KR101971588B1 - A heating medium boiler having reburning combustor reducing nitrogen oxide - Google Patents

Abstract

The present invention is characterized in that a plurality of small fuel lean / fuel rich flames are formed on the entire end surface of the combustor, the fuel nozzles being formed at the center and having a plurality of fuel nozzles completely separated, (NOx) in which the exhaust gas generated in the combustion chamber is recycled. The simple structure can realize a basic combustion system without requiring a peripheral device, and a small-sized split flame (NOx) can be remarkably reduced through heat dispersion and reduction of flame temperature, formation of optimized air-fuel ratio of each small flame, and induction of fast combustion reaction.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a heating medium boiler including a reheat-reducing nitrogen oxide burner,

The present invention relates to a heat medium boiler, and more particularly to a heat medium boiler comprising a plurality of small fuel lean / fuel rich flames formed by a plurality of completely separated fuel nozzles, And a combustor which is formed over the entire cross section and minimizes nitrogen oxides (NOx) by recirculating the exhaust gas generated from the reheat combustion flame and the flame.

The industrial heating medium boiler is a structure in which a special synthetic oil is circulated inside the body and a burner is installed at the central part of one side of the body. When the burner is ignited, the outside air is ignited, -3 The smoke emitted and discharged through the outside of the pipe is discharged through the communication pipe.

A combustor for supplying energy to the heating medium boiler is a burner for reducing nitrogen oxides. The combustor for controlling the mixing characteristics of fuel and air, the oxygen concentration in the combustion region, and the flame temperature are controlled. In the system.

Through this process, the optimized combustor can cope with various regulations on air pollutants due to current environmental problems and it is applied to almost all industries that generate energy by using combustion system.

Currently, domestic and foreign N2OX is limited to entering the market when it is not a low NOx combustor in terms of emission concentration regulation, total amount regulation, conversion to fine dust. In addition, lower NOx regulations are anticipated, and low NOx performance has the greatest effect on market share.

In order to reduce nitrogen oxide, which is an environmental pollutant, combustion techniques that are currently generally applied include technologies such as fuel and air multi-stage technology, exhaust gas recirculation technology, combustion gas internal recirculation technology, reheat combustion, OFA and the like. However, these combustion techniques require additional external devices and require a complicated structure of peripheral devices. Therefore, in order to overcome the disadvantages of the above-described techniques, research and development for integrating and optimizing various combustion techniques have been widely carried out both domestically and internationally.

On the other hand, a heat medium boiler, which includes a combustor in which a plurality of small fuel lean / fuel rich flames are formed by a plurality of fuel nozzles, There is no way.

Korean Patent Registration No. 10-096857 discloses a fuel injection module including a primary fuel injector and two or more secondary fuel injectors disposed around the primary fuel injector. An air injection module for supplying an oxidant to the fuel injection module; And a fuel supply module for supplying fuel to the fuel injection module, wherein the secondary fuel injection body is radially disposed on a circumference around the primary fuel injection body, Wherein a primary space is formed and a secondary space is formed from the secondary fuel injection body spaced apart from the primary space to form a multistage flame. However, it can not be confirmed that a fuel nozzle is formed at the center and a plurality of fuel lean / fuel rich flames are formed.

Korean Patent Registration No. 10-1512352 discloses a fuel injection system comprising a primary fuel injector for injecting a main fuel into a combustion furnace, at least one or more fuel injectors arranged around the primary fuel injector, A recirculating induction portion for recirculating the combustion gas generated in the combustion furnace to the combustion furnace by a hydrodynamic force, a fuel supply portion for supplying fuel to the primary fuel injector and the secondary fuel injector, An oxidant supplier for supplying an oxidant to a space between the primary fuel injector and the secondary fuel injector, and an air multi-stage sleeve arranged to surround the primary fuel injector for the air multi-stage, Wherein the oxidant supplied from the supply unit is supplied in multiple stages through the inner and outer portions of the air multi-stage sleeve. It has set forth. However, it can not be confirmed that a fuel nozzle is formed at the center and a plurality of fuel lean / fuel rich flames are formed.

Thus, a plurality of small-sized fuel lean / fuel rich flames are formed on the entire end surface of the combustor by a plurality of fuel nozzles formed with a main fuel nozzle at the center and completely separated, There is no proposed heating medium boiler technology including a combustor in which the exhaust gas is recycled to minimize nitrogen oxides (NOx).

(Patent Document 0001) Korean Patent Registration No. 10-096857

(Patent Document 0002) Korean Patent Registration No. 10-1512352

SUMMARY OF THE INVENTION It is an object of the present invention to solve the above-mentioned problems of the prior art and the technical problems required from the past.

SUMMARY OF THE INVENTION It is an object of the present invention to overcome the above-mentioned drawbacks of the inventors of the present invention by carrying out in-depth research and various experiments. The object of the present invention is to provide a fuel- lean / fuel rich flame is formed in the entire end face of the combustor, and the total flame has an excess air ratio of between 1.0 and 1.2, which is optimized on the average energy efficiency, so that the combustion is carried out at an optimized excess air ratio at a low flame temperature .

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are not intended to limit the invention to the precise form disclosed. There will be.

In order to achieve the above object, the present invention provides a heating medium boiler including a heating medium circulation line and a low nitrogen oxide combustor for heating a heating medium, housing; A fuel supply unit installed in the housing and having a plurality of fuel flow paths having fuel nozzles coupled to one end thereof; An air injecting portion having a plurality of air holes through which the fuel nozzle is drawn and passed; A fuel control unit for controlling fuel injected into the fuel passage; An air control unit for controlling air introduced into the housing; Wherein the air injection unit comprises: a perforated plate in which the air holes are formed in an annular shape in the combustion chamber direction; Wherein one of the fuel passages to which the fuel nozzle is coupled includes a main fuel nozzle formed at a central portion of the perforated plate, and the inner circumferential size of one of the air holes and the inner circumferential size of the other one of the air holes are different from each other. Nitrogen oxides combustors; A fuel nozzle for a reburn provided on one side of the combustion chamber; And a complete combustion induction module for completely burning the unburned fraction and / or CO at the rear end of the combustion chamber.

When the ratio (L _F / L _B ) of the flame length (L _F ) to the length of the combustion chamber (L _B ) is 0.1 to 0.3 or less, the main fuel nozzle (L _MF ) is located at the end of the flame, 5 to 20 wt% can be sprayed.

When the ratio (L _F / L _B ) of the flame length (L _F ) to the combustion chamber length (L _B ) is greater than 0.1 to 0.3, the main fuel nozzle (L _MF ) And 5-20 wt% of the total fuel can be injected.

When the ratio (L _F / L _B ) of the flame length (L _F ) to the length of the combustion chamber (L _B ) is 0.1 to 0.3 or less, 5 to 20 wt% of the total fuel is injected into the first fuel nozzle for the reburn .

If the ratio (L _F / L _B ) of the flame length (L _F ) to the length of the combustion chamber (L _B ) is greater than 0.1 to 0.3, 5 to 20 wt% of the total fuel is injected into the second fuel nozzle can do.

Further, when the ratio (L _F / L _B ) of the length (L _B ) of the combustion chamber to the length (L _F ) of the flames formed is greater than 0.1 to 0.3, air can be injected into a part of the second fuel nozzles have.

Further, the combustion induction module may be a mesh structure.

In addition, the combustion induction module may include a heated body that is formed in a shape orthogonal to the exhaust gas passing direction of the combustion chamber, a shape capable of flowing into the mesh structure, and a heating unit for heating the heated body.

Further, the material to be heated may have a shape of any one of spherical, polygonal, amorphous, and linear shapes.

Further, the material to be heated may be a thermally conductive material.

In addition, the combustion induction module may be configured such that a plurality of ropes coated with ceramics or ceramics intersect with each other in such a manner that the ship of the combustion chamber is orthogonal to the gas passing direction.

The rope may have a heat resistance of 1200 to 1600 占 폚, a specific gravity of 0.2 to 0.5, and a diameter of 6 to 20 mm.

Further, the heating body is a ferroelectric body. Barium titanate.

Further, the heating means may be a high frequency generator.

In addition, a spiral or concave / convex heat transfer element for heat transfer may be additionally formed in the exhaust gas and / or the heat medium passage.

As described above, the effect of the present invention with the above-described configuration is that a basic combustion system can be implemented without a peripheral device as a simple constitution.

In addition, there is an effect that nitrogen oxides (NOx) can be remarkably reduced through heat dispersion through a small split flame, lowered flame temperature, optimized air-fuel ratio flame formation, exhaust gas recirculation, and quick combustion reaction induction.

Further, there is an effect that control of the combustion condition according to the amount of load through the main fuel nozzle is facilitated.

It should be understood that the effects of the present invention are not limited to the above effects and include all effects that can be deduced from the detailed description of the present invention or the configuration of the invention described in the claims.

Figure 1 is a graph of the correlation between nitrogen oxide and excess air ratio.
2 is a perspective view of a low nitrogen oxide combustor in accordance with an embodiment of the present invention.
3 is a cross-sectional view of a low nitrogen oxide combustor in accordance with an embodiment of the present invention.
4 is a cross-sectional view of an air injecting unit and a fuel nozzle according to an embodiment of the present invention.
5 is an operational state diagram of a low nitrogen oxide combustor according to an embodiment of the present invention.
6 is a cross-sectional view of a low NOx combustor in accordance with an embodiment of the present invention and an enlarged view of a burned-in air nozzle.
7 is a view of a boiler according to an embodiment of the present invention.
8 is thermal characteristic data of heat medium oil according to an embodiment of the present invention.
9 is a graph of thermal conductivity (kcal / m hr) according to temperature of a heat medium oil according to an embodiment of the present invention.
10 is a graph showing specific heat (kcal / kg DEG C) according to temperature of a heat medium oil according to an embodiment of the present invention.
11 is a conceptual diagram of a flame formation in a combustion chamber according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the detailed description of known functions and configurations incorporated herein will be omitted when it may unnecessarily obscure the subject matter of the present invention.

The same reference numerals are used for portions having similar functions and functions throughout the drawings. Throughout the specification, when a part is connected to another part, it includes not only a case where it is directly connected but also a case where the other part is indirectly connected with another part in between. In addition, the inclusion of an element does not exclude other elements, but may include other elements, unless specifically stated otherwise.

The present invention will be described in detail with reference to the drawings.

FIG. 2 is a perspective view of a low-nitrogen oxide combustor according to an embodiment of the present invention, and FIG. 3 is a graph showing the relationship between the nitrogen oxide and the excess air ratio in the low- Fig.

As shown in FIGS. 2 and 3, the low nitrogen oxide combustor of the present invention includes a housing 300; A fuel supply unit 100 installed in the housing 300 and having a plurality of fuel flow paths 110 to which fuel nozzles 120 are coupled at one end; An air injector (200) having a plurality of air holes (210) through which the fuel nozzle (120) is drawn and passed; A fuel control unit 510 for controlling the fuel injected into each of the fuel flow paths 110; And an air control unit 520 for controlling the air to be introduced into the housing 300. The air control unit 520 is coupled to the fuel passage 110 to control the center axis of the air injection unit 200 formed at the housing 330, And a main fuel nozzle 130 formed in the main fuel nozzle 130.

That is, the inner peripheral size of one of the air holes and the inner peripheral size of the other of the air holes may be different from each other.

The one fuel nozzle 120 and the one air hole 210 may be formed as a pair. The ratio of the fuel injected into the fuel nozzle and the air injected from the air hole may be an excess air ratio of between 1.0 and 1.2.

A small flame 400 is formed by a pair of the fuel nozzle 120 and the air hole 210. Further, a main flame is formed by the main fuel nozzle to generate a heat amount required by the boiler.

The main flame and the whole flames by a plurality of small flames have an excess air ratio of between 1.0 and 1.2, which energy efficiency is optimized on average as shown in Fig. 1, so that combustion is performed at an optimized excess air ratio at a low flame temperature .

That is, in the low nitrogen oxide combustor according to the present invention, the main flame and the plurality of small flames 400 can perform combustion at an optimum air-fuel ratio even at a low temperature, thereby remarkably reducing the nitrogen oxide produced during combustion.

The number of fuel dispersions is the same as the number of the main fuel nozzles 130 and the fuel nozzles 120, and the number of the fuel nozzles 120 may vary depending on application conditions such as heat input amount, fuel type, and the like.

The main fuel nozzle is formed in the outer cylinder center portion formed by the air hole, the main fuel injection hole 134 formed at the rear end of the main fuel nozzle, and the small portion of the main fuel injection hole may be formed with the throttling portion 131 .

An inner main fuel nozzle 132 and an inner air nozzle 133 may be formed at an inlet side of the throttle portion and an air inlet 135 may be formed at a side of the main fuel injection port.

The housing 300 can perform the function of a wind box.

In the embodiment of the present invention, it is described that the air introduction by the air control unit 520 is performed on the side surface of the housing 300, but the present invention is not limited thereto and the air introduction direction may be changed.

FIG. 4 is a cross-sectional view of an air injector 200 and a fuel nozzle 120 according to an embodiment of the present invention, and FIG. 5 is a view illustrating an operation of a low nitrogen oxide combustor according to an embodiment of the present invention. 5 is an operational state diagram for a cross section of a low nitrogen oxide combustor, and the right side view of FIG. 5 is an operational state diagram for a front view of a low nitrogen oxide combustor.

3 and 4, the fuel nozzle 120 may penetrate the air hole 210 while being spaced apart from the inner periphery of the air hole 210 by a predetermined distance so as to form the air passage 211 . Further, the main fuel nozzle 130 may be formed at the center.

Here, the air passage 211 may be the remaining space of the air hole 210 except for the space occupied by the fuel nozzle 120. In the air hole 210, air can be passed through the air passage 211 and injected in the direction of the combustion chamber.

As described above, when the sizes of the inner peripheries of the air holes 210 are different, the sizes of the air passages 211 may be different from each other.

The diameter of the fuel flow path 110 may be the same as the diameter of the air flow path 211.

4, the small flame 400 formed by the pair of the fuel nozzles 120 and the air and the air injected from the air holes 210 is divided into a fuel rich flame 410 having a low air- And a fuel lean flame 420 having a high air-fuel ratio. Further, the main flame formed by the fuel injected from the main fuel nozzle and the air injected from the air holes arranged in an annular shape can be formed in the center portion.

That is, due to the difference in air injection quantity depending on the size of the air flow passage 211, the small flame 400 is rich in fuel so that the fuel becomes rich (fuel rich) at a low air-fuel ratio compared with the fuel nozzle 120 that injects the same amount of fuel, The flame 410 and the fuel lean can be divided into the fuel lean flame 420 having a high air-fuel ratio.

D _OF / D _{IA, which} is the ratio of the outer diameter (D _OF ) of the fuel nozzle 120 to the inner diameter (D _IA ) of the air hole 210, may be 0.99 to 0.01.

D _OF / D _{IA, which} is the ratio of the outer diameter (D _OF ) of the fuel nozzle to the inner diameter (D _IA ) of the air hole, may be 0.99 to 0.01.

If the ratio of the outer diameter (D _OF ) of the fuel nozzle to the inner diameter (D _IA ) of the air hole deviates, a smooth combustion condition may not be formed or a large amount of nitrogen oxides may be generated.

The outer diameter (D _OF ) of the fuel nozzle may be the same. The combustion condition can be controlled by adjusting the inner diameter of the air hole while keeping the outer diameter of the plurality of fuel nozzles corresponding to the fuel supply unit having the plurality of fuel flow paths constant.

When the fuel supplied under the thermal load condition of 80,000 kcal / hr based on the heat load is limited to LNG, the linear velocity of supplied air may be 10 to 50 m / sec. Preferably 30 to 40 m / sec.

If the above conditions are exceeded, a smooth combustion condition is not formed or nitrogen oxide suppression suitable for a load condition can not be achieved.

When a plurality of fuel rich flames 410 and a plurality of fuel lean flames 420 are formed to form an entire flame, as shown in FIG. 1, the entire flame has an excess air ratio of 1.0 to 1.2 And the temperature of the entire flame is also lowered, so that the nitrogen oxide can be reduced.

Two or more air holes 210 whose inner circumferential sizes are different from each other may be alternately arranged.

Accordingly, the fuel rich flame 410 and the fuel lean flame 420 can be alternately arranged.

In the arrangement of the small flames 400, when the fuel rich flames 410 are concentrated in one direction and the fuel leash flames 420 are concentrated in the other direction, The flame may not be uniform.

In addition, the entire flame can be uniformed or the calorific value required of the boiler can be controlled through the main flame formed from the fuel dispersed from the main fuel nozzle.

If the entire flame is not uniform, the combustion efficiency may be lowered, so that the fuel rich flame 410 and the fuel lean flame 420 may be alternately arranged and installed to obtain a uniformly formed flame.

The air holes 210 may be arranged in an annular shape. Specifically, a plurality of arbitrary air holes 210 may be concentrically arranged from the center of the air injection portion 200.

Here, a plurality of air holes 210 having the same inner circumferential diameter may be continuously arranged along one circumference on one concentric circle. Or a plurality of air holes 210 having different inner circumferential diameters may be successively disposed along one circumference on one concentric circle.

The fuel rich flame 410 and the fuel lean flame 420 may be arranged in an annular shape.

The small flame 400 formed by the fuel nozzle 120 and the air hole 210 may be preferably arranged annularly to form a uniformly uniform whole flame.

However, the present invention is not limited to this, and it is also possible to arrange them in a hexagonal shape and a polygonal shape by external factors such as the use of the combustor and the installation position.

The air injection portion 200 may be replaceable.

The air-fuel ratio of the fuel rich flame 410 or the fuel lean flame 420 may vary depending on the use of the combustor, the installation environment of the combustor, the installation type of the combustor, and the like.

Accordingly, in order to vary the air-fuel ratio of the fuel rich flame 410 or the fuel lean flame 420, the diameter of each air hole 210 is different from that of the air injector 200 before the replacement, The air injection unit 200 can be replaced.

When the air nozzles 210 are exchanged for different air injectors 200 with different diameters, the respective air passages 211 are different, and the air supply amount to each fuel nozzle 120 is changed, The air-fuel ratio of the small flame 400 may be varied.

The air hole 210 may have a swivel for counterboring.

The swirler can be installed at a portion where air is introduced into the air hole 210. Alternatively, the swirler may be formed on the inner surface of the air hole 210 forming the air passage 211.

In the embodiment of the present invention, the air holes 210 are circular, but the present invention is not limited thereto, and may be formed in an elliptic or polygonal shape.

In the embodiment of the present invention, in order to differentiate the air-fuel ratio of the small flames 400 with a simple structure, the diameter of the air holes 210 forming a pair with the fuel nozzles 120 for injecting the same amount of fuel, So that the air-fuel ratio is different.

However, the present invention is not limited thereto, and each of the fuel nozzles 120 can inject fuel by differentiating the fuel concentration.

To this end, the fuel control unit 510 may supply different amounts of fuel to the respective fuel flow paths 110 to form the small flames 400 having different air-fuel ratios.

Although the small flame 400 is divided into the fuel rich flame 410 and the fuel lean flame 420 in the embodiment of the present invention, the plurality of fuel rich flames 410 also have different air-fuel ratios, The fuel lean flame 420 may also have different air-fuel ratios.

5, the tip end L _MF of the main fuel nozzle may be 0.1 to 20 times the outer diameter (D _OMF ) of the main fuel nozzle with respect to the end of the air injection part.

The tip (L _F ) of the fuel nozzle may be 0.1 to 20 times the outer diameter (D _OF ) of the fuel nozzle with respect to the end of the air injecting portion.

6 is a cross-sectional view of a low NOx combustor according to an embodiment of the present invention and an enlarged view of a combustion-completed air injection port 310. FIG.

5, the low nitrogen oxide combustor of the present invention is a gap between the inner surface of the housing 300 and the outer portion of the air injecting portion 200, and the combustion complete air (overfire air) 311) is injected into the combustion chamber.

housing; A fuel supply unit installed in the housing and having a plurality of fuel flow paths having fuel nozzles coupled to one end thereof; An air injecting portion having a plurality of air holes through which the fuel nozzle is drawn and passed; A fuel control unit for controlling fuel injected into the fuel passage; An air control unit for controlling air introduced into the housing; And the air injecting portion includes a perforated plate in which the air holes are formed in an annular shape in the direction of the combustion chamber, and the inner perimeter of one of the air holes and the inner perimeter of the other of the air holes are different from each other. Characterized by a nitrogen oxide combustor.

Further, an exhaust gas recirculation unit for recirculating exhaust gas after combustion to the combustion chamber may be additionally formed.

The exhaust gas recirculation unit may inject a part of the exhaust gas that has passed through the heat exchange unit at the rear end of the combustion chamber into the combustion chamber.

In addition, the exhaust gas may be introduced through one or more of the air injection unit, the fuel control unit, and the combustion chamber.

In addition, an exhaust gas spout 150 containing the air holes introduced into the combustion chamber and injecting the exhaust gas may be additionally formed.

The exhaust 150 may protrude from the surface of the perforated plate 140.

Further, the exhaust gas spout may be formed protruding from the center of the perforated plate in the outer direction. The exhaust gas may be larger than the width outer portion of the spot (W _FO) the width of the center (W _FI). Preferably, the ratio W _FI / W _FO of the width W _FO of the outer portion to the width W _FI of the center portion may be from 0.99 to 0.3. More preferably from 0.8 to 0.5. If the ratio is exceeded, the circulation region due to the exhaust gas is not smoothly formed inside, and the suppressing effect of nitrogen oxides may be lowered.

Further, the recirculated exhaust gas may be 80 to 250 캜.

Further, the exhaust gas holes and / or the exhaust gas slits may be formed evenly spaced in the circumferential direction of the combustion chamber.

Also, the flow rate ratio of the exhaust gas injected into the air injecting unit, the fuel control unit, and the combustion chamber may be 1: 0.01 to 0.1: 0.1 to 0.5.

The laminating flow unit 320 may be provided at the end of the housing 300 in the direction of spraying the combustion completion air 311 and may provide a curved flow path to the combustion completion air 311.

The laminar flow section 320 includes a curved member 321 for guiding the combustion completion air 311 discharged along the periphery of the housing 300 to be discharged toward the center of the combustion chamber, Shaped member 322 that provides a vortical flow to the combustion-completed air 311 that is coupled and discharged along the circumference of the end of the combustion zone 311.

The combustion completion air 311 supplied from the combustion completion air injection port 310 acts as an oxidant for the entire flame and proceeds to a path near the outer surface of the entire flame, that is, the inner surface of the combustion chamber, It flows in the form of wrapping the whole flame and can function to oxidize unburned hydrocarbons or carbon monoxide which may occur at the end of the entire flame.

2 and 5, when the housing 300 is formed in a cylindrical shape, a combustion-completed air injection opening 310 is formed in a ring shape around the outer periphery of the circular air injection portion 200 .

The ring-shaped member 321 having a curved inner surface may be coupled to the end of the housing 300 in the form of a ring so that the ring-shaped member 322 having a circular cross section may be provided so as to be formed by cutting a part of the tube .

Here, the space between the outer surface of the ring-shaped member 322 and the inner surface of the curved member 321 can provide a curved flow path to the combustion completion air 311. [

The radius of curvature of the inner surface of the curved member 321 and the radius of curvature of the ring member 322 may be different.

The laminar flow portion 320 may be formed by the curved member 321, the ring-shaped member 322, and the curved flow path.

The combustion-completed air 311 that has passed through the laminar flow section 320 is increased in fluidity in the straight direction by the laminar flow, and the oxidizer function as described above can be efficiently performed.

When the radius of curvature of the inner surface of the curved member 321 or the radius of curvature of the end surface of the ring-shaped member 322 is adjusted to change the size of the curved flow path, the flow rate or flow rate of the combustion completion air 311 can be adjusted.

It goes without saying that the ring-shaped member 322 can be replaced for the purpose of adjusting the flow rate or the flow rate of the combustion completion air 311.

The low nitrogen oxide combustor of the present invention may further include an exhaust gas hole or an exhaust gas slit for exhaust gas recirculation in the combustion chamber. An exhaust gas hole or an exhaust gas slit may be provided on the side surface of the housing 300.

The exhaust gas in the closed combustion chamber can be recirculated through the exhaust gas hole or the exhaust gas slit by being injected from the high-pressure combustion chamber into the relatively low-pressure housing 300, mixed with air and injected.

Although the exhaust gas holes or the exhaust gas slits are provided on the side surfaces of the housing 300 in the embodiment of the present invention, the exhaust gas holes or the exhaust gas slits are not necessarily provided, and the exhaust gas holes or the exhaust gas slits are installed in the air control unit 520 It may be mixed with the supplied air and supplied.

7 shows a boiler according to an embodiment of the present invention. The exhaust gas which has undergone the heat exchange in the heat exchanging part 13 consisting of the post-combustion heating medium tube 11 in the boiler is branched at the rear end of the heat exchanging part and the supply flow rate thereof is regulated by the exhaust gas damper 10, Lt; RTI ID = 0.0 > air. ≪ / RTI >

It is clear that the exhaust gas supplied to the combustor according to the combustion condition can be variously changed in the input conditions.

The mixed combustion air is supplied to the combustor through the first pressurized blower 3 and the flow rate can be controlled by the first air damper 6 for combustion. The mixed combustion air may be partially branched and supplied into the combustion chamber through the second combustion air damper (7). At this time, an exhaust gas hole and / or an exhaust gas slit may be formed in the combustion chamber.

A heating medium boiler comprising a heating medium circulation line and a low nitrogen oxide combustor for heating a heating medium, the heating medium boiler comprising: a housing; A fuel supply unit installed in the housing and having a plurality of fuel flow paths having fuel nozzles coupled to one end thereof; An air injecting portion having a plurality of air holes through which the fuel nozzle is drawn and passed; A fuel control unit for controlling fuel injected into the fuel passage; An air control unit for controlling air introduced into the housing; A low nitrogen oxide combustor characterized in that an inner peripheral size of one of the air holes and an inner peripheral size of the other one of the air holes are different from each other; And a first temperature sensor for measuring a heating medium temperature of the boiler inlet portion; A second temperature sensor for measuring the temperature of the heating medium at the boiler outlet; And a combustion controller for comparing the temperature values of the first temperature sensor and the second temperature sensor to control the operation of the low nitrogen oxide combustor.

The combustion control unit may stop the operation of the low nitrogen oxide combustor when the temperature of the heating medium at the boiler outlet is not less than the high temperature reference point and the heating medium temperature of the boiler inlet is not less than the high temperature reference point, Characterized in that air and / or exhaust gas alone is injected into the nitrogen oxide combustor.

The high temperature reference point may be from 200 ° C to 700 ° C. Preferably 250 < 0 > C to 500 < 0 > C. More preferably 300 < 0 > C.

If the temperature condition is exceeded, a smooth heat transfer does not occur.

The combustion control unit operates the low nitrogen oxide combustor at an excess air ratio of 1.0 or less when the heating medium temperature at the boiler inlet portion is at or below the low temperature reference point when the heating medium temperature at the boiler outlet portion is between the high temperature reference point and the low temperature reference point, The low-nitrogen oxide combustor is operated at an excess air ratio of 1.0 or higher.

The low temperature reference point may be 100 ° C to 300 ° C. Preferably 150 ° C to 280 ° C. More preferably 230 < 0 > C.

If the temperature condition is exceeded, a smooth heat transfer does not occur.

When the temperature of the heating medium at the boiler inlet portion is higher than the high temperature reference point, the combustion control portion operates the low nitrogen oxide combustor at an excess air ratio of 1.0 or less, and when the heating medium temperature at the boiler inlet portion is lower than the high temperature reference point The low-nitrogen oxide combustor is operated at an excess air ratio of 1.0 or higher.

In addition, it is obvious that the same operation control can be performed by measuring the pressure condition of the boiler inlet / outlet of the heat medium oil by using a pressure sensor and setting a predetermined high pressure condition and a low pressure condition.

The fuel nozzle may be formed to pass through the air hole while being spaced apart from the inner periphery of the air hole by a predetermined distance so that an air passage is formed.

Further, two or more of the above-described air holes having different inner circumferential sizes may be alternately arranged.

Further, air holes having any one or more of a plurality of circular, elliptical, and polygonal shapes having different inner circumferential diameters from each other can be continuously arranged along the circumference on one or more concentric circles.

The apparatus may further include a combustion-completed air injection port through which the combustion-completed air is injected as a gap between the inner surface of the housing and the outer periphery of the air injection portion.

In addition, it is also possible to use a pressurized blower for supplying combustion air through the combustion air supply passage of the low nitrogen oxide combustor, a combustion air passage for introducing air into the pressurized blower from the air intake port, A flue gas circulation passage introduced into the combustion air passage, an exhaust gas circulation damper provided in the exhaust gas circulation passage, and a combustion air damper provided in the combustion air supply passage.

The exhaust gas recirculation damper is closed at the time of high load combustion of the low nitrogen oxide combustor while the exhaust gas circulating damper is maintained at a predetermined opening degree at the time of low load combustion of the low nitrogen oxide combustor to operate the high nitrogen load Wherein a difference in the blowing rate of the combustion air from the burner of the combustion device during combustion operation is reduced to maintain a good combustion state during the low combustion operation.

A heating medium boiler comprising a heating medium circulation line and a low nitrogen oxide combustor for heating a heating medium, the heating medium boiler comprising: a housing; A fuel supply unit installed in the housing and having a plurality of fuel flow paths having fuel nozzles coupled to one end thereof; An air injecting portion having a plurality of air holes through which the fuel nozzle is drawn and passed; A fuel control unit for controlling fuel injected into the fuel passage; An air control unit for controlling air introduced into the housing; Wherein the air injection unit comprises: a perforated plate in which the air holes are formed in an annular shape in the combustion chamber direction; Wherein one of the fuel passages to which the fuel nozzle is coupled includes a main fuel nozzle formed at a central portion of the perforated plate, and the inner circumferential size of one of the air holes and the inner circumferential size of the other one of the air holes are different from each other. Nitrogen oxides combustors; Fuel nozzles (20, 21) for reheat combustion formed on one side of the combustion chamber; And a complete combustion induction module (22) for completely burning unburned fraction and / or CO at the rear end of the combustion chamber.

The main fuel nozzle 130, the first fuel damper 18 for the reburn, the second fuel damper 19 for the reburn, the first fuel nozzle 20 for the reburn, the second fuel for the reburn 20, One or more of the nozzles 21 may be formed.

The plurality of first fuel nozzles for the reburn burner may be formed. The width L _RF between the plurality of first fuel nozzles may be equal or equal to L _RF1 = L _RF2 .

The second fuel nozzle for the reburn burner may be formed in a plurality of units. The width L _G between the plurality of second fuel nozzles may be equal or equal to the gap L _G1 = L _G2 .

When the ratio (L _F / L _B ) of the flame length (L _F ) to the length of the combustion chamber (L _B ) is 0.1 to 0.3 or less, the main fuel nozzle (L _MF ) is located at the end of the flame, 5 to 20 wt% can be sprayed.

It is obvious that the flame length can be predicted through the sensor. The sensor may be a temperature sensor.

If the above conditions are exceeded, a fuel-rich region is formed by spraying hydrocarbon water (for example, LNG) to the downstream portion of the flame, and the effect of reducing nitrogen oxides in the combustion chamber that reduces NO in the exhaust gas to N ₂ can not be obtained .

When the ratio (L _F / L _B ) of the flame length (L _F ) to the combustion chamber length (L _B ) is greater than 0.1 to 0.3, the main fuel nozzle (L _MF ) And 5-20 wt% of the total fuel can be injected.

When the ratio (L _F / L _B ) of the flame length (L _F ) to the length of the combustion chamber (L _B ) is 0.1 to 0.3 or less, 5 to 20 wt% of the total fuel is injected into the first fuel nozzle for the reburn .

If the ratio (L _F / L _B ) of the flame length (L _F ) to the length of the combustion chamber (L _B ) is greater than 0.1 to 0.3, 5 to 20 wt% of the total fuel is injected into the second fuel nozzle can do.

Further, when the ratio (L _F / L _B ) of the length (L _B ) of the combustion chamber to the length (L _F ) of the flames formed is greater than 0.1 to 0.3, air can be injected into a part of the second fuel nozzles have.

Further, the combustion induction module may be a mesh structure.

In addition, the combustion induction module may include a heated body that is formed in a shape orthogonal to the exhaust gas passing direction of the combustion chamber, a shape capable of flowing into the mesh structure, and a heating unit for heating the heated body.

Further, the material to be heated may have a shape of any one of spherical, polygonal, amorphous, and linear shapes.

Further, the material to be heated may be a thermally conductive material.

The thermally conductive material may be a ceramic material. Preferably, it may be any one or a mixture of two or more of alumina, silica, silicon nitride, zirconia, titanium dioxide, and yttria.

And a material coated with a ceramic coating material comprising a solvent, nano graphite, colloidal silica, colloidal alumina, a polyester silicone composite resin, a mixture of alumina, zirconia, titanium dioxide and yttria, and a silicone oil polymer have.

In addition, the combustion induction module may be configured such that a plurality of ropes coated with ceramics or ceramics intersect with each other in such a manner that the ship of the combustion chamber is orthogonal to the gas passing direction.

The rope may have a heat resistance of 1200 to 1600 占 폚, a specific gravity of 0.2 to 0.5, and a diameter of 6 to 20 mm.

If the condition is exceeded, complete combustion of CO or the like can not be achieved.

Further, the heating body is a ferroelectric body. Barium titanate.

The ferroelectric may be a material having a polarization itself without an external electric field. Preferably aluminum oxide, titanium oxide, ceramic, barium titanate (BaTiO3).

Further, the heating means may be a high frequency generator.

In addition, a spiral or concave / convex heat transfer element for heat transfer may be additionally formed in the exhaust gas and / or the heat medium passage.

It will be understood by those skilled in the art that the foregoing description of the present invention is for illustrative purposes only and that those of ordinary skill in the art can readily understand that various changes and modifications may be made without departing from the spirit or essential characteristics of the present invention. will be.

It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. For example, each component described as a single entity may be distributed and implemented, and components described as being distributed may also be implemented in a combined form.

The scope of the present invention is defined by the appended claims, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included within the scope of the present invention.

1: Boiler
2: Economizer
3: First pressurized blower
4: air supply path
5: Exhaust gas circulation passage
6: first air damper for combustion
7: second air damper for combustion
8: Third air damper for combustion
9: Second pressurized blower
10: Exhaust gas damper
11: heating medium tube
12: Flue gas recirculation part
13: Heat exchanger
14: first temperature sensor
15: second temperature sensor
16: first pressure sensor
17: Second pressure sensor
18: First fuel damper for reburn
19: Second fuel damper for reburn
20: First fuel nozzle for reburn
21: Second fuel nozzle for reburn
22: Complete combustion induction module
100: fuel supply unit
110: fuel flow path
120: Fuel nozzle
130: main fuel nozzle
140: Perforated plate
150:
200:
210: air hole
211: air flow
300: housing
310: Combustion completed air nozzle
311: Combustion complete air
320: laminar flow
321: Curved member
322: ring member
400: Small flame
410: fuel rich flame
420: Fuel Lean Flame
510: fuel control unit
520:
600:
700: heat medium storage tank

Claims (15)

A heating medium boiler comprising a heating medium circulation line and a low nitrogen oxide combustor for heating a heating medium,
housing;
A fuel supply unit installed in the housing and having a plurality of fuel flow paths having fuel nozzles coupled to one end thereof;
An air injecting portion having a plurality of air holes through which the fuel nozzle is drawn and passed;
A fuel control unit for controlling fuel injected into the fuel passage;
An air control unit for controlling air introduced into the housing;
Wherein the air injection unit comprises: a perforated plate in which the air holes are formed in an annular shape in the combustion chamber direction;
Wherein one of the fuel passages to which the fuel nozzle is coupled includes a main fuel nozzle formed at a central portion of the perforated plate,
A low nitrogen oxide combustor in which an inner peripheral size of one of the air holes and an inner peripheral size of the other one of the air holes are different from each other;
A fuel nozzle for a reburn provided on one side of the combustion chamber;
And a complete combustion induction module for completely burning unburned fraction and / or CO at the rear end of the combustion chamber,
Further comprising a combustion-completed air ejecting opening through which combustion-completed air is ejected as a gap between an inner surface of the housing and an outer periphery of the air ejecting portion,
Further comprising a laminar flow section provided at an end of the housing in the combustion-completed air injection direction and providing a curved flow path to the combustion-completed air,
Wherein the laminar flow portion includes a curved member for guiding the combustion completion air discharged along the periphery of the housing to be discharged toward the center of the combustion chamber, And a ring-shaped member for providing a vortex flow in the heat-generating body.
delete delete delete delete delete The method according to claim 1,
Wherein the combustion induction module is a mesh structure.
The method of claim 7,
Wherein the combustion induction module is formed in a shape orthogonal to an exhaust gas passing direction of the combustion chamber and includes a heating body having a shape capable of flowing in the mesh structure and a heating means for heating the heating body. Boiler.
The method of claim 8,
Wherein the object to be heated is at least one of a sphere, a polygonal shape, an amorphous shape, and a linear shape.
The method of claim 9,
Wherein the heating target is a thermally conductive material.
The method of claim 7,
Wherein the combustion induction module is configured such that a plurality of ropes coated with ceramics or ceramics cross each other in the form that the ship of the combustion chamber is orthogonal to the gas passing direction.
The method of claim 11,
Wherein the rope has a heat resistance of 1200 to 1600 占 폚, a specific gravity of 0.2 to 0.5, and a diameter of 6 to 20 mm.
The method of claim 8,
Wherein the material to be heated is barium titanate which is a ferroelectric material.
The method of claim 8,
Wherein the heating means is a high-frequency generator.
The method according to claim 1,
And a spiral or concave / convex type heat transfer element for heat transfer is additionally formed in the exhaust gas and / or the heat medium passage.

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