invention, the air-fuel mixture colliding with the primary air in a direction perpendicular to the air forms a boundary layer extending from the baffle plate to the inner wall surface of the cylindrical combustion chamber. In other words, the starting point of the forced vortex) is regulated by the baffle plate, so that the boundary layer of the air-fuel mixture does not collapse due to a change in the air pressure of the primary air or a change in the supply pressure of the fuel gas. A stable flame that is always unaffected by pressure changes can be formed.

[Brief description of the drawings]

FIG. 1 is a schematic configuration diagram showing a first embodiment of a swirl combustor according to the present invention.

FIG. 2 is an explanatory diagram of a forced vortex zone and a free vortex zone formed in a combustion chamber.

FIG. 3 is an explanatory diagram showing cross-sectional views of swirling flows in the combustor during combustion of the combustor according to the embodiment with various gas flows.

FIG. 4 is an explanatory diagram showing a state in which primary air is swirled and a state of collision and mixing with fuel gas ejected from a nozzle orifice when viewed from above an air introduction chamber.

FIG. 5 is an explanatory diagram of a formation state of a wall-adhered flame in the present embodiment.

FIG. 6 is a schematic configuration diagram showing a second embodiment of the present invention.

FIG. 7 is a schematic configuration diagram showing a third embodiment of the present invention.

FIG. 8 is a schematic configuration diagram showing a fourth embodiment of the present invention.

FIG. 9 is a schematic configuration diagram showing a fifth embodiment of the present invention.

FIG. 10 is an explanatory diagram showing a sectional state of a swirling flow in the chamber in a combustion state in the embodiment by flows of air and various gases.

FIG. 11 is a schematic configuration diagram showing a sixth embodiment of the present invention.

FIG. 12 shows O ₂ = 0 when burned by the combustor of the present embodiment.
5 is a graph of actual measurement data of% converted NO _X concentration.

FIG. 13 shows CO / C when burned by the combustor of the present embodiment.
It is a graph of measured data of O ₂ value.

FIG. 14 is an explanatory diagram showing the relationship between the internal pressure in the combustion chamber and the tangential speed together with the regions of forced vortex and free vortex.

FIG. 15 is an explanatory diagram showing an operation of a process in which the flow of the swirled free vortex is discharged outside the combustion chamber while being swirled 1.5 to 3.5 times in the free vortex zone.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Cylindrical combustion chamber 4 Air introduction chamber 5 Primary air swirler 6 Secondary air introduction slit 7 Air chamber 10 Fuel gas supply pipe 11 Baffle plate 12, 12a, 12b Nozzle nozzle 17 Fuel gas chamber 18 Air passage

Claims (8)

(57) [Scope of request for utility model registration] An outside of the cylindrical combustion chamber is formed as an air chamber provided with a fan, and an air introduction chamber communicating with the air chamber is connected to a lower portion of the cylindrical combustion chamber. A primary air swirler is provided to give a swirl by allowing air to flow in from the circumferential direction, and a combustion gas supply pipe is inserted and arranged in the air introduction chamber from the bottom side of the chamber so as to be coaxial with the central axis of the air introduction chamber. provided with a baffle plate in the upper portion of the fuel gas supply pipe, a plurality of nozzles nozzle holes for ejecting radially from the peripheral surface of the fuel gas supply pipe to a position directly below the baffle plate is provided, the outer periphery of the baffle plate and the air Guidance
The primary air swirler described above is between the entrance and the inner peripheral surface.
Primary air and fuel gas mixed by swirling flow of primary air
While rotating the air-fuel mixture from the air introduction chamber,
An air-fuel mixture ejection gap is provided for ejection along the inner peripheral surface of the combustion chamber.
Only, swirl combustor having a secondary air introducing slit for introducing the secondary air into the side wall of the cylindrical combustion chamber. 2. The swirling combustor according to claim 1, wherein a secondary air swirler is provided in the secondary air introduction slit so as to provide swirling in the same direction as the primary air swirler. 3. The swirling combustor according to claim 1, wherein a tertiary air introduction hole for forming a flow toward the central axis of the combustion chamber is provided on a wall surface near an outlet of the cylindrical combustion chamber. 4. A resonance silencer chamber protruding toward the air chamber is provided on the upper side wall surface of the cylindrical combustion chamber, and the resonance silencer chamber and the combustion chamber are communicated by a communication hole. 3. The swirl combustor according to 3. 5. The swirl combustor according to claim 1, wherein the nozzle orifices provided immediately below the baffle plate are arranged in two or more stages. 6. A narrow air passage for raising air in the air chamber along the outer periphery of the fuel gas supply pipe is provided at a root side of a path where the fuel gas supply pipe protrudes from the air chamber to the air introduction chamber. A fuel gas chamber is formed on the outlet side of the passage, and a nozzle nozzle at an arbitrary stage below the uppermost nozzle nozzle is buried in the fuel gas chamber, and fuel gas ejected from the buried nozzle nozzle is buried in the fuel gas chamber. 6. The swirl combustor according to claim 5, wherein the fuel gas is caused to collide with an opposing wall surface of the fuel gas chamber. 7. The fuel supply pipe according to claim 1, wherein a part of the fuel gas is divided by connecting a flow dividing pipe to the fuel supply pipe, and the divided fuel gas is introduced into the secondary air introduction slit.
The swirl combustor according to any one of the first to third aspects. 8. The swirl according to claim 1, wherein the primary air passing through the primary air swirler is configured to be swirled 1.5 to 3.5 times in the cylindrical combustion chamber. Type combustor.