KR101216492B1 - Large-capacity boiler - Google Patents

Abstract

An object of the present invention is to provide a large-capacity boiler that minimizes incomplete combustion of a fuel to increase combustion efficiency and heating performance, to burn a large amount of solid fuel with small particles, and to easily clean the inside of a heating tube.
A large capacity boiler according to the present invention includes a tubular combustion chamber; An inner space forming body located in a central portion of the combustion chamber, the upper portion of which is narrower than the lower portion; A post combustion inner tube connected inside the inner space forming body to communicate with each other; An outer space forming body having an upper cone shape narrower than the lower portion, being spaced apart from the inner space forming body by a predetermined interval, surrounding the outside of the inner space forming body, and having a plurality of through holes formed therein; A late combustion exterior which is spaced apart from the late combustion inner tube by a predetermined interval to surround the outer side of the late combustion inner tube, and is connected to communicate with each other on top of the outer space forming body, and a plurality of through holes are formed; A tank having an inlet through which water is introduced and an outlet through which the water is discharged; And a first heating tube positioned inside the tank and into which gas discharged from the combustion chamber is introduced, and an upper end of the late combustion exterior and the late combustion inner tube may be connected to each other to form a plurality of through holes. .

Description

Large Capacity Boiler {LARGE-CAPACITY BOILER}

The present invention relates to a large capacity boiler, and more particularly to a large capacity boiler for heating water.

Currently used boilers have various structures from industrial boilers to domestic boilers. In general, a domestic boiler is a heating means for heating the indoor space comfortably and warmly in a low temperature season such as winter season, early spring or late autumn, and is heated by heating water or heat medium in a closed container by combustion heat or other heat source. Heat medium such as water or steam is circulated to the heating line to heat the indoor space. Oil, gas, or solid fuel may be used as a fuel for hot water heating. Among them, particularly in the case of a small particle solid fuel, the space between the solid fuels is small and sufficient contact between the solid fuel and the air is not achieved. Incomplete combustion of a solid fuel and a reduction in combustion efficiency and heating performance are caused.

In addition, when small-particle solid fuel is burned in large quantities at one time, air does not reach the center of the solid fuel accumulated in a large volume. Therefore, since only the outside of the solid fuel pile is burned, it is impossible to apply to a large-capacity boiler that burns a large amount of solid fuel.

In addition, when the burner is used for a long time, foreign matters such as dust and sand accumulate in the combustion chamber. At this time, it is not easy to remove foreign matters such as dust and sand, which results in poor burner performance and shortened lifespan. have.

In addition, when a component made of a metal such as a burner of a burner is exposed to excessive high temperatures, corrosion of the metal and degradation of durability occur.

In the case of solid fuel, unlike oil or gas, it takes a long time to reach the normal combustion temperature at the beginning of fuel ignition.

In addition, solid fuels contain a large amount of dust in the exhaust gas, unlike oil or gas, where dust is deposited through a heating tube that heats hot water and the gas flow inside the heating tube is not desired. , And there is a problem of lowering the heating performance.

An object of the present invention is to provide a large capacity boiler capable of burning a large amount of solid fuel with small particles.

Another object of the present invention is to provide a large-capacity boiler capable of increasing combustion efficiency and heating performance by minimizing incomplete combustion by uniformly maximizing contact between continuously introduced solid fuel and air.

In addition, another object of the present invention is to provide a large-capacity boiler capable of minimizing corrosion and increasing durability.

In addition, another object of the present invention is to provide a large-capacity boiler capable of immediately removing dust and foreign matter during combustion in real time, thereby improving combustion efficiency and heating performance.

In addition, the present invention has another object to provide a large-capacity boiler that can shorten the time required to the normal combustion temperature at the initial stage of ignition to increase combustion efficiency and heating performance.

In addition, another object is to provide a large-capacity boiler that is easy to clean the heating tube for heating hot water.

A large capacity boiler according to the present invention includes a tubular combustion chamber; An inner space forming body located in a central portion of the combustion chamber, the upper portion of which is narrower than the lower portion; A post combustion inner tube connected inside the inner space forming body to communicate with each other; An outer space forming body having an upper cone shape narrower than the lower portion, being spaced apart from the inner space forming body by a predetermined interval, surrounding the outside of the inner space forming body, and having a plurality of through holes formed therein; A late combustion exterior which is spaced apart from the late combustion inner tube by a predetermined interval to surround the outer side of the late combustion inner tube, and is connected to communicate with each other on top of the outer space forming body, and a plurality of through holes are formed; A tank having an inlet through which water is introduced and an outlet through which the water is discharged; And a first heating tube positioned inside the tank and into which gas discharged from the combustion chamber is introduced, and an upper end of the late combustion exterior and the late combustion inner tube may be connected to each other to form a plurality of through holes. .

Preferably, at least one first blower pipe connected to the outer space forming body to supply external air between the outer space forming body and the inner space forming body;

At least one second blower tube connected to the late combustion appearance to supply external air between the late combustion appearance and the late combustion inner tube; At least one third blower pipe connected to the combustion chamber so as to supply external air to the combustion chamber; A body surrounding the outside of the combustion chamber at a predetermined distance from the combustion chamber; And at least one fourth blower pipe connected to the body to supply external air between the body and the combustion chamber, and a plurality of through holes may be formed in the combustion chamber.

Preferably, the lower combustion chamber may further include a lower combustion chamber connected to each other to communicate with each other, the upper portion having a wider cone shape than the lower portion, and having a plurality of through holes formed therein.

Preferably, the gas discharge inner pipe is connected to the inside of the combustion chamber to communicate with each other, the plurality of through-holes are formed; A gas discharge appearance surrounding the outside of the gas discharge inner tube spaced apart from the gas discharge inner tube at a predetermined interval; And at least one fifth blower pipe connected to the gas exhausting exterior to supply external air between the gas exhaust inner tube and the gas exhausting exterior.

Preferably, at least one sixth blower pipe connected to the lower combustion chamber to supply outside air into the lower combustion chamber; A heater provided in at least one of the first to sixth blower tubes to ignite the fuel; A pair of discharge rollers provided at a lower portion of the lower combustion chamber; And a temperature detector disposed below the lower combustion chamber and measuring a temperature inside the lower combustion chamber. When the temperature value measured from the temperature detector is equal to or less than a predetermined value, the discharge roller is driven to operate in the lower combustion chamber. Dust may be emitted.

Preferably, the blowing unit for forcibly supplying the outside air to at least one or more of the first to sixth blowing pipe; And a valve provided in at least one of the first to sixth blower pipes to control the flow of the outside air.

Preferably, the first oil is connected to one end of the first heating tube so as to communicate with the inside of the first heating tube, the first oil including a partition wall for blocking the water in the interior of the first heating tube and the tank; Eastern; And a second heating tube having one end connected to communicate with the first flow part and the inside thereof. And a second flow unit connected to the other end of the second heating tube so as to communicate with the inside of the second heating tube, and including a partition wall for blocking the water inside the second heating tube and the inside of the tank. The other end of the first heating tube may be connected to the gas discharge appearance.

Preferably, the third heating tube is one end is connected to communicate with the second flow portion and the inside; And an exhaust pipe for discharging the gas discharged from the other end of the third heating tube to the outside of the tank.

Preferably, the first door is coupled to one side of the first flow portion for opening and closing the first flow portion from the outside of the tank; And a second door coupled to one side of the second flow part to open and close the second flow part from the outside of the tank.

Preferably, the cover surrounding the portion connecting the first heating tube and the gas discharge appearance is sealed to form an inner space; And a cover flow tube connecting the inner space of the tank and the inner space of the cover to communicate with each other to introduce and discharge water in the tank into the inner space of the cover.

The large-capacity boiler according to the present invention can minimize the incomplete combustion by burning the exhaust gas at a high temperature and maximizing the contact between the fuel and the air, thereby maximizing the combustion efficiency and the heating performance. This has the effect of enabling the burner to burn large quantities of small solid fuel which was not possible. In addition, the combustion of the exhaust gas through the high temperature pyrolysis of the solid fuel can minimize the incomplete combustion, increase the combustion efficiency, and the heating performance, there is an effect that can minimize the emission of greenhouse gases. In addition, it is possible to remove dust and foreign matter in real time during solid fuel combustion, and to minimize the time required for the normal combustion temperature at the initial stage of ignition, thereby increasing the combustion efficiency and heating performance. In addition, since excessive temperature rise of the component exposed to high temperature can be prevented, the durability of the component can be improved. Since the inside of the heating tube for heating the hot water is very easy to clean, there is an effect that can prevent the thermal efficiency, and the heating performance due to dust deposition inside the heating tube.

1a and 2b is a perspective view of a large capacity boiler according to an embodiment of the present invention,
2 is a perspective view of a burner of a large-capacity boiler according to one embodiment of the present invention;
3a is a plan view of a burner of a large capacity boiler according to one embodiment of the present invention;
Figure 3b is a front view of the burner of the large capacity boiler according to an embodiment of the present invention,
Figure 3c is a side view of the burner of the large capacity boiler according to an embodiment of the present invention,
3d is a rear view of the burner of the large-capacity boiler according to one embodiment of the present invention;
4 is a front perspective view of a burner of a large capacity boiler according to one embodiment of the present invention;
5 is a view showing the flow of air supplied to the combustion chamber of the burner of the large-capacity boiler according to an embodiment of the present invention,
6 is a left side view of a heat exchanger of a large capacity boiler according to an embodiment of the present invention;
7a is a right side view of a heat exchanger of a large capacity boiler according to an embodiment of the present invention;
Figure 7b is a side projection of the heat exchanger of the large-capacity boiler according to an embodiment of the present invention,
8 is an exploded perspective view of a heat exchanger of a large capacity boiler according to an embodiment of the present invention;
9 is a view showing the gas flow in the heat exchange unit of the large-capacity boiler according to an embodiment of the present invention, and
10 is a partially enlarged view illustrating a connection portion of a cover of a large capacity boiler according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the inventor should appropriately interpret the concepts of the terms appropriately It should be interpreted in accordance with the meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined. Therefore, the embodiments described in this specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible.

1a and 2b is a perspective view of a large-capacity boiler according to an embodiment of the present invention, Figure 2 is a perspective view of a burner of a large-capacity boiler according to an embodiment of the present invention, Figure 3a is a large-capacity boiler according to an embodiment of the present invention 3B is a front view of the burner of the large-capacity boiler according to one embodiment of the present invention, FIG. 3C is a side view of the burner of the large-capacity boiler according to one embodiment of the present invention, and FIG. 3D is one embodiment of the present invention. Back view of the burner of the large-capacity boiler according to the example, FIG. 4 is a front perspective view of the burner of the large-capacity boiler according to one embodiment of the present invention, and FIG. 5 is supplied to the combustion chamber of the burner of the large-capacity boiler according to the embodiment of the present invention. It is a figure which shows the flow of the air which becomes.

The burner 10 of the large-capacity boiler according to the embodiment of the present invention includes an inner space forming body 120, a combustion chamber 100, and a blower 240.

The combustion chamber 100 has a cylindrical shape, and a cone-shaped inner space forming member 120 is formed at a central portion inside the combustion chamber 100, and is spaced apart from the inner space forming body 120 by a predetermined interval outside the inner space forming body 120. The cone-shaped outer space forming body 121 is located. The upper combustion inner tube 130 is connected to the upper end of the inner space forming body 120, and is connected to communicate with the inner space forming body 120. In addition, the late combustion inner tube 130 is spaced apart from the late combustion inner tube 130 by a predetermined interval outside the late combustion outer tube 131, the outer space forming body 121 and the outer space forming body 121 to communicate with the inside. ) Is connected to the top. In addition, the upper end of the late combustion exterior 131 and the late combustion inner tube 130 is connected to each other, a plurality of through-holes are formed in the connection portion.

The outer side of the combustion chamber 100 is spaced apart from the combustion chamber 100 by a predetermined interval to form a cylindrical combustion chamber exterior 110. The inner body 210 is spaced apart from the combustion chamber exterior 110 by a predetermined interval on the outside of the combustion chamber exterior 110, and the body 200 is spaced apart from the inner body 210 by a predetermined interval on the outside of the inner body 210. do. In addition, the gas discharge inner tube 140 is connected to the upper portion of the combustion chamber 100 so as to communicate with the combustion chamber 100, and the gas discharge inner tube 140 is spaced apart from the gas discharge inner tube 140 by a predetermined distance to the outside of the gas discharge inner tube 140. 141 is configured.

The lower combustion chamber 150 is connected to the lower portion of the combustion chamber 100. The lower combustion chamber 150 has a cone shape and solid fuel introduced into the combustion chamber 100 is stacked from the lower combustion chamber 150. In addition, dust in which the solid fuel is combusted may be discharged to the lower combustion chamber 150. A pair of discharge rollers 160 are formed at the lower end of the lower combustion chamber 150. When the discharge rollers 160 are stopped, the dust is blocked, and when the discharge rollers 160 are rotated, the dusts are discharged. The emission of can be controlled. Although not shown, a temperature measuring unit having a predetermined distance from the lower portion of the lower combustion chamber 150 may be positioned to measure a temperature of the lower portion of the lower combustion chamber 150. According to an embodiment of the present invention, the temperature measuring unit may include a temperature sensor or It may include an optical sensor for measuring the temperature. In addition, the discharge portion 220 is connected to the lower portion of the body 200 may discharge the dust discharged through the discharge roller 160. In addition, the discharge roller 160 is not completely in contact with each other, there is a gap between the discharge roller 160, the air forcibly introduced through the blower pipe 250f connected to the discharge unit 220 inside the lower combustion chamber 150 To help burn solid fuel.

The fuel supply pipe 230 is for supplying the solid fuel into the combustion chamber 100. According to an embodiment, a screw (not shown) may be configured inside the fuel supply pipe 230 to supply the solid fuel. In addition, one side of the fuel supply pipe 230 is provided with a fuel detection sensor 410 can detect whether the solid fuel, and the input amount.

The blower 240 is for supplying fresh air to the combustion chamber 100, the lower combustion chamber 150, and the like, and supplies air to the plurality of blower tubes 250. The blower tube 250 includes the combustion chamber 100, the lower combustion chamber 150, the inner body 210, the late combustion exterior 131, the gas discharge exterior 141, the outer space forming body 121, and the fuel supply pipe 230. Is connected to each. In addition, second and third heaters 301 and 302 are configured in the blower pipe 250b connected to the combustion chamber 100, and a first heater 300 is provided in the blower pipe 250e connected to the lower combustion chamber 150. It is configured to ignite the solid fuel injected into the combustion chamber 100, and the lower combustion chamber 150. In addition, each blower pipe 250 is configured with a valve 420, by operating each valve 420 individually, it is possible to independently adjust the air supply amount through each blower pipe (250). Therefore, optimum combustion is possible according to the input amount of the solid fuel, the combustion situation, the combustion progression stage, and the like.

Meanwhile, a plurality of through holes are formed in the combustion chamber 100, the lower combustion chamber 150, the outer space forming body 121, the late combustion external appearance 131, and the gas discharge inner tube 140, according to one embodiment of the present invention. According to this, the through hole preferably has a diameter through which the solid fuel cannot pass. In addition, a plurality of through holes are formed in the combustion chamber exterior 110. According to one embodiment of the present invention, the through holes of the combustion chamber exterior 110 have a larger diameter than the through holes of the combustion chamber 100 for a smooth flow of air. It is preferable to have.

Operation of the burner of the large-capacity boiler according to one embodiment of the present invention is as follows. Solid fuel, such as pellets, is injected into the combustion chamber 100 from the fuel supply pipe 230, and the air supplied from the blower 240 flows in together through the blower pipe 250h configured at one side of the fuel supply pipe 230. The solid fuel to be injected is stacked from the lower combustion chamber 150 to be accumulated in the combustion chamber 100. At this time, the solid fuel does not accumulate and a space is formed inside the internal space forming member 120 configured at the center of the combustion chamber 100. .

The injected solid fuel is ignited by the first to third heaters 300, 301, and 302. The solid fuel is heated by heating air introduced into the combustion chamber 100 and the lower combustion chamber 150 through the blower pipes 250b and 250e. Is ignited. Meanwhile, the solid fuel may be stacked only in the lower combustion chamber 150 for efficient ignition of the solid fuel, and the solid fuel may be further charged after the solid fuel in the lower combustion chamber 150 is ignited to stack the solid fuel in the combustion chamber. In this case, the first heater 300 is operated first to ignite the solid fuel in the lower combustion chamber 150, and then the second and third heaters 301 and 302 are operated to operate the solid fuel in the combustion chamber 100. Can ignite. After the ignition is finished, the operation of the first to third heaters 300, 301, and 302 is stopped.

On the other hand, air is supplied for smooth and complete combustion of the solid fuel, and the air conveyed through the blower pipe 250c connected to the outer space forming body 121 is solid through the through hole of the outer space forming body 121. Supplied to the fuel. The air transferred through the blower pipe 250d connected to the late combustion appearance 131 is supplied to the solid fuel through the through hole of the late combustion appearance 131. In addition, the air transported through the blower tube 250a connected to the inner body 210 is supplied to the solid fuel through the through hole of the combustion chamber exterior 110, the combustion chamber 100, and the lower combustion chamber 150. The air is supplied to the combustion chamber 100 and the lower combustion chamber 150 through the blower pipes 250b and 250e including the first to third heaters 300, 301, and 302. Each blower tube 250 may be changed in position and number configured for smooth air supply, and the first and third heaters 300, 301 and 302 may also be changed in consideration of ignition performance. have.

The hot gas generated while the solid fuel is pyrolyzed is discharged through the gas discharge inner tube 140, wherein the gas is mixed with incomplete combustion gas, and it is preferable to completely burn the incomplete combustion gas. Since the internal space former 120 is located at the center of the solid fuel, the interior of the internal cavity 120 is at a very high temperature and strong flames and complete combustion gases are generated. The high temperature complete combustion gas generated inside the inner space former 120 is discharged along the late combustion inner tube 130, and a strong flame inside the inner space former 120 is also ejected along the late combustion inner tube 130. .

At this time, the incomplete combustion gas passing through the gas discharge inner pipe 140 is supplied from the high-temperature flame ejected from the late combustion inner pipe 130, the blowing pipe (250g) connected to the gas discharge outer tube 141 of the gas discharge inner pipe 140 It is completely combusted by the air introduced through the through hole, and the air introduced through the through hole formed at the connection portion between the late combustion inner tube 130 and the late combustion appearance 131.

Dust of the burned solid fuel and foreign matter such as sand buried in the solid fuel are discharged to the lower portion of the lower combustion chamber 150. The dust, and foreign matter, of the solid fuel burned is lower in temperature than the solid fuel in combustion. Therefore, when the temperature measured by the temperature measuring unit is below a predetermined value, it can be seen that dust is accumulated inside the lower combustion chamber 150, in which case the discharge roller 160 is operated. According to the operation of the discharge roller 160, the dust of the lower combustion chamber 150 is discharged to the discharge unit 220, the dust and foreign matter in the dust is more densely pulverized by the roller. If the temperature measured by the temperature measuring unit 400 during the discharge of the dust is a predetermined value or more can be seen as a solid fuel in combustion, the operation of the discharge roller 160 is stopped.

On the other hand, the central portion of the solid fuel to be burned is higher than the outside, and problems such as corrosion and deterioration may occur when a metal such as the outer space forming body 121 located at the central portion of the solid fuel is exposed to excessive high temperatures. Can be. Therefore, the air flows between the spaced outer space forming body 121 and the space space 120, and between the late combustion appearance 131 and the late combustion inner tube 130 to prevent excessive temperature rise. Can be.

Similarly, the metal is caused by the air flowing between the combustion chamber 100 and the combustion chamber exterior 110, between the lower combustion chamber 150 and the inner body 210, and between the gas exhaust inner tube 140 and the gas exhaust exterior 141. It is possible to prevent excessive high temperature exposure of the components consisting of corrosion and degradation of durability.

Meanwhile, in the combustion chamber 100 in which solid fuel is mainly combusted, the supply and flow of air is very important. Referring to FIG. 5, the air supplied to the inner body 210 passes through a through hole of the combustion chamber exterior 110. The fuel cell is supplied as a solid fuel through the through hole of the combustion chamber 100. This allows the air to sequentially pass through the through-hole of the relatively large diameter combustion chamber exterior 110 and the through-hole of the relatively small combustion chamber 100, thereby slowing the flow rate of the air and uniformly contacting the solid fuel with the air. Is to maximize. By lowering the air flow rate, it is possible to prevent scattering of the solid fuel which may occur when the air flow rate is high, and by increasing the contact between the solid fuel and the air uniformly, it is possible to increase combustion efficiency and reduce incomplete combustion. In addition, since the air reaches the outer surface of the combustion chamber evenly, it is possible to more reliably prevent excessive temperature rise of the combustion chamber 100. In FIG. 5, the configuration of the apparatus is briefly exaggerated to help understand the air flow supplied through the blower pipe 250a connected to the inner body 210.

6 is a left side view of a heat exchanger of a large capacity boiler according to an embodiment of the present invention, FIG. 7A is a right side view of a heat exchanger of a large capacity boiler according to an embodiment of the present invention, and FIG. 7B is a large capacity according to an embodiment of the present invention. 8 is an exploded perspective view of a heat exchanger of a large capacity boiler according to an embodiment of the present invention, FIG. 9 is a view illustrating a gas flow of the heat exchanger of a large capacity boiler according to an embodiment of the present invention, and FIG. 10 is a partially enlarged view illustrating a connection portion of a cover of a large capacity boiler according to an embodiment of the present invention.

Heat exchange unit 20 of the large-capacity boiler according to an embodiment of the present invention is the tank 600, the first heating tube 700, the second heating tube 710, the third heating tube 720, and the exhaust pipe 640 ).

The tank 600 has a cylindrical shape, and the inlet 610 and the outlet 611 are formed at the lower side and the upper side, respectively, and the water flowing into the tank 600 through the inlet 610 is the outlet 611. It is discharged from the tank 600 through.

One end of the first heating tube 700 is connected to the gas discharge appearance 141 of the burner, and the gas discharged from the burner flows into the first heating tube 700. The other end of the first heating tube 700 is connected to the first flow portion 800, the first flow portion 800 is composed of a partition wall and the water inside the tank 600 and the inside of the first heating tube 700 To block. In addition, the first flow part 800 may be opened and closed from the outside of the tank 600 by the first door 630.

One end of the second heating tube 710 is connected to the first flow part 800, and the other end is connected to the second flow part 810, and the second flow part 810 is connected to the second door 631. It can be opened and closed from the outside. In this case, the first flow part 800 and the second flow part 810 are disposed to face each other so as to be shifted from each other. In addition, one end of the third heating tube 720 is connected to the second flow portion 810, the other end is connected to the exhaust pipe 640 side.

9 is a view showing the gas flow in the heat exchange unit of the large-capacity boiler according to an embodiment of the present invention, for the sake of understanding such that only two second heating tubes 710 and three third heating tubes 720 are shown. The structure is shown briefly. Arrows with solid lines indicate the flow of gas and arrows with dashed lines indicate the flow of water.

Referring to Figure 9, the gas flow of the heat exchange unit of the large-capacity boiler according to an embodiment of the present invention is as follows. The gas discharged from the burner 10 flows into the first heating pipe 700 and flows into the first flow part 800 through the first heating pipe 700. The gas of the first flow part 800 flows into the second flow part 810 through the second heating tube 710 connected to the upper part of the first flow part 800, and flows into the second flow part 810. The gas is introduced into the third heating tube 720 connected to the upper side of the second flow part 810, and the gas passing through the third heating tube 720 is discharged to the exhaust pipe 640. At this time, the water flowing into the tank 600 through the inlet 610 is in contact with the first to third heating tubes 700, 710, 720, the first flow portion 800, and the second flow portion 810 Heated through the heat exchange, the heated water is discharged to the outside of the tank 600 through the outlet 611.

On the other hand, the portion where the first heating tube 700 and the tank 600 is connected is particularly high in temperature due to the hot gas freshly discharged from the burner, the heat loss when the portion is exposed to the outside of the tank 600 There is a risk of a large, safety accident. In order to prevent this, the first heating tube 700 may be positioned inside the tank 600 without directly connecting the tank 600, but in this case, the first heating tube 700 may be disposed in the tank 600. The strength fixed inside is weak and durability may be reduced. Therefore, by directly fixing one end of the first heating tube 700 to the tank 600, by using the cover 620 in this portion to securely fix the first heating tube 700 to the tank 600 and at the same time Heat loss and a safety accident can be prevented. Referring to FIG. 10, a cover 620 having an inner space is coupled to a portion where the first heating tube 700 and the tank 600 are connected, and a plurality of cover flow tubes 621 are connected. The water inside the tank 600 is introduced into the cover 620 through the cover flow tube 621 and heated, and again flows out into the tank 600 to prevent heat loss and the temperature of the cover 620 exposed to the outside. By lowering the safety accident can be prevented.

In addition, the large-capacity boiler according to the present invention can very easily remove the dust deposited in the heating tube during the gas flow process. The first door 630 communicates directly with the first heating tube 700 and the second heating tube 710, and the second door 631 is the second heating tube 710 and the third heating tube. Since it directly communicates with 720, the first door 630 and the second door 631 may be opened to conveniently clean each heating tube. In addition, the heat exchange part of the large-capacity boiler according to the embodiment of the present invention may be disposed at an inclined side toward the first door 630 at a predetermined angle, in which case the first heating tube 700 and the first heating tube 700 are cleaned by cleaning. Dust separated from the inside of the heating tube 710 may be easily collected toward the first door 630. Therefore, there is an advantage that the dust removal is very easy, in addition to the dust discharge port 801 formed in the lower portion of the first flow portion 800 can be more easily removed dust. On the other hand, the dust outlet may be opened and closed by a door not shown.

Small particle solid fuels do not have a large space between the particles. There is no problem when burning a small amount of solid fuel, but when burning a large amount of solid fuel at a time, air does not reach the center of the solid fuel accumulated in a large volume. Therefore, since only the outer side of the solid fuel pile is burned and the center portion is difficult to burn, it is very difficult to implement a large-capacity boiler that burns a large amount of solid fuel at present. In addition, when a large amount of fuel is burned, a component made of a metal such as a combustion chamber is exposed to excessive high temperature, causing corrosion and deterioration of the component.

The large-capacity boiler according to the present invention allows a maximum uniform contact with air as well as the outside of the continuous solid fuel stack, thereby minimizing incomplete combustion and increasing combustion efficiency and heating performance, thereby reducing the particle size. It is possible to implement a large-capacity boiler capable of burning a large amount of solid fuel.

In addition, by burning the exhaust gas through the high temperature pyrolysis of the solid fuel, it is possible to minimize incomplete combustion, increase combustion efficiency, and heating performance, and minimize emission of greenhouse gases.

In addition, when a large amount of fuel is burned, the temperature rises excessively. As a result, the combustion chamber made of metal and the like are exposed to excessive high temperatures, thereby causing corrosion and deterioration of durability. However, in the large-capacity boiler according to the present invention, the air supplied to the solid fuel can cool the components by sufficiently uniformly contacting the components made of metal such as a combustion chamber. Therefore, corrosion and durability degradation can be prevented by preventing the component from being exposed to excessive high temperatures.

In addition, there arises a problem that combustion efficiency is lowered, such as dust generated after the solid fuel is burned, and air supply to the solid fuel is not smooth when foreign matter is accumulated in the combustion chamber. However, the large-capacity boiler according to the present invention can increase combustion efficiency since dust and foreign matter removal are removed in real time and automatically during solid fuel combustion.

In addition, since the contact area between the solid fuel and the air is very large and it is possible to make uniform contact, it is possible to minimize the time required to the normal combustion temperature at the beginning of ignition. Therefore, combustion efficiency and heating performance can be improved.

In addition, in the case of a solid fuel, unlike in the case of using oil or gas, a large amount of dust is contained in the exhaust gas, and the dust is deposited as it passes through the heating tube for heating the hot water, and the gas flow inside the heating tube is not desired. , And there is a problem of lowering the heating performance. However, since the large-capacity boiler according to the present invention is very easy to clean the inside of the heating tube, it is possible to prevent the above problems.

As described above, although the present invention has been described by way of limited embodiments and drawings, the present invention is not limited thereto and is intended by those skilled in the art to which the present invention pertains. Various modifications and variations are possible within the scope of equivalents of the claims to be described.

10: burner 20: heat exchanger
100: combustion chamber 110: combustion chamber appearance
120: internal space formation 121: external space formation
130: late combustion inner tube 131: late combustion appearance
140: gas discharge inner tube 141: gas discharge appearance
150: lower combustion chamber 160: discharge roller
200: body 210: inner body
220: discharge portion 230: fuel supply pipe
240: Blower 250a ~ 250h: Blower tube
300: first heater 301: second heater
302: third heater 410: fuel detection sensor
420: valve
600: tank 610: inlet
611: outlet 620: cover
621: cover flow pipe 630: first door
631: second door 640: exhaust pipe
700: first heating tube 710: second heating tube
720: third heating tube 800: first flow portion
801: dust outlet 810: second flow portion

Claims (11)

Tubular combustion chamber;
An inner space forming body located in a central portion of the combustion chamber, the upper portion of which is narrower than the lower portion;
A post combustion inner tube connected inside the inner space forming body to communicate with each other;
An outer space forming body having an upper cone shape narrower than the lower portion, being spaced apart from the inner space forming body by a predetermined interval, surrounding the outside of the inner space forming body, and having a plurality of through holes formed therein;
A late combustion exterior which is spaced apart from the late combustion inner tube by a predetermined interval to surround the outer side of the late combustion inner tube, and is connected to communicate with each other on top of the outer space forming body, and a plurality of through holes are formed;
A tank having an inlet through which water is introduced and an outlet through which the water is discharged;
A first heating tube located inside the tank and into which gas discharged from the combustion chamber is introduced;
A first flow part connected to one end of the first heating pipe so as to communicate with the inside of the first heating pipe, and including a partition wall blocking the water inside the first heating pipe and the tank;
A second heating tube having one end connected to communicate with the first flow part;
A second flow part connected to the other end of the second heating tube so as to communicate with the inside of the second heating tube, and including a partition wall for blocking the water inside the second heating tube and the tank;
The upper combustion exterior and the upper end of the post combustion inner tube is connected to each other to form a plurality of through holes, the other end of the first heating tube is a large capacity boiler connected to the gas discharge appearance.
The method of claim 1,
At least one first blower pipe connected to the outer space forming body to supply external air between the outer space forming body and the inner space forming body;
At least one second blower tube connected to the late combustion appearance to supply external air between the late combustion appearance and the late combustion inner tube;
At least one third blower pipe connected to the combustion chamber so as to supply external air to the combustion chamber;
A body surrounding the outside of the combustion chamber at a predetermined distance from the combustion chamber; And
At least one fourth blower pipe connected to the body to supply outside air between the body and the combustion chamber;
Further comprising a large capacity boiler in which the combustion chamber is formed with a plurality of through holes.
The method of claim 2,
The lower combustion chamber is connected to the lower portion of the combustion chamber so as to communicate with each other, the upper portion has a wider cone shape than the lower portion, and a plurality of through holes are formed.
Large capacity boiler containing more.
The method of claim 3,
A gas discharge inner tube connected to an upper portion of the combustion chamber so as to communicate with each other and having a plurality of through holes formed therein;
A gas discharge appearance surrounding the outside of the gas discharge inner tube spaced apart from the gas discharge inner tube at a predetermined interval; And
At least one fifth blower pipe connected to the gas exhaust appearance so as to supply outside air between the gas exhaust inner tube and the gas exhaust appearance;
Large capacity boiler containing more.
5. The method of claim 4,
At least one sixth blower pipe connected to the lower combustion chamber so as to supply outside air into the lower combustion chamber;
A heater provided in at least one of the first to sixth blower pipes to ignite fuel introduced into the combustion chamber;
A pair of discharge rollers provided at a lower portion of the lower combustion chamber; And
Further provided in the lower combustion chamber lower temperature measuring unit for measuring the temperature inside the lower combustion chamber,
When the temperature value measured from the temperature measuring unit is less than a predetermined value, the discharge roller is driven to discharge dust in the lower combustion chamber.
The method of claim 5,
A blower forcibly supplying the outside air to at least one of the first to sixth blower pipes; And
A valve provided in at least one of the first to sixth blower pipe to control the flow of the outside air
Large capacity boiler containing more.
delete The method of claim 1,
A third heating tube having one end connected to communicate with the second flow part; And
An exhaust pipe for discharging the gas discharged from the other end of the third heating tube to the outside of the tank
Large capacity boiler containing more.
9. The method of claim 8,
A first door coupled to one side of the first flow part to open and close the first flow part from the outside of the tank; And
A second door coupled to one side of the second flow part to open and close the second flow part from the outside of the tank;
Large capacity boiler containing more.
10. The method of claim 9,
A cover that surrounds and seals a portion where the first heating tube and the tank are connected to form an inner space; And
A cover flow pipe which connects the inside of the tank and the inner space of the cover to communicate with each other so that water inside the tank flows into and out of the inner space of the cover.
Large capacity boiler containing more.
The method of claim 10,
The tank is a large capacity boiler inclined at a predetermined angle so that the first door side is located lower than the second door side.

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