JPH10169921A - Combustion apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress the generation of NOx. SOLUTION: A thick burner 21 which has a rich flame hole 22 for injecting a thick mixture 32 and a thin burner 23 which has a thin burner port 24 for injecting a thin mixture 34 are alternately arranged and an inclined surface 31 is provided being expanded in the downstream direction on the outlet side of the burner 23 to the thin burner port 24. As a result, the flow of the thin mixture with a lower concentration of the fuel is deflected to cool a high temperature area on the downstream side of a thick flame thereby enabling suppression of the generation of NOx.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a combustion apparatus using gas or kerosene as a fuel, and more particularly to a combustion apparatus employing a lean-burn system.

[0002]

2. Description of the Related Art Conventionally, this type of combustion apparatus is disclosed in
The one described in JP-A-03122 was common. Hereinafter, this combustion device will be described with reference to FIGS. 15 and 16.

[0005] As shown in FIGS. 15 and 16, a rich burner 3 having a rich burner port 2 for ejecting a rich mixture 1 having a high fuel concentration, and a light burner mouth for ejecting a lean mixture 4 having a low fuel concentration. 5
The rich burner 3 and the light burner 6 are arranged such that the rich mixture 1 and the light mixture 4 are ejected from the respective flame ports 2 and 5 in parallel. 2 and light flame 5
Are provided on the same plane.

[0004] With the above configuration, the rich mixture 1 is supplied to the rich burner 3.
From the rich flame outlet 2, forming a rich flame 7 downstream of the rich flame outlet 2, the light mixture 4 is blown out from the light flame outlet 5 of the light burner 6, and a light flame 8 is downstream of the light flame outlet 5. Had formed. The rich air-fuel mixture 1 and the light air-fuel mixture 4 are configured to be ejected from each of the flame ports 2 and 5 in parallel, so that a wide high-temperature area 9 is formed downstream of the rich flame 7. The rich flame 7 plays the role of igniting and maintaining the flame of the lean flame 8, and in the high-temperature region 9 downstream of the rich flame 7, a large amount of high-concentration NOx is generated. Because of the small amount, NOx could be reduced in the entire combustion apparatus.

[0005]

However, in the conventional combustion apparatus, high-concentration NOx is generated in the rich flame 7 formed downstream of the rich flame port 1, so that it is diluted by the lean flame 8, but is sufficiently diluted. There was a problem that NOx could not be reduced.

Further, since the rich flame 7 formed by the rich flame port 2 and the light flame 8 formed by the light flame port 5 are formed in parallel, the flame length of the light flame 8 becomes longer, and as a result, combustion occurs. There is a need to lengthen the chamber in the flow direction of the air-fuel mixture, and as a result, there is a problem that the size of the combustion device itself increases.

[0007] The light flame 8 has a low fuel concentration.
There was a problem that the flame-retarding property was extremely poor, and it was vulnerable to changes in the external environment due to wind and the like, and combustion became unstable.

[0008]

SUMMARY OF THE INVENTION In order to solve the above-mentioned problems, the present invention provides a rich burner having a rich flame outlet for discharging a rich air-fuel mixture, and a light burner having a light flame outlet for discharging a light air-fuel mixture. The burners are arranged alternately, and the outlet side surface of the light burner reaching the light flame outlet is formed as an inclined surface expanding in the downstream direction.

According to the above invention, the light air-fuel mixture is blown out so as to spread in a fan shape in the downstream direction of the light flame port,
The flame surface of the light flame is formed so as to enclose the rich flame.
Further, by cooling the region downstream of the flame surface of the high-temperature rich flame with a low-temperature light flame, the amount of NOx generated by the high-flame flame is suppressed, and NOx generated by the high-flame flame is reduced by the light flame. Reburn. The NOx is further reduced, and the flame length of the lean flame is shortened. As a result, the height of the combustion device can be reduced.

[0010]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The first technical means of the present invention comprises a rich burner having a rich flame port for discharging a rich air-fuel mixture and a light burner having a light flame port for discharging a light air-fuel mixture. The outlet side surface of the light burner reaching the light flame outlet is formed as an inclined surface that expands in the downstream direction. The outlet side surface of the light burner is an inclined surface that expands in the downstream direction, and the lean air-fuel mixture ejected from the light flame outlet and having an equivalence ratio of less than 1 flows along this inclined surface and goes downstream. Spreads, forming a fan-shaped light flame. In the rich burner, a rich air-fuel mixture having an equivalence ratio higher than 1 is ejected from the rich flame outlet to form a rich flame. Since a light flame has an equivalent ratio lower than 1, the flame temperature is generally low and the flame length is long, but since it has a fan-shaped flame shape,
Elongation of the flame length in the downstream direction can be suppressed. On the downstream side of the rich flame, a high-temperature region is formed, and thermal N
Although O is generated, the amount of NOx generated can be suppressed by reducing the high-temperature region downstream of the rich flame and cooling the light flame having a low flame temperature.

A second technical means of the present invention is to alternately dispose a rich burner having a rich flame port for discharging a rich air-fuel mixture and a light burner having a light flame port for discharging a light air-fuel mixture. In addition, the outlet side surface of the light burner reaching the light flame outlet has a curved surface shape that expands in the downstream direction. The outlet side surface of the light burner has a curved surface that expands in the downstream direction, and the lean air-fuel mixture ejected from the light flame outlet and having an equivalence ratio of less than 1 flows strongly along this curved surface due to the Coanda effect. Spread as you go, forming a fan-shaped light flame. In the rich burner, a rich air-fuel mixture having an equivalence ratio higher than 1 is ejected from the rich flame outlet to form a rich flame. Since the light flame has an equivalence ratio of less than 1, the flame temperature is generally low and the flame length is long. However, since the flame has a fan-like flame shape, the extension of the flame length in the downstream direction can be suppressed. On the downstream side of the rich flame, a high-temperature region is formed and thermal NO is generated. However, by reducing the high-temperature region downstream of the rich flame and cooling the light flame having a low flame temperature, the NOx generation amount is reduced. Can be suppressed.

Further, a third technical means of the present invention comprises a rich burner having a rich flame outlet for ejecting a rich air-fuel mixture, and an outlet having a light flame outlet for ejecting a light air-fuel mixture and reaching the light flame opening. It is composed of a light burner whose part is inclined to the deep flame outlet side, light burner, dark burner,
A plurality of light burners are arranged as one set. Since the outlet of the light burner is inclined in the downstream direction of the rich flame port, the light mixture having an equivalence ratio of less than 1 ejected from the rich flame port is obliquely ejected toward the downstream of the rich flame port. . In the rich burner, a rich air-fuel mixture having an equivalence ratio higher than 1 is ejected from the rich flame outlet to form a rich flame. Since a light flame has an equivalence ratio lower than 1, the flame temperature is generally low and the flame length is long.
Since the gas is ejected in an oblique direction, the flame length in the downstream direction can be suppressed from growing. On the downstream side of the rich flame, a high-temperature region is formed, and thermal NO is generated.The high-temperature region downstream of the rich flame is cooled by a light flame having a low flame temperature, and the light flame envelops the rich flame, Since thermal NO generated downstream of the rich flame is reburned by the light flame, N
Ox generation can be suppressed.

A fourth technical means of the present invention is to alternately dispose a rich burner having a rich flame port for discharging a rich air-fuel mixture and a light burner having a light flame port for discharging a light air-fuel mixture. A deflecting member is provided downstream of the light flame port to deflect the light air-fuel mixture ejected from the light flame port toward the rich flame port. Since a deflecting member for deflecting the flow of the lean air-fuel mixture toward the rich flame side is provided downstream of the light-flame mouth, the lean air-fuel mixture ejected from the lean flame port with an equivalence ratio of less than 1 is rich flame. It is deflected downstream of the mouth.
In the rich burner, a rich air-fuel mixture having an equivalence ratio higher than 1 is ejected from the rich flame outlet to form a rich flame. Light flame has an equivalence ratio of 1
Since the temperature is lower, the flame temperature is generally lower and the flame length is longer. However, since the flow is deflected by the deflecting member, the flame length in the downstream direction can be suppressed from increasing. On the downstream side of the rich flame, a high-temperature region is formed, and thermal NO is generated.The high-temperature region downstream of the rich flame is cooled by a light flame having a low flame temperature, and the light flame envelops the rich flame, Since the thermal NO generated downstream of the rich flame is reburned by the lean flame, the amount of NOx generated can be suppressed. In addition, since the deflection plate 39 receives radiation from the rich flame 33 and becomes high temperature, the deflection plate 39 becomes an ignition source of the light flame 35,
It is possible to stably hold the light flame 35 having poor flame holding performance.

According to a fifth technical means of the present invention, in the fourth technical means of the present invention, the deflecting member has a sectional shape convex toward the light flame port. Since the cross-sectional shape of the deflecting member is convex in the direction of the light flame port, it is easy to distribute the light air-fuel mixture ejected from the light flame port in two directions, left and right. Since the air can be deflected, it is possible to suppress an increase in the flame length in the downstream direction of the lean flame. Thermal NO is generated in a high-temperature region formed on the downstream side of the rich flame, and a low-flame light flame having a low flame temperature cools the high-temperature region downstream of the rich flame.
Since the lean flame envelops the rich flame and the thermal NO generated downstream of the rich flame is reburned by the lean flame, the amount of NOx generated can be suppressed.

According to a sixth technical means of the present invention, in the fourth or the fifth technical means of the present invention, the deflection member is made of a ceramic material. And since the deflecting member is made of a ceramic material, even if the deflecting member is heated by radiation from a light flame or a rich flame, the deflecting member is hardly deformed, and the durability performance as a combustion device can be improved, It is possible to enhance the stability of deflecting the flow of the lean mixture ejected from the bright flame outlet.

According to a seventh technical means of the present invention, a rich burner having a rich flame port for discharging a rich air-fuel mixture and a light burner having a light flame port for discharging a light air-fuel mixture are alternately arranged. The outlet of the light burner is an inclined surface inclined toward the dense burner, and the light flame outlet is provided on the inclined surface. The outlet of the light burner is a slope inclined toward the rich burner side, and a light flame port is provided on the slope. Deflected to the side. In the rich burner, a rich air-fuel mixture having an equivalence ratio higher than 1 is ejected from the rich flame outlet to form a rich flame. Since the light flame has an equivalence ratio lower than 1, the flame temperature is generally low and the flame length is long. However, the light mixture is deflected obliquely from the inclined surface toward the downstream side of the rich flame outlet, so that it is downstream. Flame length can suppress elongation. On the downstream side of the rich flame, a high-temperature region is formed, and thermal NO is generated.The high-temperature region downstream of the rich flame is cooled by a light flame having a low flame temperature, and the light flame envelops the rich flame, Since the thermal NO generated downstream of the rich flame is reburned by the lean flame, the amount of NOx generated can be suppressed.

According to an eighth technical means of the present invention, in the seventh technical means of the present invention, a plurality of light flame ports are arranged in a zigzag shape on an inclined surface. And, since the light flame ports provided on the inclined surface are arranged in a zigzag shape, the flame length in the downstream direction can be suppressed, and the high temperature area downstream of the rich flame is cooled by the low flame with low flame temperature, Since the lean flame envelops the rich flame and the thermal NO generated downstream of the rich flame is reburned by the lean flame, the amount of NOx generated can be suppressed. Furthermore, since the flame area of the lean flame can be increased, the volume of the entire combustion device can be reduced.

According to a ninth technical means of the present invention, in the seventh or eighth technical means of the present invention, the inclined surface is made of a ceramic material. And, since the inclined surface at the outlet of the light burner is made of a ceramic material, even if the inclined surface is heated by radiation from a light flame or a rich flame, there is little deformation and the durability performance of the combustion device can be improved. it can.

According to a tenth technical means of the present invention, a rich burner having a rich flame port for discharging a rich air-fuel mixture and a light burner having a light flame port for discharging a light air-fuel mixture are alternately arranged. , The light flame port is located downstream of the rich flame port. And, since the light flame port is configured to be located on the downstream side of the rich flame port, the light flame is stably held by the high temperature region formed downstream of the rich flame, and the flame downstream of this rich flame is Since the light flame having a low flame temperature cools the high temperature region, the amount of thermal NO generated downstream of the rich flame can be suppressed.

According to an eleventh technical means of the present invention, in the tenth technical means of the present invention, a rim portion made of a ceramic material is provided between the dark burner and the light burner. Since the rim portion made of a ceramic material is provided between the light burner and the rich burner, the side surface of the light burner is less likely to be deformed even when heated by radiation from the rich flame. Endurance performance can be enhanced.

[0021] The twelfth technical means of the present invention includes a rich burner having a rich flame outlet for ejecting a rich mixture, a light burner having a light flame outlet for ejecting a light mixture, and a rich burner. It consists of a rim part having a cross section that is upwardly convex between the light flame ports.
A rim is provided between the rich flame port and the light flame port, and the upper surface of the rim portion is shaped like an upwardly convex mountain or circle, so that the upper surface of the rim receives radiation from the flame and has a high temperature. It is possible to enhance the flame holding performance of a light flame having a low equivalent ratio and poor flammability.

According to a thirteenth technical means of the present invention, in the twelfth technical means of the present invention, the rim portion is made of a ceramic material. Since the rim portion is made of a ceramic material, deformation of the rim portion, which becomes high in temperature, can be suppressed, and the durability of the combustion device can be improved.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. (Embodiment 1) FIG. 1 is a configuration diagram of a main part of a combustion apparatus according to Embodiment 1 of the present invention. FIG. 2 is a sectional view of a main part. In the drawing, reference numeral 21 denotes a rich burner, and a rich flame port 22 is provided on the upper surface of the downstream end. Reference numeral 23 denotes a light burner, and a dark burner 21.
A light flame port 24 is provided on the upper surface of the downstream end in the same manner as described above. The dark burners 21 and the light burners 23 are arranged alternately and housed in a burner case 25. On the lower surface of the burner case 25, a fan 26 for supplying combustion air to the rich burner 21 and the light burner 23 is provided. Reference numeral 27 denotes a dark nozzle that supplies fuel to the burner 21, and reference numeral 28 denotes a light nozzle that supplies fuel to the light burner 23. The dark nozzle 27 and the light nozzle 28 are provided on a burner head 29, and the burner head 29 is provided on a side surface of the burner case 25. A dark burner 21 and a light burner 23;
A partition plate 30 having openings on the nozzle 27 and 28 sides is provided in the burner case 25 between the fans 26. The outlet side surface of the light burner 23 has a diverging inclined surface 31 such that the flow path becomes wider toward the light flame outlet 24 on the downstream side.
It has become.

Next, the operation and operation will be described. Fuel is supplied from the nozzles 27 and 28 to the burner 2 via the burner head 29.
1, 23. On the other hand, the combustion air is supplied to the fan 26.
Are supplied to the burners 21 and 23. And burner 2
The fuel and the combustion air are mixed in 1 and 23 to form an air-fuel mixture and are ejected from the flame ports 22 and 24.

In the rich burner 21, a rich mixture 32 having a high equivalent ratio of fuel to air and an equivalent ratio of 1 or more is formed, is ejected from the rich flame port 22, and forms a rich flame 33 downstream thereof. On the other hand, in the light burner 23, a light mixture 34 in which the equivalent ratio of fuel to air is low and the equivalent ratio is 1 or less is formed, is ejected from the light flame port 24, and a light flame 35 is formed downstream thereof.

Since the rich mixture 32 has an equivalence ratio of 1 or more, a high-temperature region 36 in which a chemical reaction actively occurs is formed downstream of the rich flame 33. In this high-temperature region 36, a large amount of NOx
Is generated. On the other hand, since the light mixture 34 has an equivalent ratio of 1 or less, the chemical reaction proceeds to ebb and flow, and the temperature of the light flame 35 itself is much lower than that of the rich flame 33.

The lean air-fuel mixture 34 flows divergently by the inclined surface 31 on the way to the downstream light-flame port 24 of the light burner 23, and a part thereof flows toward the rich flame 33 and suppresses the high-temperature rich flame 33. Help. Therefore, the high-temperature region 36 downstream of the rich flame 33 becomes smaller, and is cooled by the light flame 35, so that the generation amount of NOx can be reduced. Further, since the light flame 35 has a fan-shaped flame shape, the flame length in the downstream direction can be suppressed from increasing.

(Embodiment 2) FIG. 3 is a sectional view of a main part of a combustion apparatus according to Embodiment 2 of the present invention. The difference from the first embodiment is
The outlet side surface of the light burner 23 has a smooth curved surface 3 that widens as the flow path reaches the light flame outlet 24 downstream.
That is, 7. The components having the same reference numerals as those in the first embodiment have the same structure, and the description will be omitted.

Next, the operation and function will be described. The outlet side surface of the light burner 23 is a smooth curved surface 37 which expands divergently in the downstream direction, and the equivalent ratio ejected from the light flame outlet 24 is lower than 1. Due to the Coanda effect, the air-fuel mixture 34 flows strongly along the curved surface 37, spreads downstream, and forms a fan-shaped fresh flame 35. Dark burner 2
In 4, a rich mixture 32 having an equivalent ratio higher than 1 is ejected from the rich flame port 22 to form a rich flame 33. Since the light flame 35 has an equivalent ratio lower than 1, the flame temperature is generally low and the flame length is long. However, since the flame has a fan-like flame shape, the extension of the flame length in the downstream direction can be suppressed. In addition, rich flame 3
3, a high-temperature region 36 is formed, and the thermal NO.
Is generated, but the high-temperature region 36 downstream of the rich flame 33
Is reduced by the light flame 35, and the amount of NOx generated can be suppressed by cooling.

(Embodiment 3) FIG. 4 is a sectional view of a main part of a combustion apparatus according to Embodiment 3 of the present invention. The difference from the first and second embodiments is that the outlet portion 38 of the light burner 23 reaching the light flame port 24 is inclined toward the rich flame port 22 side, and a plurality of light burners, dark burners, and light burners are arranged as one set. That is. Examples 1 and 2
Those having the same reference numerals have the same structure, and a description thereof will be omitted.

Next, the operation and function will be described. Since the outlet 38 of the lean burner 23 is inclined in the downstream direction of the rich flame 22, the lean mixture in which the equivalent ratio ejected from the lean flame 24 is lower than 1 is shown. 34 is ejected obliquely toward the downstream side of the rich flame outlet 33. In the rich burner 21, a rich mixture 32 having an equivalent ratio higher than 1 is ejected from the rich flame port 22 to form a rich flame 33. Since the equivalent ratio of the light flame 35 is lower than 1, the flame temperature is generally low and the flame length is long. However, since the flame is jetted obliquely, the flame length in the downstream direction can be suppressed from growing. On the downstream side of the rich flame 33, a high-temperature region 36 is formed, and thermal NO is generated.
The low temperature high temperature region 36 is cooled by the light flame 35 having a low flame temperature, and the light flame 35 envelops the rich flame 33. The thermal NO generated downstream of the rich flame 33 is reburned by the light flame 35. , NOx generation amount can be suppressed.

(Embodiment 4) FIG. 5 is a sectional view of a main part of a combustion apparatus according to Embodiment 4 of the present invention. The difference from the first to third embodiments is that a deflecting member 39 for deflecting the flow of the lean mixture 34 is provided downstream of the lean flame port 24 of the lean burner 23. The components having the same reference numerals as those of the first to third embodiments have the same structure, and description thereof will be omitted.

Next, the operation and operation will be described. Since a deflecting member 39 for deflecting the flow of the lean mixture 34 toward the rich flame 22 is provided downstream of the lean flame 24, the light flame 24 is provided.
The lean air-fuel mixture 34 having an equivalence ratio lower than 1 is deflected downstream of the rich flame outlet 22. In the rich burner 21, a rich mixture 32 having an equivalent ratio higher than 1 is ejected from the rich flame port 22 to form a rich flame 33. Since the equivalent ratio of the light flame 35 is lower than 1, the flame temperature is generally low and the flame length is long. However, since the flow is deflected by the deflecting member 39, the flame length in the downstream direction can be suppressed from increasing. On the downstream side of the rich flame 33, a high temperature region 36 is formed, and thermal NO is generated.
6 is cooled by the light flame 35 having a low flame temperature,
Since the lean flame 35 envelops the rich flame 33 and the thermal NO generated downstream of the rich flame 33 is reburned by the lean flame 35, the generation amount of NOx can be suppressed. In addition, since the deflection plate 39 receives the radiation from the rich flame 33 and becomes high temperature,
The deflecting plate 39 serves as an ignition source of the light flame 35, and can stably hold the light flame 35 having poor flame holding performance.

(Embodiment 5) FIG. 6 is a sectional view of a main part of a combustion apparatus according to Embodiment 5 of the present invention. The difference from Example 4 is that
The deflecting member 39 has a sectional shape that is convex in the direction of the light flame port 24. The components having the same reference numerals as those of the fourth embodiment have the same structure, and the description is omitted.

Next, the operation and operation will be described. Since the cross-sectional shape of the deflecting member 39 is convex toward the light flame port 24, the light mixture 34 ejected from the light flame port 24 is distributed in two directions, left and right. Since the lean mixture 34 can be easily and effectively deflected to the downstream side of the rich flame 33, the flame length in the downstream direction of the lean flame 35 can be suppressed from increasing. Thermal NO is generated in a high-temperature region 36 formed on the downstream side of the rich flame 33. The low-temperature flame 36 having a low flame temperature cools the high-temperature region 36 downstream of the rich flame 33, and the light flame 35 Envelop the rich flame 33, rich flame 3
Since the thermal NO generated downstream of the third flame is reburned by the light flame 35, the amount of NOx generated can be suppressed.
Further, since the deflecting plate 39 receives the radiation from the rich flame 33 and becomes high temperature, the deflecting plate 39 becomes an ignition source of the light flame 35, and the light flame 35 having poor flame holding performance can be stably held.

(Embodiment 6) FIG. 7 is a sectional view of a main part of a combustion apparatus according to Embodiment 6 of the present invention. The difference from the fourth or fifth embodiment is that the deflection member 39 is made of a ceramic material 40. The components having the same reference numerals as those of the fourth or fifth embodiment have the same structure, and the description is omitted.

Next, the operation and operation will be described. Since the deflecting member 39 is made of the ceramic material 40, even if the deflecting member 39 is heated by the radiation from the light flame 35 or the rich flame 33, it may be deformed. And the durable performance as a combustion device can be improved.
The stability of deflecting the flow of the lean mixture 34 ejected from the nozzle can be improved.

(Embodiment 7) FIG. 8 is a sectional view of a main part of a combustion apparatus according to Embodiment 7 of the present invention. The difference from the first to sixth embodiments is that the outlet of the light burner 23 having the light flame port 24 is an inclined surface 42 inclined to the dense burner 21 side. The components having the same reference numerals as those of the first to sixth embodiments have the same structure, and the description is omitted.

Next, the operation and operation will be described. The outlet of the light burner 23 is an inclined surface 41 inclined toward the dense burner 21, and the light flame port 24 is provided on the inclined surface 41. A light mixture 3 with an equivalence ratio of less than 1
4 is deflected to the downstream side of the rich flame outlet 22. In the rich burner 21, the rich mixture 32 whose equivalent ratio is higher than 1
To form a rich flame 33. Since the light flame 35 has an equivalent ratio lower than 1, the flame temperature is generally low and the flame length is long.
Since it is obliquely deflected toward the downstream side, the flame length in the downstream direction can be suppressed from extending. In addition, rich flame 33
On the downstream side of the high temperature region 36 is formed, and thermal NO is generated.
Since the light flame 35 having a low flame temperature cools down, the light flame 35 envelops the rich flame 33, and the thermal NO generated downstream of the rich flame 33 is reburned by the light flame 35,
The generation amount of NOx can be suppressed.

(Eighth Embodiment) FIG. 9 is a sectional view of a main part of a combustion apparatus according to an eighth embodiment of the present invention. The difference from the seventh embodiment is that
That is, a plurality of light flame ports 24 are arranged in a zigzag shape on the inclined surface 41. The components having the same reference numerals as those of the seventh embodiment have the same structure, and the description is omitted.

Next, the operation and function will be described. Since the light flame ports 24 provided on the inclined surface 41 are arranged in a zigzag pattern, the area load on the flame surface of the light flame can be reduced, and the generation of NOx can be suppressed. Can be. Further, since the flame area of the lean flame 35 can be increased, the volume of the entire combustion device can be reduced.

(Embodiment 9) FIG. 10 shows Embodiment 9 of the present invention.
It is principal part sectional drawing of the combustion apparatus of FIG. The difference from the seventh or eighth embodiment is that the inclined surface 41 is made of a ceramic material 42. The components having the same reference numerals as those of the seventh or eighth embodiment have the same structure, and the description is omitted.

Next, the operation and action will be described. Since the inclined surface 41 at the outlet of the light burner 23 is made of the ceramic material 42, even if the inclined surface 41 is heated by radiation from the light flame 35 or the rich flame 33, the inclined surface 41 is heated. , Less deformed,
The durability performance of the combustion device can be improved.

(Embodiment 10) FIG. 11 is a sectional view showing a main part of a combustion apparatus according to Embodiment 10 of the present invention. The difference from the first to ninth embodiments is that the light flame port 24 is mixed with the mixture 32, 3
4 is provided on the downstream side in the flow direction. Example 1
Elements having the same reference numerals as those of to 9 have the same structure, and a description thereof will be omitted.

Next, the operation and operation will be described. Since the light flame port 24 is located downstream of the rich flame port 22, the high temperature region 36 formed downstream of the rich flame 33 is formed.
As a result, the lean flame 35 is stably maintained, and the high temperature region 36 downstream of the rich flame 33 is cooled by the low flame temperature of the low flame 33. Therefore, the amount of thermal NO generated downstream of the rich flame 33 is reduced. Can be suppressed.

(Embodiment 11) FIG. 12 is a sectional view showing a main part of a combustion apparatus according to Embodiment 11 of the present invention. The difference from the tenth embodiment is that a rim 44 made of a ceramic material 43 is provided between the dark burner 21 and the light burner 23. The components having the same reference numerals as those in the tenth embodiment have the same structure, and a description thereof will be omitted.

Next, the operation and operation will be described. Since the rim portion 44 made of the ceramic material 43 is provided between the light burner 23 and the dark burner 21, the side surface of the light burner 23 Since deformation can be reduced even when heated by radiation, the durability of the combustion device can be improved.

(Embodiment 12) FIG. 13 is a sectional view showing a main part of a combustion apparatus according to Embodiment 12 of the present invention. The difference from the first to eleventh embodiments is that a rim portion 45 having a cross-sectional shape convex upward is provided between the dark burner 21 and the light burner 23. The components having the same reference numerals as those of the first to eleventh embodiments have the same structure, and a description thereof will be omitted.

Next, the operation and operation will be described. A rim portion 45 is provided between the rich flame port 22 and the light flame port 24 and the rim portion 4 is provided.
5, the upper surface of the rim portion 4 has a convex shape.
5 can be heated to a high temperature by receiving radiation from the rich flame 33, and the flame holding performance of the light flame 24 having a low equivalent ratio and poor combustibility can be enhanced.

(Thirteenth Embodiment) FIG. 14 is a sectional view of a main part of a combustion apparatus according to a thirteenth embodiment of the present invention. The difference from the twelfth embodiment is that the rim 45 is made of a ceramic material 46. The components having the same reference numerals as those of the twelfth embodiment have the same structure, and the description is omitted.

Next, the operation and function will be described. Since the rim portion 45 is made of the ceramic material 46, the deformation of the rim portion 45 which becomes high in temperature can be suppressed, and the durability performance as a combustion device can be improved. Can be.

[0052]

As described above, according to the combustion apparatus of the present invention, the shape of the outlet of the light burner is provided with an inclined surface or a curved surface in which the flow path expands in the downstream direction, and the deflecting member is provided.
Also, by inclining the burner outlet surface itself and positioning the light flame outlet downstream of the rich flame outlet, the flow of the lean mixture jetting out of the light flame outlet provided in the light burner can be controlled by rich flame or rich flame. By hitting the high-temperature region formed on the downstream side, the high-temperature region is reduced, and the temperature of the region is reduced by the light flame, thereby suppressing the generation of thermal NO. The NOx concentration can be reduced. By deflecting the flow of the lean mixture, the flame length of the lean flame can be shortened, and the volume of the combustion device can be reduced.

Further, by using a ceramic material for the outlet surface of the light burner having the light flame port, deformation due to radiation from the flame is suppressed, stable combustion is achieved, and durability performance as a combustion device is improved. Can be.

Further, by providing a deflecting member downstream of the light flame outlet of the light burner or by providing a rim portion between the rich burner and the light burner, the flame holding performance of the light flame having poor flame holding performance can be enhanced. Combustion noise can be reduced and odor caused by fuel slip can be reduced.

[Brief description of the drawings]

FIG. 1 is a configuration diagram of a main part of a combustion apparatus according to a first embodiment of the present invention.

FIG. 2 is a sectional view of a main part of the combustion apparatus.

FIG. 3 is a sectional view of a main part of a combustion apparatus according to a second embodiment of the present invention.

FIG. 4 is a sectional view of a main part of a combustion apparatus according to a third embodiment of the present invention.

FIG. 5 is a sectional view of a main part of a combustion apparatus according to a fourth embodiment of the present invention.

FIG. 6 is a sectional view of a main part of a combustion apparatus according to a fifth embodiment of the present invention.

FIG. 7 is a sectional view of a main part of a combustion apparatus according to a sixth embodiment of the present invention.

FIG. 8 is a sectional view of a main part of a combustion apparatus according to a seventh embodiment of the present invention.

FIG. 9 is a sectional view of a main part of a combustion apparatus according to an eighth embodiment of the present invention.

FIG. 10 is a sectional view of a main part of a combustion apparatus according to a ninth embodiment of the present invention.

FIG. 11 is a sectional view of a main part of a combustion apparatus according to a tenth embodiment of the present invention.

FIG. 12 is a sectional view of a main part of a combustion apparatus according to an eleventh embodiment of the present invention.

FIG. 13 is a sectional view of a main part of a combustion apparatus according to a twelfth embodiment of the present invention.

FIG. 14 is a sectional view of a main part of a combustion apparatus according to a thirteenth embodiment of the present invention.

FIG. 15 is a configuration diagram of a main part of a conventional combustion device.

FIG. 16 is a sectional view of a main part of the combustion device.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 21 Rich burner 22 Rich flame port 23 Light burner 24 Light flame port 31 Inclined surface 32 Rich mixture 34 Light mixture 37 Curved surface 38 Outlet 39 Deflection member 40 Ceramic material 41 Inclined surface 42 Ceramic material 43 Ceramic material 44 Rim portion 45 Rim Part 46 Ceramic material

Claims (13)

[Claims] 1. A rich burner having a rich flame port and ejecting a rich air-fuel mixture and a light burner having a light flame port and ejecting a light air-fuel mixture are alternately provided, and reach the light flame port. A combustion device in which an outlet side surface of the light burner has an inclined surface that expands in a downstream direction. 2. A rich burner having a rich flame port and ejecting a rich air-fuel mixture and a light burner having a light flame port and ejecting a light air-fuel mixture are arranged alternately, and reach the light flame port. A combustion device in which the outlet side surface of the light burner has a curved surface shape that expands in a downstream direction. 3. A rich burner having a rich flame outlet for ejecting a rich air-fuel mixture, and an outlet portion having a light flame opening and reaching the light flame opening is inclined toward the rich flame opening to eject a light air-fuel mixture. A burner comprising a plurality of light burners, the light burners, the dense burners, and the light burners. 4. A dense burner having a rich flame outlet and ejecting a rich air-fuel mixture and a light burner having a light flame opening and ejecting a light air-fuel mixture are arranged alternately, and a downstream side of the light flame opening is provided. A deflecting member for deflecting the lean air-fuel mixture jetted from the lean flame port toward the rich flame port side. 5. The combustion apparatus according to claim 4, wherein the deflecting member has a cross section convex toward the light flame port side. 6. The combustion device according to claim 4, wherein the deflection member is made of a ceramic material. 7. A rich burner having a rich flame port and ejecting a rich air-fuel mixture and a light burner having a light flame port and ejecting a light air-fuel mixture are arranged alternately, and the outlet of the light burner is connected to the light burner. A combustion device having an inclined surface inclined to a rich burner side, and the light flame port provided on the inclined surface. 8. The combustion apparatus according to claim 7, wherein a plurality of light flame ports are arranged in a zigzag shape on the inclined surface. 9. The combustion device according to claim 7, wherein the inclined surface is made of a ceramic material. 10. A dense burner having a rich flame port and ejecting a rich mixture, and a light burner having a light flame port and ejecting a light mixture are alternately arranged. A combustion device configured to be located downstream from a flame outlet. 11. The combustion apparatus according to claim 10, wherein a rim portion made of a ceramic material is provided between the rich burner and the light burner. 12. A rich burner having a rich flame port and ejecting a rich air-fuel mixture, a light burner having a light flame port and ejecting a light air-fuel mixture, and an upper portion provided between said rich flame port and said light flame port. A combustion device provided with a rim having a convex cross-sectional shape. 13. The combustion device according to claim 12, wherein the rim portion is made of a ceramic material.