KR102465873B1 - Flameless combustion boiler - Google Patents

Abstract

The present invention is a boiler housing 100; And a burner 200 communicating with the inside of the boiler housing 100; The boiler housing 100 includes a main combustion chamber 110 in which flameless combustion is performed; a heat exchange chamber 120 located on one side of the main combustion chamber 110, communicating with the main combustion chamber 110, and having heat exchange particles 121 inside; a partition wall 130 positioned between the main combustion chamber 110 and the heat exchange chamber 120 and having a hole 131 formed therein; And a heat exchanger 140 located inside the boiler housing 100 and penetrated through the main combustion chamber 110 and the heat exchange chamber 120; combustion in the main combustion chamber 110 The generated exhaust gas (G) is moved to the heat exchange room 120 along the hole 131, providing a boiler.

Description

Flameless combustion boiler

The present invention relates to flameless combustion boilers.

Recently, due to the government's environmental policy, environmental regulations of thermal power plants have become stricter, and in particular, interest in reducing NOx and SOx related to fine dust is increasing.

In the case of industrial boilers, measures to reduce NOx are in progress due to the government's low-NOx burner supply project and fine dust countermeasure policy, but improvement of the combustion system itself and technology development are still insufficient, and emissions by direct combustion as well as industrial use In the case of pollutant reduction facilities, NOx reduction related to fine dust is urgently needed.

Conventionally, a technique for controlling flame temperature through FGR (Flue gas recirculation, exhaust gas recirculation) for flame temperature control and controlling Thermal-NOx generated by oxidation of nitrogen in the air through this has been commercialized. For FGR, an FGR fan should be used, but due to the limitations of the fan, a low temperature exhaust gas of about 350 to 400 degrees must be used, causing instability of the flame and limiting the operating range.

In particular, in the case of a low NOx burner, there is a limitation in suppressing NOx emission, and there is a problem accompanied by vibration and noise. In addition, in the case of environmental facilities using the direct combustion method, the reduction rate for removal targets (eg, VOCs) is very high, but there is a problem in that NOx emissions due to flames inevitably increase.

(Patent Document 1) Japanese Unexamined Patent Publication No. 2007-078331

(Patent Document 2) Korean Patent Registration No. 10-1360515

(Patent Document 3) Korean Patent Publication No. 10-2018-0133456

The present invention has been made to solve the above problems.

Specifically, the present invention is to control Thermal-NOx, reduce CO and NOx emissions, and maximize combustion efficiency by using the FGR method.

In addition, the present invention is to provide a heat exchange room inside the boiler to uniformly maintain the temperature inside the main combustion chamber, reduce thermal fatigue, and expand the heat exchange area compared to conventional commercial boilers.

In addition, the present invention is to provide a heat exchange room inside the boiler, so that combustion stability is secured even after switching to flameless combustion, thereby reducing sensitivity according to changes in operating conditions.

One embodiment of the present invention for solving the above problems, the boiler housing 100; And a burner 200 communicating with the inside of the boiler housing 100; The boiler housing 100 includes a main combustion chamber 110 in which flameless combustion is performed; a heat exchange chamber 120 located on one side of the main combustion chamber 110, communicating with the main combustion chamber 110, and having heat exchange particles 121 inside; a partition wall 130 positioned between the main combustion chamber 110 and the heat exchange chamber 120 and having a hole 131 formed therein; And a heat exchanger 140 located inside the boiler housing 100 and penetrated through the main combustion chamber 110 and the heat exchange chamber 120; combustion in the main combustion chamber 110 The generated exhaust gas (G) is moved to the heat exchange room 120 along the hole 131, providing a boiler.

In one embodiment, the partition wall 130 is located under the main combustion chamber 110, the heat exchange chamber 120 is located below the partition wall 130, and the burner 200 is located in the heat exchange chamber. It is inserted upward into the inside of 120, and its end may communicate with the main chamber 110.

In one embodiment, the heat exchanger 140, the inlet 141 into which the heating medium (M) is introduced; and an outlet 142 through which the heating medium M is discharged. Including, the heating medium (M) may flow from the heat exchange chamber 120 to the side of the main combustion chamber 110.

In one embodiment, an insulator C may be positioned inside the boiler housing 100.

In one embodiment, the heat exchange room 120 includes an exhaust gas outlet 122 formed to be in fluid communication with the outside of the boiler housing 110, and the exhaust gas (G) generated in the main combustion chamber 110 is The exhaust gas may pass through the chamber 110, the hole 131, and the heat exchange chamber 120 and be discharged to the exhaust gas outlet 122.

In one embodiment, heat is exchanged with the heat exchange particles 121 in the heat exchange chamber 120 using exhaust gas (G) burned in the main combustion chamber 110 and introduced into the heat exchange chamber 120. The fuel F and the oxidizer A supplied into the main combustion chamber 110 may be heated simultaneously.

In another embodiment of the present invention for solving the above problems, the heat exchange chamber 120 is located on the side of the main combustion chamber 110, and the heat exchange chamber 120 is provided in two or more plural, The main combustion chamber 110 may be located between the heat exchange chambers 120 .

In one embodiment, the heat exchanger 140 is provided in plurality, and one of the heat exchangers 140 is formed to be connected from one of the heat exchange chambers 120 to the main combustion chamber 110, Another one of the heat exchanger 140 may be formed to be connected from the other one of the heat exchange chamber 120 to the main combustion chamber 110 .

According to the present invention, the following effects are achieved.

The present invention uses the FGR method to control Thermal-NOx, reduce CO and NOx emissions, and maximize combustion efficiency.

In addition, the present invention provides a heat exchange room inside the boiler, so that the temperature inside the main combustion chamber can be uniformly maintained, and thermal fatigue can be reduced and the heat exchange area can be enlarged compared to conventional commercial boilers. Accordingly, since the internal temperature of the main combustion chamber can be maintained at about 800 to 1000 degrees, inexpensive materials can be applied, and thus costs can be reduced, and maintenance costs due to reduced thermal fatigue can be reduced.

In addition, the present invention is provided with a heat exchange room inside the boiler, so that combustion stability is secured even after switching to flameless combustion, and sensitivity to changes in operating conditions can be reduced. .

In addition, a verification experiment was conducted to confirm that NOx and CO emissions were reduced in flameless combustion, and as a result, it was confirmed that the temperature of the combustion chamber was uniform and NOx and CO emissions were reduced in the flameless combustion stage.

1 to 3 are views for explaining a boiler according to an embodiment of the present invention.
4 and 5 are views for explaining a boiler according to another embodiment of the present invention.
6 is a view for explaining that flameless combustion occurs in the boiler according to the present invention.
7 is a view for explaining changes in NO concentration and CO concentration generated during combustion in the boiler according to the present invention.

In some cases, in order to avoid obscuring the concept of the present invention, well-known structures and devices may be omitted or may be shown in block diagram form centering on core functions of each structure and device.

In addition, in describing the embodiments of the present invention, if it is determined that a detailed description of a known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description will be omitted. In addition, terms to be described later are terms defined in consideration of functions in the embodiment of the present invention, which may vary according to the intention or custom of a user or operator. Therefore, the definition should be made based on the contents throughout this specification.

The boiler according to the present invention includes a boiler housing 100 and a burner 200.

Referring to Figures 1 to 5, the boiler of the present invention will be described.

The boiler housing 100 includes a main combustion chamber 110, a heat exchange chamber 120, a partition wall 130, and a heat exchanger 140.

The main combustion chamber 110 is provided inside the boiler housing 100 and is a space where an oxidizing agent A and a fuel F are supplied from a burner 200 to be described later, and combustion takes place.

In the main combustion chamber 110, an oxidizing agent (A) and a fuel (F) are supplied from a burner (200), and the oxidizing agent (A) and the fuel (F) meet and are combusted. Exhaust gas (G) generated after combustion in the main combustion chamber 110 is recirculated inside the main combustion chamber 110, and flameless combustion occurs in the main combustion chamber 110. A detailed description of this will be given later.

At this time, the fuel F and the oxidizer A supplied into the main combustion chamber 110 may be simultaneously heated by the heat of the exhaust gas G.

At this time, since the internal temperature of the main combustion chamber 110 is maintained at about 800 degrees to about 1000 degrees, the flame is stable and the generation of Thermal-NOx can be controlled. A detailed description of this will be given later.

The main combustion chamber 110 is located on one side of a heat exchange chamber 120 to be described later.

The heat exchange chamber 120 is provided inside the boiler housing 100 and communicates with the main combustion chamber 110 .

The heat exchange chamber 120 is in the form of a packed bed, and heat exchange particles 121 are provided inside the heat exchange chamber 120 .

Heat exchange with the heat exchange particles 121 may be performed using the exhaust gas G flowing into the heat exchange chamber 120 .

Since the heat exchange particles 121 are provided inside the heat exchange chamber 120, the temperature and heat of the exhaust gas G transmitted from the main combustion chamber 110 can be preserved.

Accordingly, flames can be maintained in the main combustion chamber 110 by the heat of the heat exchange chamber 120 .

In addition, heat exchange particles 121 are provided inside the heat exchange chamber 120 to prevent the exhaust gas (G) from moving to the heat exchange chamber 120 after being burned in the main combustion chamber 110, and the heat exchange chamber ( The differential pressure between the heat exchange chamber 120 and the main combustion chamber 110 increases compared to when the heat exchange particles 121 are not provided inside the 120. Accordingly, the exhaust gas flowing through the main combustion chamber 110 (G ) can be maximized, and the generation of high-temperature nitrogen oxides can be suppressed by controlling the flame temperature by maximizing the recirculation inside the main combustion chamber 110 without a separate exhaust gas recirculation facility. Therefore, the burden of facilities and costs for treating nitrogen oxides is reduced.

At this time, the size and shape of the provided heat exchange particles 121 may be changed.

The heat exchanging particles 121 may be formed of a material suitable for receiving heat energy and transferring it back, and in one embodiment, the heat exchanging particles 121 may be formed of a ceramic material or the like.

The heat exchange particles 121 may be filled with a medium such as ceramic balls or sand, but are not limited thereto.

An exhaust gas outlet 122 is formed on one side of the heat exchange chamber 120 .

The exhaust gas (G) discharged from the main combustion chamber 110 flows into the heat exchange chamber 120, and the flowing exhaust gas (G) flows through the exhaust gas outlet 122 formed on one side of the heat exchange chamber 120, the boiler housing It can be discharged to the outside of (100). Referring to FIGS. 1 and 2 , a partition wall 130 is positioned below the main combustion chamber 110 , and a heat exchange chamber 120 is positioned below the partition wall 130 . That is, the main combustion chamber 110 and the heat exchange chamber 120 are positioned perpendicular to the ground.

At this time, referring to another embodiment of the present invention, the partition wall 130 is located on the side of the main combustion chamber 110, and the heat exchange chamber 120 is located on the side of the partition wall 130. That is, the main combustion chamber 110 and the heat exchange chamber 120 are positioned horizontally with respect to the ground. This will be described later.

The partition wall 130 is located between the main combustion chamber 110 and the heat exchange chamber 120, and a hole 131 is formed therein.

That is, exhaust gas G discharged from the main combustion chamber 110 is moved to the heat exchange chamber 120 through the hole 131 formed in the partition wall 130 .

At this time, the partition wall 130 is in the form of a plate in which the hole 131 is formed, and may separate the main combustion chamber 110 and the heat exchange chamber 120, but is not limited thereto.

At this time, the number of holes 131 formed in the barrier rib 130 is not limited to the number shown.

In addition, an insulator C may be positioned inside the boiler housing 100 .

An insulator C may be positioned inside the boiler housing 100 between the main combustion chamber 110 and the heat exchange chamber 120 .

As the insulator C is positioned, heat inside the main combustion chamber 110 and the heat exchange chamber 120 can be prevented from leaking out to the outside of the boiler housing 100, so that the main combustion chamber 110 and the heat exchange chamber ( 120) can further preserve the internal temperature.

Accordingly, it is possible to quickly heat the heating medium (M) to be described later, and recirculation of the exhaust gas (G) in the main combustion chamber 110 can be maximized.

At this time, the type of heat insulator (C) to be positioned is not limited to a specific type.

The burner 200 communicates with the inside of the boiler housing 100 and supplies fuel F and an oxidizing agent A to the inside of the boiler housing 100 .

Referring to FIGS. 1 and 2 , the burner 200 may be inserted into the heat exchange chamber 120 and communicate with the main combustion chamber 110 .

That is, the fuel (F) and the oxidizer (A) flowing into the burner 200 are moved to the main combustion chamber 110 through the heat exchange chamber 120, and the preheated fuel (F) passing through the heat exchange chamber 120 ) and an oxidizing agent may be supplied to the main combustion chamber 110.

The location of the burner 200 is preferably determined so that the generated flame can be located in the center of the main combustion chamber 110.

At this time, referring to another embodiment of the present invention, the burner 200 is inserted into the main combustion chamber 110. This will be described later.

The heat exchanger 140 is located inside the boiler housing 100.

The heat exchanger 140 may be continuously connected to the inside of the main combustion chamber 110 and the heat exchange chamber 120 .

The heat exchanger 140 includes an inlet 141 and an outlet 142 at both ends.

The heating medium M is introduced from the inlet 141, flows along the inside of the heat exchanger 140, and then flows out through the outlet 142.

A heating medium M having a low temperature is injected into the inlet 141 , and the heating medium M having a high temperature by heating the heating medium M in the heat exchanger 140 flows out through the outlet 142 .

The inlet 141 is formed on the heat exchange chamber 120 side, and the outlet 142 is formed on the main combustion chamber 110 side. That is, the heating medium M is introduced from the heat exchange chamber 120 side into the inlet 141 .

As the inlet 141 is formed on the heat exchange chamber 120 side, the heating medium M having a low temperature may be first heated in the heat exchange chamber 120 . In particular, since the heat exchange chamber 120 is provided with heat exchange particles 121, the heat exchange efficiency is high and it can be quickly heated. Thereafter, the heating medium M previously heated in the heat exchange chamber 120 is introduced into the main combustion chamber 110, and the heating medium M may be further heated to a high temperature in the main combustion chamber 110.

Conventionally, when the low-temperature heating medium (M) flows into the main combustion chamber 110, it is difficult to maintain a flame-free state in the main combustion chamber 110, but in the present invention, the heating medium (M) has already ), this problem can be solved, and unsafe operation due to heat exchange in the main combustion chamber 110 can be prevented.

At this time, the heating medium (M) may be water, but is not limited thereto.

At this time, since flameless combustion occurs in the main combustion chamber 110, the installed heat exchanger 140 has a uniform spatial heat distribution and can be installed over a wide area.

At this time, the structure and size of the heat exchanger 140 is not limited to the bar shown, and may exist in various forms.

Referring to FIG. 3, a boiler according to the present invention is shown in 3D. However, the boiler according to the present invention is not limited to the shape and size shown.

Referring to FIGS. 4 and 5, another embodiment of the present invention in which the heat exchange chamber 120 is located on the side of the main combustion chamber 110 will be described, and structural differences that differ from the above-described embodiment will be mainly described. .

In another embodiment of the present invention, the partition wall 130 is located on the side of the main combustion chamber 110, and the heat exchange chamber 120 is located on the side of the partition wall 130. In addition, the heat exchange chamber 120 has two or more plural is provided with

Hereinafter, it is assumed that the heat exchange chamber 120 is formed of two.

Heat exchange chambers 120 are positioned on both sides of the main combustion chamber 110, and the above-described partition wall 130 is formed between the heat exchange chamber 120 and the main combustion chamber 110.

The burner 200 is formed by being inserted into the main combustion chamber 110 .

The exhaust gas (G) generated in the main combustion chamber 110 flows into each heat exchange chamber 120 and is discharged through the exhaust gas outlet 122 .

The heat exchanger 140 may be provided in plurality.

For example, two heat exchangers 140 may be provided, and one of the heat exchangers 140 may be connected from one of the heat exchange chambers 120 to the main combustion chamber 110 .

The other one of the heat exchanger 140 may be formed to be connected from the other one of the heat exchange chamber 120 to the main combustion chamber 110 .

The inlet 141 of the heat exchanger 140 may be located on the heat exchange chamber 120 side, and the outlet 142 may be located on the main combustion chamber 110 side.

At this time, the number and arrangement of the provided heat exchangers 140 are not limited to those shown in the drawings as described above.

At this time, when the heat exchange chamber 120 is formed in two, the size and number of the heat exchange particles 121 located in the heat exchange chamber 120 is one heat exchange chamber 120, compared to the above-described embodiment, They may be smaller in size and larger in number. Alternatively, the initial speeds of the oxidizing agent A and the fuel F supplied from the burner 200 may be higher than those of the above-described embodiment.

At this time, after the exhaust gas (G) is discharged from the main combustion chamber 110 at a certain concentration or higher, the heat exchange chamber 120 is located on both sides of the main combustion chamber 110 compared to the above-described embodiment. Heat is not discharged to the outside, and the temperature can be better preserved.

Referring to Figs. 6 and 7, it will be described that no flame is generated in the main combustion chamber 110, and the generation of NO and CO at this time is reduced.

6 is a diagram for explaining that flameless combustion occurs.

Referring to A-A' of FIG. 6 (a), conventional combustion occurs when 2400 s has elapsed after combustion in the main combustion chamber 110. Referring to FIG. 6(b) showing the heat distribution in the main combustion chamber 110 at this time, the combustion area in the main combustion chamber 110 at A-A' shows a central aspect.

Referring to BB' of FIG. 6 (a), flameless combustion occurs when 7200 s has elapsed after combustion in the main combustion chamber 110. Referring to FIG. 6(b) showing the heat distribution in the main combustion chamber 110 at this time, the combustion area is uniformly distributed in the main combustion chamber 110 at BB'.

Accordingly, it can be seen that the temperature inside the main combustion chamber 110 is uniformly distributed in flameless combustion.

7 is a graph showing changes in NO concentration and CO concentration with time in the main combustion chamber 110.

In general, as the temperature increases, CO emissions decrease, and NOx emissions increase in proportion to the temperature. Therefore, CO and NOx emissions are in inverse proportion to each other.

Referring to FIG. 7 , in the conventional combustion section, CO shows a tendency to initially increase and then decrease, but NOx increases in proportion to temperature, showing that CO and NOx emissions are in inverse proportion. At this time, when 2400 s has elapsed after combustion in the main combustion chamber 110, NOx is detected as a high value of 53 ppm, and CO is detected as 4.2 ppm.

In flameless combustion, the temperature inside the main combustion chamber 110 is maintained uniformly, and both CO and NOx emissions are reduced. It is detected as a high value in ppm, and 3.6 ppm of CO is detected, and in the case of NOx, it can be seen that 87% of NOx is reduced in flameless combustion compared to conventional combustion.

Therefore, since flameless combustion is implemented in the main combustion chamber 110 according to the present invention, both CO and NOx can be reduced.

In the above, the present specification has been described with reference to the embodiments shown in the drawings so that those skilled in the art can easily understand and reproduce the present invention, but this is only exemplary, and those skilled in the art can make various modifications and equivalents from the embodiments of the present invention. It will be appreciated that embodiments are possible. Therefore, the scope of protection of the present invention should be defined by the claims.

100: boiler housing
110: main room
120: heat exchange room
121: heat exchange particles
122: exhaust gas outlet
130: bulkhead
131: hall
140: heat exchanger
141: inlet
142: outlet
200: burner
A: oxidizing agent
G: flue gas
F: fuel
C: Insulation
M: heating medium

Claims (7)

Boiler housing 100; and
A burner 200 communicating with the inside of the boiler housing 100; including,
The boiler housing 100,
A main combustion chamber 110 in which flameless combustion is performed;
a heat exchange chamber 120 located on one side of the main combustion chamber 110, communicating with the main combustion chamber 110, and having heat exchange particles 121 inside;
a partition wall 130 positioned between the main combustion chamber 110 and the heat exchange chamber 120 and having a hole 131 formed therein; and
A heat exchanger 140 located inside the boiler housing 100 and penetrated through the main combustion chamber 110 and the heat exchange chamber 120;
Exhaust gas (G) generated by combustion in the main combustion chamber 110 is moved to the heat exchange chamber 120 along the hole 131,
The partition wall 130 is located on the side of the main combustion chamber 110, and the partition wall 130
The heat exchange room 120 is located on the side,
The heat exchange chamber 120 is provided in a plurality of two or more, and the main combustion chamber 110 is located between the heat exchange chambers 120.
Boiler.
delete According to claim 1,
The heat exchanger 140,
an inlet 141 through which the heating medium M is introduced; and
an outlet 142 through which the heating medium M is discharged; including,
The heating medium (M) flows from the heat exchange chamber 120 to the main combustion chamber 110,
Boiler.
According to claim 1,
The heat exchange room 120 includes an exhaust gas outlet 122 formed to be in fluid communication with the outside of the boiler housing 110,
Exhaust gas (G) generated in the main combustion chamber 110 passes through the main combustion chamber 110, the hole 131 and the heat exchange chamber 120 and is discharged to the exhaust gas outlet 122,
Boiler.
According to claim 1,
Using the exhaust gas (G) burned in the main combustion chamber 110 and introduced into the heat exchange chamber 120,
Heat exchange with the heat exchange particles 121 is performed in the heat exchange chamber 120,
Boiler.
delete According to claim 1,
The heat exchanger 140 is provided in plurality,
One of the heat exchangers 140 is formed to be connected from one of the heat exchange chambers 120 to the main combustion chamber 110,
The other one of the heat exchanger 140 is formed to be connected from the other one of the heat exchange chamber 120 to the main combustion chamber 110.
Boiler.

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