KR101879083B1 - Furnance and power generation system - Google Patents

Abstract

A first combustion chamber having a first combustion space formed therein; An air supply unit having air supply means for supplying combustion air to the first combustion chamber so as to form a swirling flow in the first combustion space; A second combustion chamber formed above the first combustion chamber and forming a second combustion space communicating with the first combustion space; And a cooling air fan for cooling the second combustion chamber to form a swirling flow in the second combustion chamber and supplying the combustion air cooled in the second combustion chamber to cool the wall surface of the second combustion chamber, And a fisher.

Description

FURNANCE AND POWER GENERATION SYSTEM [0002]

The present invention relates to a combustor and a modular power generation system.

It should be noted that the contents described in this section merely provide background information on the present invention and do not constitute the prior art.

Generally cogeneration power generation can be composed of incineration facilities, power generation facilities, and environmental facilities.

Generally, small-scale cogeneration power generation is a diesel power generation using liquefied fuel such as gas power generation using high-volatile gas and heavy oil.

Solid fuel and waste resource fuels are used for medium and large sizes of more than 10MW. The internal volume of the incineration chamber is designed to be large so that many fuels can be simultaneously burned due to the low calorific value of the fuel compared to gas or liquefied fuel.

In order to use solid fuels or waste resource fuels in small cogeneration facilities, the size of the incinerator should be reduced to close to that of gas-fired or liquefied fuel combustors, and production costs should be reduced to similar levels.

In addition, the main use of small-scale cogeneration facilities that use solid fuels or waste resource fuels as a fuel source is installed in jungle, remote book, and depraved areas, which are rich in waste resources and difficult to be connected with electricity.

Therefore, in the case of a small cogeneration facility that uses solid fuel or waste resource fuel as a fuel source, the facility must be made compact because it must be able to be conveniently transported, installed and operated in an undersea region.

However, in the conventional case, there is a problem that a large amount of time and cost are required for installation and construction because a steel structure or the like needs to be installed over a large area when constructing a cogeneration plant, have.

Generally, when the cogeneration plant is installed, the area where the combustion boiler is installed and the area where the turbine is installed are distant from each other, so that there is a problem that heat loss is much generated when the steam pipe is connected.

Therefore, it is necessary to develop a compact power generation system that can minimize the heat loss between the combustion boiler and the turbine.

Japanese Laid-Open Publication No. 2016-023640

As one aspect of the present invention, there is provided a combustor and a power generation system capable of maximizing the mixing effect of combustion air to improve efficiency.

As one aspect of the present invention, there is provided a combustor and a power generation system in which the power generation system is modularized and is easily transferred to the site and installed.

According to an aspect of the present invention, there is provided a fuel cell system including a first combustion chamber having a first combustion space formed therein; An air supply unit having air supply means for supplying combustion air to the first combustion chamber so as to form a swirling flow in the first combustion space; A second combustion chamber formed above the first combustion chamber and forming a second combustion space communicating with the first combustion space; And a cooling air fan for cooling the second combustion chamber to form a swirling flow in the second combustion chamber and supplying the combustion air cooled in the second combustion chamber to cool the wall surface of the second combustion chamber, And a fisher.

Preferably, the air supply unit may include a plurality of air supply units disposed in one direction of the first combustion chamber.

Preferably, the air supply unit includes a first air supply unit installed in an upper region of the first combustion chamber and having a first air supply unit for supplying combustion air so as to form a downward swirling flow in the first combustion space; And a second air supply unit installed in a lower region of the first combustion chamber and configured to supply combustion air so as to form an upward swirling flow in the first combustion space, And the second air supply means may be disposed in one direction of the first combustion chamber.

Preferably, the first air supply portion includes: the first air supply means for supplying combustion air through the lower side portion of the upper region of the first combustion chamber; A first air flow passage which surrounds an upper region of the first combustion space and has an upward swirl flow; And a first guide member guiding the combustion air discharged into the first combustion space through a discharge port formed at an upper end of the first air flow path to be pivoted downward, The second air supply means for supplying the combustion air through the upper side portion of the lower region of the combustion chamber; And a second air passage provided in a shape surrounding the lower region of the first combustion space and formed with a downward swirling flow.

Preferably, the cooling air fan supplies the cooled combustion air through the upper side portion of the second combustion chamber so that an upward swirling flow is formed in the second combustion space; A cooling passage provided in a shape surrounding the second combustion chamber and having a downward swirling flow; And a guide vane for guiding the combustion air cooled in the second combustion space to be discharged through a discharge port spaced apart in a circumferential direction on a lower inner wall of the cooling passage.

Preferably, the guide vane may include a first guide vane that is spaced apart from the lower inner wall of the cooling passage in a circumferential direction, and is connected to the discharge port; And a second guide vane that is spaced apart from the lower outer wall of the cooling passage in the circumferential direction and is formed to be inclined toward the inner wall of the cooling passage.

Preferably, the air supply means and the cooling air fan may be arranged in one direction of the first combustion chamber.

According to another aspect of the present invention, there is provided a power generation system including at least a plurality of power generation modules including a combustor, a boiler, a generator, and an accessory equipment, And the receiving module includes a first receiving module in which the combustor according to any one of claims 1 to 7 of the power generating modules is disposed; And a second receiving module installed above the first receiving module and having a cavity member connected to at least the upper side of the combustor of the power generating module and a boiler connected to the combustor via the cavity member, Power generation system.

Preferably, the cavity member is connected to the upper side of the second combustion chamber of the combustor, and the other side is connected to the boiler to form a flow path in a bent direction.

Preferably, the receiving module may further include a third receiving module installed on the front surface of the first receiving module, wherein the generator receiving the steam is connected to the boiler via a steam pipe.

According to an embodiment of the present invention as described above, since the cooling air fan includes the cooling air fan for supplying the combustion air cooled to form the swirling flow in the second combustion space of the second combustion chamber, It is possible to maximize the mixing effect and improve the efficiency of the combustor and the power generation system.

According to an embodiment of the present invention, there is an effect that the power generation system is modularized and is easily transferred and installed to the site.

1 is a perspective view of a combustor according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view showing a state in which the combustor of FIG. 1 is formed with a swirling flow in the first combustion chamber by an air supply unit. FIG.
Fig. 3 is a cross-sectional view showing a state in which the combustor of Fig. 1 is formed with a swirling flow in the second combustion chamber by a cooling air bearing portion. Fig.
4 is a perspective view of a second combustion chamber and a cooling air bearing portion of a combustor according to an embodiment of the present invention.
5 is a plan view showing a state in which a swirling flow in the first combustion chamber is formed by the air supply unit.
Fig. 6 is a plan view showing a state in which a swirling flow in the second combustion chamber is formed by the cooling air bearing portion. Fig.
7 is a perspective view illustrating a power generation system according to an embodiment of the present invention.
8 is a front view of a combined state of the first accommodating module and the second accommodating module installed over one and two layers of the power generation system of Fig.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. However, the embodiments of the present invention can be modified into various other forms, and the scope of the present invention is not limited to the embodiments described below. Further, the embodiments of the present invention are provided to more fully explain the present invention to those skilled in the art. The shape and size of elements in the drawings may be exaggerated for clarity.

Hereinafter, a combustor 10 according to an embodiment of the present invention will be described in detail with reference to the drawings.

1 to 6, a combustor 10 according to an embodiment of the present invention may include a first combustion chamber 500, an air supply unit, a second combustion chamber 800, and a cooling air unit 900 .

A first combustion chamber S1 having a first combustion space S1 formed therein and a second combustion chamber S2 having a first combustion chamber S1 formed in the first combustion chamber S1 so as to form a swirling flow in the first combustion space S1, And a second combustion space (S2) formed on the first combustion chamber (500) and communicating with the first combustion space (S1), wherein the second combustion space (S2) A cooling air fan 910 for supplying combustion air cooled in the second combustion chamber 800 to cool the second combustion chamber 800 and form a swirling flow in the second combustion space S2 (Not shown).

2, a first combustion space S1 is formed in the first combustion chamber 500, and an upward upward flow is formed in the first combustion space S1 as a whole by air supply means .

A fuel stacking portion in which solid fuel is stacked can be formed on the bottom surface of the first combustion chamber 500 and fuel supplied from the fuel supply portion 40 through the bottom side of the bottom portion can be stacked on the fuel stacking portion.

The upward swirling flow can be formed entirely in the first combustion space S1 by the swirled combustion air supplied by the air supply means.

The second combustion chamber 800 is formed above the first combustion chamber 500 and is a space for secondarily combusting the combustion gas discharged from the first combustion chamber 500.

The cooling air heater unit 900 cools the wall surface of the second combustion chamber 800 by the cooled combustion air supplied by the cooling air fan 910 and supplies the cooling air to the second combustion space S2 of the second combustion chamber 800 And forms a swirling flow upward.

As shown in FIGS. 2 and 3, a plurality of air supply units may be disposed in one direction of the first combustion chamber 500.

In the conventional case, when a plurality of air supply means are provided, air supply means is generally provided so as to be opposed to both sides of the combustion chamber of the combustor 10 through the combustion chamber.

The power generation system of the present invention is characterized in that a plurality of air supply units of the air supply unit are disposed on one side of the combustor 10 so that the combustor 10 is disposed in one end area of the first accommodating module 100-1, A plurality of air supply means and a cooling air fan 910 may be installed.

The combustor 10 is disposed in one end region of the first accommodating module 100-1 so that the combustor 10 can be more easily connected to the plurality of power generating modules such as the fuel supply unit 40 and the boiler 20 There is an effect that can be installed.

For example, as shown in Figs. 7 and 8, the combustor 10 installed in the end region of the first accommodating module 100-1 and the boiler 20 The combustor 10 installed in the end region of the first accommodating module 100-1 and the combustor 10 installed in the end of the first accommodating module 100-1 in the vertical direction via the cavity member 21, The supply unit 40 may be installed in a horizontal direction so that the solid fuel can be easily supplied to the combustor 10.

In the air supply unit, a plurality of air supply units may be introduced into the first combustion space S1 from one direction of the first combustion chamber 500.

The air supply unit may include a plurality of air supply units individually controlled in flow rate by the control unit, and the plurality of air supply units may be disposed in one direction of the first combustion chamber 500.

As shown in FIGS. 2 and 3, the air supply unit may include a first air supply unit 600 and a second air supply unit 700.

The air supply unit includes a first air supply unit 610 provided in an upper region of the first combustion chamber 500 and configured to supply combustion air to form a downward swirling flow in the first combustion space S1, A second air supply means 710 installed in a lower region of the first combustion chamber 500 and supplying combustion air so as to form an upward swirling flow in the first combustion space S1, The first air supply unit 610 and the second air supply unit 710 may be disposed in one direction of the first combustion chamber 500. [

For example, the first air supply unit 600 may include a first air supply unit 610, the second air supply unit 700 may include a second air supply unit 710, The flow rate of the combustion air can be individually controlled by the controller 610 and the second air supply unit 710.

3, the first air supply unit 600 includes an upper region 510 of the first combustion chamber 500 so as to form a downward swirling flow in the first combustion space S1, The first air supply means 610 for supplying the combustion air through the lower side portion and the upper region 510 of the first combustion space S1, A first guide member 650 for guiding the combustion air discharged into the first combustion space S1 downward through an air passage 630 and a discharge port formed at the upper end of the first air passage 630 can do.

The first air supply means 610 is a member for supplying combustion air so as to form a swirling flow in the first combustion space S1 through the first air flow path 630. [

The first air passage 630 may be provided with a upward guide 631 inclined upward and an upward swirling flow may be formed in the first air passage 630.

The first discharge port is formed at an upper end of the first air passage 630 and a swirling flow formed in the first air passage 630 is discharged to the first combustion space S1.

The first guide member 650 may be formed on the entire surface of the first discharge port and extend downward from the upper surface of the first combustion chamber 500.

The first discharge port is formed at the upper end of the inner wall of the first air passage 630 and the upward swirling flow formed in the first air passage 630 can be discharged into the first combustion space S1, The discharged combustion air may collide against the ceiling of the first combustion chamber 500 and the first guide member 650 and may be lowered while maintaining the turning force to form a downward swirling flow in the first combustion space S1.

3, the second air supply unit 700 includes the second air supply unit (not shown) for supplying the combustion air through the upper side portion of the lower region 530 of the first combustion chamber 500 And a second air passage 730 which surrounds the lower region 530 of the first combustion space S1 and has a downward swirling flow.

The downwardly inclined downward guide 731 may be provided in the second air passage 730 to form a downward swirling flow in the second air passage 730.

The second discharge port is formed at the lower end of the second air passage 730. A downward swirling flow formed in the second air passage 730 can be discharged to the first combustion space S1, The combustion air striking the bottom surface of the first combustion chamber 500 is lifted while maintaining the swirl force, so that the upward swirling flow can be formed in the first combustion space S1.

The second combustion chamber 800 is formed above the first combustion chamber 500 and is a space for secondarily combusting the combustion gas discharged from the first combustion chamber 500.

The cooling air heater unit 900 cools the wall surface of the second combustion chamber 800 by the cooled combustion air supplied by the cooling air fan 910 and supplies the cooling air to the second combustion space S2 of the second combustion chamber 800 And forms a swirling flow upward.

4, the cooling air unit 900 may include a cooling air fan 910, a cooling flow path 930, and a guide blade 950.

The cooling air fan 900 is provided with the cooling air fan 910 for supplying the combustion air cooled through the upper side of the second combustion chamber 800 so as to form an upward swirling flow in the second combustion space S2, A cooling passage 930 formed to surround the second combustion chamber 800 and having a downward swirling flow and a discharge port spaced apart in the circumferential direction from a lower inner wall of the cooling passage 930, And guide vanes 950 for guiding the combustion air cooled in the second combustion space S2 to be discharged.

The cooling passage 930 may include an inner wall in contact with the second combustion chamber 800 and an outer wall spaced apart from the inner wall and the cooling passage 930.

And the discharge port may be spaced apart from the inner wall of the cooling passage 930 in the circumferential direction.

The downward swirling flow formed by supplying the cooled combustion air through the upper side portion of the second combustion chamber 800 by the cooling air fan 910 collides with the bottom surface of the cooling air bearing portion 900 and rises while maintaining the swirling force An upward swirling flow can be formed in the second combustion space S2.

At this time, the guide vane 950 can guide the combustion air discharged into the second combustion space S2 upwardly through the discharge port spaced apart in the circumferential direction from the lower inner wall of the cooling passage 930.

4, the guide vane 950 includes a first guide vane 951 spaced from the lower inner wall of the cooling passage 930 in the circumferential direction and connected to the discharge port, And a second guide vane 953 spaced from the lower outer wall of the passage 930 in the circumferential direction and formed to be inclined toward the inner wall of the cooling passage 930.

As shown in FIG. 4, the first guide vane 951 may be installed only in a part of the discharge port.

Although not shown, it is needless to say that the first guide vane 951 may be installed at the discharge port.

The combustor 10 of the present invention may be disposed in the direction of one side of the first combustion chamber 500, and the cooling air fan 910 may be disposed in the first combustion chamber 500.

6, the first air supply unit 600 includes a first air supply unit 610, the second air supply unit 700 includes a second air supply unit 710, The first air supply means 610, the second air supply means 710 and the cooling air fan 910 are disposed in a direction of one side of the first combustion chamber 500. The first air supply means 610, the second air supply means 710, The flow rate of the air can be individually controlled.

Next, the power generation system will be described in detail with reference to Figs. 1 to 8. Fig.

Referring to the drawings, a power generation system according to an embodiment of the present invention includes a first receiving module 100-1 and a second receiving module 100-2, and further includes a third receiving module 100-3, And a fourth accommodation module 100-4.

As shown in Figs. 7 and 8, the present invention is characterized in that at least part of a plurality of power generation modules including a combustor 10, a boiler 20, a generator 30, and an accessory facility is divided into a plurality of receiving modules And the plurality of power generation modules are linked and installed.

The receiving module includes a first receiving module 100-1 in which at least the combustor 10 described above is disposed, and a second receiving module 100-1 installed above the first receiving module 100-1, A second accommodation module (100-2) in which a cavity member (21) connected to the upper side of the combustor (10) and a boiler (20) connected to the combustor (10) via the cavity member ).

The receiving module of the present invention can be made to be accommodated and movable at least a part of a plurality of power generation modules including the combustor 10, the boiler 20, the generator 30, and an accessory facility.

The power generation system can be compactly modularized through the structure of the accommodating module which is accommodated in at least a part of the power generation modules and can be moved and installed to the site easily.

For example, the combustor 10 described above is installed in the first accommodating module 100-1, the cavity member 21 connected to the upper side of the combustor 10 is provided in the second accommodating module 100-2, A boiler 20 connected to the combustor 10 through a cavity member 21 may be installed.

The cavity member 21 is formed on the upper side of the combustor 10 and can form a flow path in a direction bent in connection with the boiler 20.

In this way, the second receiving module 100-2 provided with the weight-chain boiler 20 is provided on the upper side of the first receiving module 100-1, and the weight is increased to the first receiving module 100-1 The vibration generated in the installed combustor 10 can be reduced.

8, one side of the cavity member 21 is connected to the upper side of the second combustion chamber 800 of the combustor 10, and the other side of the cavity member 21 is connected to the boiler 20, A flow path can be formed.

Specifically, the inlet of the cavity member 21 is connected to the upper side of the second combustion chamber 800, the outlet of the cavity member 21 can be connected to the boiler 20 member, and the high temperature combustion gas And the outflow direction of the combustion gas flowing out through the outflow port may be set to be bent in the perpendicular direction.

In the power generation system of the present invention, the flow path connecting the combustor 10 and the boiler 20 by the cavity member 21 is formed in the bent direction, whereby the accommodating module constituting the power generation system can be further downsized

However, when the cavity member 21 forms a flow path in the bent direction, the efficiency of the power generation system may be reduced without smooth flow of the airflow in the bent direction.

3, the power generation system of the present invention is constructed such that the cooling air is introduced into the first combustion space S2 by the upward swirl flow introduced into the second combustion space S2 of the second combustion chamber 800 by the cooling air- The combustion gas can be discharged from the second combustion chamber 800 to the cavity member 21 while the swirling force of the combustion gas rising in the first combustion chamber S1 is improved.

That is, even if the cavity member 21 forms a curved flow path for connection with the boiler 20, the swirling force is maintained by the upward swirl flow introduced by the cooling air element unit 900, The combustion gas can be smoothly introduced into the direction of the boiler 20 connected to the bent direction and thus the efficiency of the power generation system can be improved.

Further, when the flow path is formed in the direction in which the cavity member 21 is bent, there is a problem that the mixing effect in the cavity member 21 can not be expected while the combustion gas discharged from the combustor 10 is discharged while forming the shortest path have.

However, in the present invention, the combustion air is primarily mixed in the first combustion space S1 by the swirling flows of the first air supply unit 600 and the second air supply unit 700, and the second combustion space S2 And is mixed tertiaryly in the internal space of the cavity member 21 by the swirling flow formed by the cooling air fan 910 while being mixed by the swirling flow supplied from the cooling air fan 910 in the combustion air The efficiency of the power generation system can be improved.

7, a third accommodation room (not shown) installed on the front surface of the first accommodation module 100-1 and having a generator 30 communicating with the boiler 20 through a steam pipe P is installed, And may further include a module 100-3.

The steam generated in the boiler 20 can be transferred to the generator 30 through the steam pipe P and the steam pipe P is formed to connect the boiler 20 and the generator 30 in the shortest path .

As shown in FIG. 8, the vibration skid 200 may be constructed such that the power generating units disposed inside the receiving module are connected to each other to cancel the vibration by connecting the power generating modules adjacent to each other have.

The vibration skid 200 connects the plurality of power generation modules disposed inside the separate receiving module in an integrated manner to cancel the vibration generated in the plurality of power generation modules while the power generation modules having different vibration periods act integrally.

Although not shown, the combustor 10, which is a power generation module disposed inside the receiving module on one side, and the generator 30, which is a power generation module disposed inside the other receiving module, are connected to the combustor 10 And the vibration generated in the generator 30 are offset from each other, so that the vibration can be canceled.

8, the first accommodating module 100-1 includes a combustor 10, a first air supply unit 600, a second air supply unit 700, and a cooling air unit 900 A generator 30 is installed in the third accommodating module 100-3 and a fuel supply unit 40 is provided in the fourth accommodating module 100-4 so as to supply the solid fuel to the combustor 10 .

A cavity member 21 and a boiler 20 may be installed in the second accommodating module 100-2.

The combustor 10 installed in the first accommodating module 100-1 may include a first combustion chamber 500, an air supply portion, a second combustion chamber 800, and a cooling air portion 900.

8, by arranging the first air supply means 610 and the second air supply means 710 in one direction of the first combustion chamber 500 of the combustor 10, the combustor 10 is divided into the first The first air supply means 610 and the second air supply means 710 can be provided in the remaining area in a state where the air supply module is disposed in one end area of the accommodation module 100-1.

The combustor 10 provided in the end region of the first accommodating module 100-1 and the fuel supply unit 40 provided in the fourth accommodating module 100-4 can be easily linked to the combustor 10 to facilitate the solid fuel .

Further, the first air supply unit 610, the second air supply unit 710, and the cooling air unit 900 of the air supply unit may be disposed together in one direction of the combustor 10.

As shown in FIG. 8, the power generation system of the present invention may further include a file module 300 that fixes the accommodation module to the installation area.

The file module 300 may include a guide socket 310, a base file 330, and a fixing member 350.

The file module 300 includes a guide socket 310 disposed in an installation area of the accommodating module and a base file 330 which is guided by the guide socket 310 to be mounted on the ground of the installation area of the accommodating module, And a fixing member 350 fixing the guide socket 310 and the accommodation module to integrate the guide socket 310 with the foundation pile 330.

The foundation file (330) can be pushed into the ground to fix the receiving module to the ground.

At this time, the fixing member 350 can be bolted to the flange member with the louver plate D1 as a buffer material interposed therebetween.

4, the louver plate D1 includes a first louver plate D1 disposed below the bottom plate of the receiving module and a second louver plate D1 disposed below the bottom plate of the receiving module, And a louver plate D1.

The first louver plate D1, the bottom plate of the receiving module, the second louver plate D1, and the second flange member are fixed on the upper side of the guide socket 310 of the file module 300, ). ≪ / RTI >

The fixing member 350 may be a bolt member that is inserted through the guide socket 310 and the receiving module.

8, the power generation system of the present invention includes a bottom plate of the receiving module and a lower cushioning member 400 for cushioning and connecting the vibration skid 200, and the lower cushioning member 400, A louver plate D1 provided on the upper side of the bottom plate of the receiving module and a louver plate D1 provided on the louver plate D1 for supporting the vibration skid 200 apart from the bottom plate of the receiving module And a rubber vibration isolating plate D2.

For example, the vibration skid 200 can be bolted to the bottom plate of the receiving module via the rubber dustproof plate D2,

Alternatively, the vibration skid 200 may be fixed to the bottom plate of the receiving module via the rubber dustproof plate D2 and the louver plate D1 disposed below the dustproof plate.

Vibrations applied to the vibration skid 200 by the power generation module in which vibrations such as the combustor 10 and the generator 30 are generated can be superimposedly buffered by the louver plate D1 and the rubber dustproof plate D2 have.

It goes without saying that various embodiments of the combustor 10 having various embodiments described above may be applied to the power generation system of the present invention.

Therefore, the detailed configuration of the combustor 10 utilized in the power generation system has already been described, and a detailed description thereof will be omitted in order to avoid redundancy.

Although the embodiments of the present invention have been described in detail, it is to be understood that the scope of the present invention is not limited to the above embodiments and various changes and modifications may be made without departing from the scope of the present invention. It will be obvious to those of ordinary skill in the art.

10: Combustor 20: Boiler
21: cavity member 30: generator
40: fuel supply unit
100-1: first accommodation module 100-2: second accommodation module
100-3: third accommodating module 100-4: fourth accommodating module
200: Vibration skid 300: File module
310: guide socket 330: foundation file
350: fixing member 400: lower buffer member
500: first combustion chamber 510: upper region
530: lower region 600: first air supply portion
610: first air supply means 630: first air flow path
631: upper guide 650: first guide member
700: second air supply part 710: second air supply part
730: second air flow path 731: downward guide
800: second combustion chamber 900:
910: Cooling air fan 930: Cooling air flow
950: guide wing 951: first guide wing
953: second guide blade D1: louver plate
D2: rubber anti-vibration plate P: steam piping
S1: first combustion space S2: second combustion space

Claims (10)

A first combustion chamber in which a first combustion space is formed;
An air supply unit having air supply means for supplying combustion air to the first combustion chamber so as to form a swirling flow in the first combustion space;
A second combustion chamber formed above the first combustion chamber and forming a second combustion space communicating with the first combustion space; And
A cooling air fan for cooling the second combustion chamber, forming a swirling flow in the second combustion space, and supplying a cooling air cooled by the second combustion chamber to cool a wall surface of the second combustion chamber; / RTI >
The air conditioner according to claim 1,
And a plurality of air supply means are disposed in one direction of the first combustion chamber.
The air conditioner according to claim 1,
A first air supply unit installed in an upper region of the first combustion chamber and having a first air supply unit for supplying combustion air so as to form a downward swirling flow in the first combustion space; And
And a second air supply unit installed in a lower region of the first combustion chamber and having a second air supply unit for supplying combustion air so as to form an upward swirling flow in the first combustion space,
Wherein the first air supply means and the second air supply means are disposed in one direction of the first combustion chamber.
The air conditioner according to claim 3,
The first air supply means for supplying the combustion air through the lower side portion of the upper region of the first combustion chamber;
A first air flow passage which surrounds an upper region of the first combustion space and has an upward swirl flow; And
And a first guide member for guiding the combustion air discharged into the first combustion space through a discharge port formed at an upper end of the first air flow path to turn downward,
Wherein the second air supply unit includes:
The second air supply means for supplying combustion air through the upper side portion of the lower region of the first combustion chamber;
And a second air passage which surrounds the lower region of the first combustion space and has a downward swirling flow.
The cooling device according to claim 1,
The cooling air fan that supplies the combustion air cooled through the upper side portion of the second combustion chamber so that an upward swirling flow is formed in the second combustion space;
A cooling passage provided in a shape surrounding the second combustion chamber and having a downward swirling flow; And
And a guide vane for guiding the combustion air cooled in the second combustion space to be discharged through a discharge port spaced apart in a circumferential direction from a lower inner wall of the cooling passage.
6. The apparatus according to claim 5,
A first guide blade spaced apart from the lower inner wall of the cooling passage in the circumferential direction and connected to the discharge port;
And a second guide blade spaced from the lower outer wall of the cooling passage in a circumferential direction and inclined in an inner wall direction of the cooling passage.
The method according to claim 1,
Wherein the air supply means and the cooling air fan are disposed in one direction of the first combustion chamber.
At least a part of a plurality of power generation modules including a combustor, a boiler, a generator, and an accessory is divided into a plurality of power receiving modules, and the plurality of power generating modules are connected to each other,
The receiving module includes:
A first receiving module in which the combustor according to any one of claims 1 to 7 of the power generating modules is disposed;
And a second receiving module installed above the first receiving module and having a cavity member connected to at least the upper side of the combustor of the power generating module and a boiler connected to the combustor via the cavity member, Power generation system.
9. The apparatus according to claim 8, wherein the cavity member comprises:
Wherein one side is connected to the upper side of the second combustion chamber of the combustor and the other side is connected to the boiler to form a flow path in a bent direction.
9. The system of claim 8,
And a third receiving module installed on a front surface of the first receiving module and having a generator connected to the boiler via a steam pipe.

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