KR101254928B1 - Low nitrogen oxide burner - Google Patents

Abstract

PURPOSE: A low nitrogen oxide burner is provided to combust fuel together with combustion air mixed with partial exhaust gas in a combustion chamber, thereby reducing a thermal nitrogen oxide in a combustion process without increasing the volume of the combustion chamber. CONSTITUTION: A low nitrogen oxide burner includes a burner body(1100), a first fuel supplying part(1200), a second fuel supplying part(1300), a blast tube(1400), and a flame holder plate(1500). The burner body forms an air supply path(1110), and is mounted on a burner mounting hole(110) of a combustion chamber(100). The first fuel supplying part is branched off from a fuel supplying pipe penetrating the burner body, and is placed at the central portion of the burner body. The flame holder plate is coupled to the first fuel supplying part. The blast tube is inserted into the burner mounting hole. The front end of the blast tube is firstly bent in an inner diameter direction, and is secondly bent to be parallel to the flame holder plate. Second fuel supplying parts are branched off from the fuel supplying pipe, and are radially placed along the periphery of the first fuel supplying part. The end portions of the second fuel supplying parts are bent outside, and are separated from one another at regular intervals on the firstly bent surface of the blast tube.

Description

Low nitrogen oxide burner

The present invention relates to a gas burner, and more particularly to a low-nox burner capable of reducing the production of nitrogen oxides.

In general, nitrogen oxides are produced by fuel NOx produced by the oxidation of chemically bound nitrogen components in the fuel during combustion, and nitrogen in the combustion air is released at high temperature to remove nitrogen molecules in the combustion air. Thermal NOx produced by oxidation, and prompt NOx produced rapidly when hydrocarbon-based fossil fuel is exposed to high temperature in high concentration state.

Among these nitrogen oxides, in particular, the fuel rusty can not be controlled by the combustion technology, and therefore, the low-nox burner has a technical problem in preventing the formation of two nitrogen oxides, thermal and prompt knox.

Conventional low-nox burners (Patent No. 0784880) employ a Flue Gas Recirculation technique for recovering exhaust gases and mixing them into a flame. In order to increase the thermal rust reduction effect in such a conventional burner, it is important to increase the amount of exhaust gas attracted.

Therefore, it is required to further reduce the neck diameter of the janggu flame to increase the flow rate of the exhaust gas, so that the front end of the blast tube bent at a more sharp angle can be the direction of the design.

However, as the bending angle of the front end of the blast tube increases sharply, the flow of combustion air interferes with the ejection of fuel gas, resulting in a problem that the combustion state becomes unstable. Therefore, it is necessary to develop a new low knox burner capable of sharply bending the tip to reduce the diameter of the flame neck and achieving both a stable combustion state and good quality mixing by a right angle crossing.

The present invention has been made to solve the above problems, and an object of the present invention is to increase the tip angle of the blast tube so that the blowing speed of the combustion air does not interfere with the gas blowing so that the reduction of thermal rust generation is Of course, to achieve a stable combustion state.

The low-nox burner according to the present invention for achieving the above object forms an air supply passage and is branched from the fuel supply pipe installed through the burner body and the burner body mounted in the burner mounting hole of the combustion chamber, and disposed at the center of the burner body. A first fuel supply unit, an insulator plate coupled to the first fuel supply unit, a blast tube inserted into the burner mounting hole, and the tip is first bent in the inner diameter direction and then bent second to be parallel to the insulator plate; And a second fuel supply branch which is branched from the fuel supply pipe and disposed radially along the circumference of the first fuel supply section and whose ends are bent outwardly and spaced at regular intervals on the first bent surface of the blast tube.

Low-nox burner according to the present invention is disposed along the circumference of the blast tube and includes an exhaust gas induction portion for guiding the exhaust gas of the combustion chamber to the supply passage.

The low knox type burner according to the present invention further includes a third fuel supply branch which is branched from the fuel supply pipe and disposed radially along the circumference of the first fuel supply and whose end is disposed forward than the front end of the blast tube.

The tip of the blast tube is arranged forward than the end of the first fuel supply.

The first fuel supply has a plurality of fuel injection holes arranged radially.

An injection path is formed between the blast tube and the retaining plate.

The retaining plate is provided with a plurality of air blowing holes.

The retaining plate has a plurality of air slits.

According to the low-nox burner according to the present invention, even if the blowing speed of the combustion air is increased in order to increase the thermal knox reduction effect, the fuel gas ejection is not disturbed and the prompt knox reduction effect is not lowered, thereby further reducing the occurrence of the entire knox. It is effective.

1 is a cross-sectional view showing a low-nox burner according to an embodiment of the present invention.
2 is a partial perspective view showing a low-nox burner according to an embodiment of the present invention.
3 is a cross-sectional view showing a low rusty burner according to another embodiment of the present invention.
Figure 4 is a cross-sectional view showing a low-nox burner according to another embodiment of the present invention.
5 is a cross-sectional view showing a low-nox burner according to still another embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Note that, in the drawings, the same components are denoted by the same reference symbols as possible. Further, the detailed description of known functions and configurations that may obscure the gist of the present invention will be omitted. For the same reason, some of the components in the drawings are exaggerated, omitted, or schematically illustrated.

1 is a cross-sectional view showing a low knox type burner according to an embodiment of the present invention, Figure 2 is a partial perspective view showing a low knox type burner according to an embodiment of the present invention.

As shown, the low-nox burner 1000 according to the embodiment of the present invention, the burner body 1100, the first fuel supply unit 1200, the second fuel supply unit 1300, the blast tube ( 1400, a flame plate 1500, an exhaust gas induction unit 1600, and a fuel supply pipe 1700.

The burner body 1100 is mounted to the burner mounting hole 110 of the combustion chamber 100, and the blast tube 1400 is inserted into the burner mounting hole 110. An exhaust gas inducing unit 1600 to be described below is formed at one side of the blast tube 1400 so that the exhaust gas of the combustion chamber 100 smoothly flows into the burner body 1100. An air supply passage 1110 through which an air is supplied through a blower (not shown) is formed in the burner body 1100. The air flowing through the air supply passage 1110 of the burner main body 1100 is provided between the plurality of air ejection holes 1520 of the flameproof plate 1500, which will be described later, and the flameproof plate 1500 and the blast tube 1400. It is ejected through the injection furnace 1510 which is formed, and is supplied to the combustion chamber 100.

The first fuel supply unit 1200 is formed by branching from the fuel supply pipe 1700 installed through the burner main body 1100, and is disposed at the center of the blast tube 1400 so that the front end of the first fuel supply unit 1200 is positioned at the center of the flame plate 1500. It penetrates into the combustion chamber 100. A plurality of fuel injection holes 1210 are radially formed at an end portion of the first fuel supply unit 1200 drawn into the combustion chamber 100. In this case, the fuel injection holes 1210 are disposed at different positions along the axial direction of the first fuel supply unit 1200 so that the ejection of fuel is made uniform over a wide area. The fuel ejected through the fuel injection hole 1210 may be ejected in a direction orthogonal to the air ejected into the plurality of air ejection holes 1520 formed in the flame plate 1500 to implement a rapid mixing action of air and fuel.

While the end of the first fuel supply unit 1200 is drawn into the combustion chamber 100, the end of the first fuel supply unit 1200 is disposed to be located inside the blast tube 1400, and the front end of the blast tube 1400 to be described below is the first fuel supply unit 1200. Since the fuel is injected through the second fuel supply unit 1300, the fuel injected through the second fuel supply unit 1300 is mixed with the air supplied through the injection path 1510, and then, through the first fuel supply unit 1200. It is mixed once more with the fuel injected. Therefore, the fuel supplied to the combustion chamber 100 is more uniformly mixed with combustion air and combusted, whereby the prompt knox emissions in the exhaust gas are significantly reduced.

The second fuel supply unit 1300 is branched from the fuel supply pipe 1700, forms a circumference, surrounds the first fuel supply unit 1200, and is disposed inside the blast tube 1400. The fuel spouted at high speed through the second fuel supply unit 1300 is rapidly mixed with the air spouted at high speed through an injection path 1510 formed between the flame plate 1500 and the blast tube 1400. A high speed flame is formed by the injection furnace 1510, and the flame speed is very high, and after the flame is gradually reduced in width by fuel and air discharged along the tip of the blast tube 1400 bent in the inner diameter direction, It is formed in an enlarged form again.

An end portion of the second fuel supply unit 1300 is bent outwardly and spaced apart from the first bent surface of the blast tube 1400 at regular intervals. The fuel discharged through the second fuel supply unit 1300 is mixed at right angles with the combustion air in the blast tube 1400, and follows the second bent surface of the blast tube 1400 in a mixed state. The shaped flame will have a narrower neck. Therefore, even if the tip of the blast tube 1400 is bent at a sharp angle parallel to the intaglio plate 1500 in order to maximize the neck speed as much as possible, combustion air is ejected through the second fuel supply unit. The flame stability is not compromised since the ejection of fuel is not obstructed by combustion air. In addition, even if the blowing speed of the combustion air is increased in order to increase the thermal knox reduction effect, the fuel gas ejection is not hindered, so that the prompt knox reduction effect is not lowered, thereby reducing the generation of the entire knox.

The blast tube 1400 is inserted into the burner mounting hole 110 to mount the burner body 1100 to the combustion chamber 100. As shown in FIG. 1, the front end of the blast tube 1400 is first bent in the inner diameter direction, and is then bent second at an angle parallel to the flame plate 1500. In order to reduce the thermal temperature and reduce thermal rust, the exhaust gas must be recycled and mixed in the flame. For this, the tip of the blast tube was bent inwardly. Here, in order to further increase the amount of recirculation, when the air is bent at a sharper angle, for example, at a right angle, the flow of air flowing through the bent at the right angle obstructs the ejection of fuel to the front, causing the flame to become unstable. There is a problem. Therefore, the low-nox burner 1000 according to the embodiment of the present invention is formed by extending the tip so as to be perpendicular to the direction of the air flow from the tip bent in the inner diameter direction of the blast tube of the conventional low-nox burner secondary By bending, the recycle amount of the exhaust gas is increased. An injection path 1510 is formed between the blast tube 1400 and the flame plate 1500. Combustion air flowing through the air supply passage 1110 through the blower is supplied to the combustion chamber 100 at a high flow rate through the injection passage 1510 having a small area. In addition, the fuel supplied through the second fuel supply unit 1300 is injected into the injection path 1510 to rapidly mix with combustion air of a high flow rate, thereby significantly reducing the generation of prompt knox.

On the other hand, since a portion of the blast tube 1400 is introduced into the combustion chamber 100 by a predetermined length, the low pressure due to the high speed flame and the minimum diameter of the flame extends deep into the front end of the flame. The flame propagation speed is very fast at the minimum diameter portion of the flame, and the exhaust gas at the rear end portion of the flame is directed to the minimum diameter portion of the flame, and is introduced into the exhaust gas induction portion 1600 to be described later and mixed with combustion air. Accordingly, the exhaust gas of the combustion chamber 100 is mixed with combustion air and combusts with the fuel, thereby lowering the temperature of the flame and suppressing the occurrence of a local high temperature region in the combustion chamber 100.

By supplying a part of the exhaust gas, which is composed of no heat generation components, remaining in the combustion chamber 100 to the combustion air and supplying it to the combustion chamber 100, the temperature of the flame is lowered, so that the combustion air is carried out over the entire volume of the flame. By working uniformly, it is possible to reduce the occurrence of a region where the temperature of the flame is 1370 ℃ or more locally in the combustion chamber 100, and to reduce the generation of thermal knox generated by the release of nitrogen in the combustion air at a high temperature.

The flame plate 1500 is coupled to an end of the first fuel supply unit 1200, and a plurality of air ejecting holes 1520 are formed through which air in the air supply passage 1110 is ejected to the combustion chamber 100. The air supplied through the plurality of air blowing holes 1520 forms a plurality of high speed air streams, and vortices are generated around the plurality of high speed air streams, and the vortices uniformly mix fuel and air. Can be. Prompt rust, which is rapidly produced when hydrocarbon-based fossil fuels are exposed to high temperatures in high concentrations, is significantly reduced by this rapid and even mixing of air and fuel.

The exhaust gas inducing unit 1600 is disposed along the circumference of the blast tube 1400 and guides the exhaust gas of the combustion chamber 100 to the air supply passage 1110. The tip of the blast tube 1400, which is bent inward, is bent at an angle parallel to the flame plate 1500 such that the minimum diameter of the flame is further retracted toward the blast tube 1400. Therefore, the distance between the exhaust gas induction unit 1600 disposed along the circumference of the blast tube 1400 and the minimum diameter portion of the flame is closer to each other, and the exhaust gas induced by the high speed flame to the minimum diameter portion of the flame is adjacent to the exhaust gas induction portion. It is introduced into the 1600 is mixed with the combustion air and burned again. By burning together with exhaust gas with little heat generation, the temperature of the flame is further lowered, and as described above, the occurrence of a particularly localized high temperature region is considerably reduced, and the reduction of thermal knox is considerable.

The fuel supply pipe 1700 is installed through the burner body 1100 and branched to form a first fuel supply unit 1200 and a second fuel supply unit 1300. The first fuel supply unit 1200 and the second fuel supply unit 1300 may receive fuel from one fuel supply pipe 1700 and eject the fuel into the combustion chamber.

3 is a cross-sectional view showing a low rusty burner according to another embodiment of the present invention.

As shown, the low-nox burner 2000 according to another embodiment of the present invention includes a third fuel supply unit 2800.

The third fuel supply unit 2800 is branched from the fuel supply pipe 2700, forms a circumference, surrounds the first fuel supply unit 2200, and is disposed inside the blast tube 2400. An end portion of the third fuel supply unit 2800 is disposed to be advanced than the front end of the blast tube 2400 and deeply introduced into the combustion chamber 100 from the blast tube 2400. The third fuel supply unit 2800 prevents the fuel from being concentrated and ejected only toward the center of the flame, thereby preventing the flame from coalescing to the center. The fuel supplied to the combustion chamber 100 through the third fuel supply unit 2800 is ejected to the combustion chamber 100 through the third fuel injection hole 2810 formed at the end of the third fuel supply unit 2800. The fuel injection hole 2810 is formed as shown in FIG. 3 so that fuel is supplied to the flame outer portion having a relatively low temperature rather than the core portion having a high temperature in the flame. Since the temperature of the outer portion of the flame is lower than 1000 DEG C, especially when fuel is supplied to this portion, the generation of prompt knox caused by the high concentration of fuel reaching the high temperature region is significantly reduced. In addition, since fuel is prevented from being ejected only to the center part, flames are prevented from clustering only into the core part.

On the other hand, the burner main body 2100, the air supply passage 2110, the first fuel supply unit 2200, the fuel injection hole 2210, the second fuel supply unit 2300, the blast tube 2400, The flame plate 2500, the injection passage 2510, the air blowing hole 2520, the exhaust gas induction portion 2600, and the fuel supply pipe 2700 are similar to the configuration and operation of Figs. Omit.

Figure 4 is a cross-sectional view showing a low-nox burner according to another embodiment of the present invention.

As shown, the low-nox burner 3000 according to another embodiment of the present invention includes a plurality of air slits 3530 in the flame plate 3500.

The flame plate 3500 having the air slit 3530 has a larger through-hole area than the air ejection hole 1520, so that the combustion air receives less resistance when ejected and is rotated so that the air is swirled. do. The flame plate 3500 having the air slit 3530 instead of the air blow hole 1520 has a flame plate 1500 having an air blow hole 1520 to increase the amount of combustion air when the pressure of the blower is low. It may be provided in place of, and in particular, it is preferable to be used in the water blowing boiler having a low blowing pressure rather than the furnace tube type boiler having a high blowing pressure.

On the other hand, the burner main body 3100, the air supply passage 3110, the first fuel supply unit 3200, the fuel injection hole 3210, the second fuel supply unit 3300, the blast tube 3400, The flame plate 3500, the injection path 3510, the exhaust gas induction part 3600, and the fuel supply pipe 3700 are similar to those in FIGS. 1 and 2, and thus detailed descriptions thereof will be omitted.

5 is a cross-sectional view showing a low-nox burner according to still another embodiment of the present invention.

As shown, the low-nox burner 4000 according to another embodiment of the present invention includes a third fuel supply unit 4800 and includes a plurality of air slits 3530 in the flame plate 3500.

Burner main body 4100, air supply passage 4110, first fuel supply unit 4200, fuel injection hole 4210, second fuel supply unit 4300, blast tube 4400, flame plate 4500, injection path 4510, air slit 4530, exhaust gas guide part 4600, fuel supply pipe 4700, third fuel supply part 4800, and third fuel injection hole 4810. 3 is similar to the configuration and operation of FIGS. 1 to 3, and thus a detailed description thereof will be omitted.

It should be noted that the embodiments of the present invention disclosed in the present specification and drawings are only illustrative of the present invention in order to facilitate the understanding of the present invention and are not intended to limit the scope of the present invention. It will be apparent to those skilled in the art that other modifications based on the technical idea of the present invention are possible in addition to the embodiments disclosed herein.

100: combustion chamber
110: burner installation work
1000, 2000, 3000, 4000: burner
1100, 2100, 3100, 4100: burner body
1110, 2110, 3110, 4110: Supply passage
1200, 2200, 3200, 4200: primary fuel supply unit
1210, 2210, 3210, 4210: fuel injection
1300, 2300, 3300, 4300: secondary fuel supply unit
1400, 2400, 3400, 4400: Blast Tube
1500, 2500, 3500, 4500: Inflammatory board
1510, 2510, 3510, 4510: spraying furnace
1520, 2520: Air Blower
3530. 4530: Air slit
1600, 2600, 3600, 4600: exhaust gas induction part
1700, 2700, 3700, 4700: Fuel supply pipe
2800, 4800: 3rd fuel supply
2810, 4810: 3rd fuel injection hole

Claims (8)

A burner body which forms an air supply passage and is mounted in a burner mounting hole of a combustion chamber;
A first fuel supply part branched from a fuel supply pipe installed through the burner main body and disposed at the center of the burner main body;
Inflammation plate and coupled to the first fuel supply unit,
The blast tube is inserted into the burner mounting hole, the front end is first bent in the inner diameter direction and then bend secondary to be parallel to the flame plate;
A second fuel supply part branched from the fuel supply pipe and disposed radially along a circumference of the first fuel supply part, and having an end portion bent outwardly and spaced apart at regular intervals from a first bent surface of the blast tube; Low-nox burner characterized by the above-mentioned. The method of claim 1,
It is disposed along the circumference of the blast tube, the low-nox burner, characterized in that it comprises an exhaust gas inducing unit for guiding the exhaust gas of the combustion chamber to the air supply passage. The method of claim 1,
And a third fuel supply part branched from the fuel supply pipe and disposed radially along a circumference of the first fuel supply part, the third fuel supply part of which an end is disposed forward of the front end of the blast tube. 4. The method according to any one of claims 1 to 3,
And the front end of the blast tube is disposed forward of the first fuel supply unit. 4. The method according to any one of claims 1 to 3,
And the first fuel supply unit includes a plurality of fuel injection holes disposed radially. 4. The method according to any one of claims 1 to 3,
Low-nox burner, characterized in that the injection path is formed between the blast tube and the retaining plate. 4. The method according to any one of claims 1 to 3,
The flame plate is a low-nox burner, characterized in that it comprises a plurality of air blowing holes. 4. The method according to any one of claims 1 to 3,
The flame plate is a low-nox burner, characterized in that it comprises a plurality of air slits.

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