JPH06123410A - Burner - Google Patents

Abstract

PURPOSE:To prevent occurrence of an unstable combustion even when the O2 concentration of combustion air is low. CONSTITUTION:A primary air discharge port 3 discharging primary air for combustion and secondary air discharge port 4 discharging secondary air for combustion and disposed around the primary air discharge port 3 are provided. At the fore end part of the secondary air discharge port 4, a side nozzle hole 11 and a main nozzle hole 12 are provided. At the fore end part of the primary air discharge port 3, a single and annular flame stabilizer 14 is provided. The direction of injection of a fuel gas from the side nozzle hole 11 is on the side of the direction of the central axis of the annular flame stabilizer 14. Fuel injected from the side nozzle hole 11 is stabilized and combusted by the flame stabilizer 14 and a circular recirculating flame-stabilizing area is formed in the rear stream of the flame stabilizer 14 by a bluff body effect. The fuel gas from the main nozzle hole 12 is injected around the recirculating flame- stabilizing area.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a burner capable of stabilizing combustion.

[0002]

2. Description of the Related Art A burner of a combustion apparatus, such as a commercial boiler, which has a low excess air ratio and burns with a slightly larger amount of combustion air than the theoretical air amount, has a nitrogen oxide N content.
In order to suppress the generation of Ox, it is an effective means to form a diffusion flame in which combustion progresses while the fuel and air are mixed in the combustion chamber in the wake of the burner.

In diffusion combustion of gaseous fuel, two types of bluff body type flame stabilizers are often provided in the burner in order to secure flame holding properties. FIG. 4 is a view for explaining the structure of an example of such a conventional burner, FIG. 4 (a) is a sectional view of such burner, and FIG. 4 (b) is a front view of the burner throat portion of such burner. Referring to the figure, the burner 4
Combustion air is supplied to the burner throat 49 of 0 from the wind box 44 while being divided into primary air, secondary air, and tertiary air. The arrow 45 indicates the flow of primary air, the arrow 46 indicates the flow of secondary air, and the arrow 47 indicates the flow of tertiary air. Reference numeral 48 is an air register that directs the flow of the tertiary air. The burner 40 is provided with a plurality of gas fuel jet nozzles (gas spuds) 43, and a flame stabilizer (frame holder) 50 is individually provided at the tip end of each of the gas spuds 43 so that the gas spuds 43 retain their flames and the burner center is
Generally, a common flame stabilizer (impeller) 51, which is larger than the frame holder 50, is provided to strengthen the flame maintenance of the burner 40 as a whole. Gas spud 43
As shown by the arrow 41, the fuel gas is supplied to the fuel gas ring 42.

[0004]

In the above-mentioned conventional technique, when the exhaust gas mixing for reducing the nitrogen oxide NOx is not carried out, or when the exhaust gas mixing ratio is small, that is, the O ₂ concentration of the wind box 44 is about 19% or more. In some cases, it exhibits excellent flame holding performance. However, when the O ₂ concentration in the wind box 44 falls below about 19% due to an increase in the exhaust gas mixture ratio, unstable combustion may result due to a change in flame holding form. The reason for such unstable combustion will be described step by step below.

(1) First, O _{2 in the} wind box 44
The decrease in concentration triggers the flame holding property in the frame holder 50, and the oxygen consumption amount near the frame holder 50 decreases.

(2) Next, the decrease in oxygen consumption in the vicinity of the flame holder 50 contributes to combustion in the downstream of the impeller 51, so the flame holding property in the downstream of the impeller 51 is enhanced.

(3) The flame holding property in the frame holder 50 is improved by the help of strengthening the flame holding in the wake of the impeller 51,
Oxygen consumption near the frame holder 50 increases.

(4) Due to the increase in oxygen consumption in the vicinity of the frame holder 50, the O ₂ partial pressure in the wake of the impeller 51 decreases, and the flame holding property in the wake of the impeller 51 decreases.

(5) The flame holding property in the frame holder 50 also decreases due to the deterioration of the flame holding property in the wake of the impeller 51, and the state returns to the above state (1), and the above (1) to (5) are repeated. .

The above phenomenon is caused by unstable combustion as a result of the two types of flame holding mechanisms of the frame holder 50 and the impeller 51 interfering with each other.

An object of the present invention is to provide a burner which does not cause unstable combustion even when the O ₂ concentration of combustion air is low.

[0012]

Means for Solving the Problems The above-mentioned problems can be solved by forming a gas-fuel combustion flame with only one flame stabilizer having a strong flame holding performance, and the gist thereof is the primary air for combustion. Flowing in the burner throat, a primary air discharge port provided in the burner throat for discharging the primary air for combustion flowing from the flow path, and a primary air discharge for discharging secondary air for combustion. A secondary air outlet arranged around the air outlet, a side nozzle provided at the tip of the secondary air outlet for injecting a part of the fuel, and a secondary air outlet for injecting the rest of the fuel. A fuel injection part having a main injection port provided at the outlet tip part, and an annular flame stabilizer provided at the tip part of the primary air discharge hole for ensuring the flame holding property of the combustion gas And the side injection port is configured so that a part of the fuel is directed in the central axis direction of the flame stabilizer. Injected in the combustion of the fuel caused to form a flame holding region by said flame holder in said main nozzle hole is in a burner for injecting the remainder of the fuel around the flame holding region.

A fuel injection port for injecting fuel is provided at the primary air discharge port, and a second flame stabilizer, which is a flame stabilizer for stabilizing the combustion of the fuel, is provided at the fuel injection port portion. A position adjusting means for moving the fuel injection port in the axial direction of the primary air flow path, wherein one of the fuel injection part and the fuel injection port injects fuel gas and the other injects liquid fuel The burner that burns only the fuel gas and the liquid fuel is also a gist.

Further, any one of the above burners provided with an air flow rate adjusting means for adjusting the flow rates of the primary air and / or the secondary air is also a gist.

[0015]

[Function] The fuel injected from the side injection port is flame-held and burned by the sole flame stabilizer and forms a flame-holding region. Since this flame stabilizer is the only flame stabilizer in the entire burner, a plurality of flame holding mechanisms do not interfere with each other to cause unstable combustion. Since the fuel injected from the main injection port is injected around the flame holding region, it is ignited by the flame holding region to form a diffusion flame.

[0016]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a sectional view showing the structure of a burner according to an embodiment of the present invention. FIG. 1 (a) is a sectional view of such a burner, and FIG. 1 (b) is a front view of a burner throat portion of such a burner. In the figure, the combustion air is separately supplied to the burner throat section 5 of the burner 1 by a wind box 6 into primary air and secondary air. Also,
The burner 1 is provided with a primary air sleeve 2 serving as a primary air flow path through which the primary air for combustion flows, and a primary air flow for combustion flowing from the primary air flow path 5 provided in the burner throat portion 5. It is provided with a primary air discharge port 3 for discharging and a secondary air discharge port 4 arranged around the primary air discharge port and discharging secondary air for combustion. Arrow 7 shows the flow of primary air, and arrow 8 shows the flow of secondary air.

A flame stabilizer 14 is provided at the tip of the primary air outlet 3.
Is provided. The flame stabilizer 14 is annular, and is the only flame stabilizer in the burner 1 of this embodiment. In the burner 1 of this embodiment, a flame stabilizer is additionally provided at the tip of the gas spud 9. Not not. As shown in FIG. 1A, the flame stabilizer 14 has a cross section in the axial direction of the primary air sleeve 2 that projects from the tip of the primary air discharge port 3 in a dogleg shape.

The burner throat 4 is provided with, for example, eight gas spuds 9, and the tips thereof are arranged at the tips of the secondary air discharge ports 4. A side injection port 11 and a main injection port 12 are provided at the tip of the gas spud 9. Gas spud 9
A fuel gas is supplied to the engine through a fuel gas ring 13 as shown by an arrow 15. Fuel gas is 10% to 50%
The amount is injected from the side injection port 11, and the remaining about 90% to 50% is injected from the main injection port 12. Reference numeral 16 indicates the fuel gas from the side injection port 11 injected in this way, and 17 indicates the main injection port 1
2 shows the fuel gas injected from No. 2.

Reference numeral 19 is a primary air damper for adjusting the flow rate of the primary air, and 10 is an air register for directing the flow of the secondary air. By controlling the air distribution of the primary air and the secondary air by the primary air damper 19 and the air register 10, the flow rate of the primary air and the secondary air can be adjusted to enhance the stable combustion condition. That is, the local air-fuel ratio of the flame stabilizer 14 can be optimized by adjusting the opening degree of the primary air damper 5, and the swirling strength of the secondary air is changed by adjusting the opening degree of the air register 10 to cause tubular recirculation. Flame holding area 1
A size of 8 can be optimized.

Next, a burner according to another embodiment of the present invention will be described. FIG. 3 is a diagram illustrating the structure of a burner according to another embodiment of the present invention. Figure 3
FIG. 3A is a sectional view of the burner, and FIG. 3B is a front view of a burner throat portion of the burner. Figure 1
The members and the like denoted by the same reference numerals are the same as the members and the like described above with reference to FIG. The burner according to the present embodiment is
One unit can burn both fuel gas and liquid fuel,
The present invention is applied to a burner capable of selecting which fuel is burned by switching.

In the burner of this embodiment, a liquid fuel burner 20 for burning liquid fuel is provided in the primary air sleeve 2. At the tip of the liquid fuel burner 20, a liquid fuel injection port 22 and a second tip having a circular or rectangular shape for stabilizing the combustion of the liquid fuel injected from the injection port 22 are provided.
The impeller 21 which is a flame stabilizer of the above is provided. Also,
Liquid fuel burner 20 with injection port 22 and impeller 21
A liquid fuel burner slide device (not shown) for manually or automatically moving the tip portion of the above in the axial direction of the primary air sleeve 2 is provided by known means. As a result, the tip of the liquid fuel burner 20 can be housed in the primary air sleeve 2 as shown in FIG. 3A, or can be located at the tip 21 ′ of the flame stabilizer 14. As a result, when burning the fuel gas, the tip of the liquid fuel burner 20 is housed in the primary air sleeve 2 so as not to interfere with the flame holding mechanism by the flame stabilizer 14.

Next, the operation of the burner 1 according to this embodiment will be described. The fuel gas injected from the side injection port 11 is flame-held by the flame stabilizer 14 and burns, and as shown in FIG. 2, in the downstream of the flame stabilizer 14, an annular recirculation flame stabilizing region 18 is formed by the bluff body effect. It is formed. From the main nozzle 12 the flame holding area 1
Fuel gas is injected around 8 and the gas is ignited by the flame of the flame holding region 18 and burns to form a diffusion flame. Since the flame stabilizer 14 is the only flame stabilizer in the entire burner 1, a plurality of flame retaining mechanisms do not interfere with each other to cause unstable combustion. Further, since the flame stabilizer 14 is an annular flame stabilizer, even if a part of the recirculation flame stabilizing region 18 fluctuates, the flame stabilizing mechanism as a whole can maintain stable combustion.

Further, the primary air damper 5 and the air register 1
As described above, the flow rates of the primary air and the secondary air are appropriately adjusted to 0 to optimize the local air-fuel ratio of the flame stabilizer 14, and
The size of the recirculation flame holding region 18 is optimized.

Regarding the burner 1 described with reference to FIG. 3, the flame stabilizer 1 is used when burning the fuel gas.
Liquid fuel burner 2 so as not to interfere with the flame holding mechanism by 4
The zero tip is housed in the primary air sleeve 2. When burning the liquid fuel, the tip of the liquid fuel burner 20 is positioned at the tip 21 ′ of the flame stabilizer 14. As a result, the liquid fuel is flame-held by the impeller 21 and burns, and the flame stabilizer 14
Stable combustion without any interference.

According to the burner 1 according to this embodiment described above, the flame stabilizer 14 is the only flame stabilizer in the entire burner 1, so that a plurality of flame stabilizing mechanisms interfere with each other to cause unstable combustion. Never.

Further, since the flame stabilizer 14 is an annular flame stabilizer, even if a part of the recirculation flame stabilizing region 18 fluctuates, the flame stabilizing mechanism as a whole can maintain stable combustion.

In the burner 1 described with reference to FIG. 3, since the tip of the liquid fuel burner 20 can be housed in the primary air sleeve 2, the liquid fuel burner 20 can be stored in the liquid even when the fuel gas is burned. Flame stabilizer 1 even when burning fuel
4. Burning is performed by holding flame by only one of the impeller 21 and the impeller 21, and by switching, burner in which any of the fuel gas and the liquid fuel can be burned does not cause unstable combustion.

Further, the primary air damper 5 and the air register 10 optimize the local air-fuel ratio of the flame stabilizer 14, and
The size of the recirculation flame holding region 18 can be optimized.

[0029]

According to the burner according to the present invention described above, the flame stabilizer is the only flame stabilizer in the entire burner.
Multiple flame holding mechanisms do not interfere with each other to cause unstable combustion.

Further, since the flame stabilizer is an annular flame stabilizer, stable combustion can be maintained as a whole flame stabilizing mechanism even if a part of the flame stabilizing region fluctuates.

Further, in the above-mentioned burner having the fuel injection port, since the fuel injection port can be housed in the primary air discharge port, when the fuel gas is burned or the liquid fuel is burned. Is burned by being flame-held and burned only by either the annular flame holder or the second flame stabilizer, and unstable combustion occurs even in a burner in which either fuel gas or liquid fuel can be selected for combustion. Never.

[Brief description of drawings]

1A and 1B are views for explaining a structure of a burner according to an embodiment of the present invention, FIG. 1A is a sectional view of the burner, and FIG. 1B is a front view of a burner throat portion of the burner. It is a figure.

FIG. 2 is a diagram illustrating a recirculation flame holding region formed by a burner according to an embodiment of the present invention.

3A and 3B are views for explaining a structure of a burner according to another embodiment of the present invention, FIG. 3A is a sectional view of the burner, and FIG. 3B is a view of a burner throat portion of the burner. It is a front view.

FIG. 4 is a diagram illustrating a structure of a conventional burner, and FIG.
FIG. 4A is a sectional view of the burner, and FIG. 4B is a front view of a burner throat portion of the burner.

[Explanation of symbols]

 1 Burner 3 Gas spud 11 Side jet 12 Main jet 14 Flame stabilizer

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Shunichi Tsumura 6-9 Takaracho, Kure-shi, Hiroshima Babcock Hitachi Co., Ltd. Kure factory (72) Keinobu Kobayashi 4026 Kuji-cho, Hitachi-shi, Ibaraki Hitate Co., Ltd. Mfg. Co., Ltd. Hitachi Research Laboratory (72) Inventor Akira Baba 3-36 Takaracho, Kure City, Hiroshima Prefecture Babcock Hitachi Kure Research Laboratory

Claims (3)

[Claims] 1. A primary air flow path through which primary air for combustion flows, a primary air discharge port provided in a burner throat section for discharging primary air for combustion flowing from the flow path, and a combustion Secondary air outlet arranged around the primary air outlet for discharging secondary air for use, side nozzles provided at the tip of the secondary air outlet for injecting a part of fuel, and A fuel injection part having a main injection port provided at the tip of the secondary air discharge port for injecting the rest of fuel, and a flame holding property of the combustion gas provided at the tip of the primary air discharge hole are secured. An annular sole flame stabilizer for maintaining the flame holding region by the flame stabilizer by injecting a part of the fuel toward the central axis direction side of the flame stabilizer by the side injection port. And the main injection port injects the rest of the fuel around the flame holding region. 2. The primary air discharge port is provided with a fuel injection port for injecting fuel, and a second flame stabilizer, which is a flame stabilizer for stabilizing the combustion of the fuel, is provided at the fuel injection port portion. And a position adjusting means for moving the fuel injection port in the axial direction of the primary air flow path, wherein one of the fuel injection unit and the fuel injection port injects fuel gas and the other injects liquid fuel. The burner according to claim 1, wherein the burner burns only the fuel gas and burns only the liquid fuel. 3. The burner according to claim 1, further comprising an air flow rate adjusting means for adjusting a flow rate with the primary air and / or the secondary air.