KR20100001731A - Incinerator - Google Patents

Abstract

PURPOSE: A combustion device is provided to achieve perfect combustion of combustible gas and the temperature rise of the exhaust gas using radiant heat. CONSTITUTION: A combustion device comprises a solid fuel feeder(100), a combustor(200), and a residue discharge device(300). The solid fuel feeder supplies solid fuel. The combustor comprises an air supply device which is provided in a housing(210) and supplies high pressure air to the inside of the housing. The residue discharge device discharges the residue of the burnt solid fuel. The housing has a dome-shaped ceiling(218) and an exhaust port(215) is formed on one side of the ceiling surface.

Description

Combustion device

The present invention relates to a combustion apparatus of a new structure that can improve thermal efficiency and achieve complete combustion by using radiant heat generated during combustion.

In general, a combustion apparatus for burning solid fuel, such as waste plastic solid fuel product (RPF) or municipal waste solid fuel product (RDF), as shown in Figures 1 and 2, the solid fuel supply for supplying solid fuel Apparatus 100, a combustor 200 for combusting the solid fuel supplied by the solid fuel supply device 100, and a residue discharge device 300 for discharging the residue of the burned solid fuel.

The combustor 200 is formed in a long cylindrical shape in the vertical direction and the pyrolysis combustion rotatably installed in the housing 210 having a venturi portion 213 therein, and the inner bottom surface of the combustion chamber 217 of the housing 210. A device 220, a drive device 230 provided outside the housing 210 and connected to the pyrolysis combustion device 220 to rotate the pyrolysis combustion device 220, and provided on one side of the housing 210 to the combustion chamber. It consists of an ignition burner 240 for igniting the solid fuel introduced into 217, and an air supply device 250 for supplying high-pressure air into the housing 210.

The housing 210 has a long vertical length and has a cylindrical shape having a ceiling surface, and an inner ceiling surface and a circumferential surface are formed of heat resistant walls 212 formed by masonry or attaching heat resistant bricks or heat resistant ceramics. The venturi part 213 is formed by protruding a middle portion of the heat-resistant wall 212 of the housing 210 in a ring shape into the housing 210 and at the same time narrowing the inner diameter of the housing 210, the inside of the housing 210. It functions to divide the space into the lower evaporation chamber 216 and the upper combustion chamber 217, and to increase the rate of rise of the combustible gas generated inside the evaporation chamber 216 by the pyrolysis combustion apparatus 220. . In addition, a solid fuel inlet 214 communicating with the evaporation chamber 216 and an exhaust port 215 communicating with the combustion chamber 217 are formed on the peripheral surface of the housing 210.

The air supply device 250 is connected to the air nozzle 251, the air nozzle 251 is exposed to the inner peripheral surface of the housing 210, the air pump 252 connected to the air nozzle 251, and the air pump 252 A plurality of injection holes (253a) is formed on the circumferential surface and extends through the upper end of the housing 210 to be formed therein and includes an auxiliary air supply pipe 253 for supplying air into the housing 210.

At this time, the injection hole 251a of the air nozzle 251 is exposed to the inner circumferential surface of the venturi part 213 and the inner circumferential surface of the housing 210 above and below the venturi part 213, as shown in FIG. The direction of 251a is inclined in the circumferential direction of the inner circumferential surface of the venturi portion 213.

Therefore, the combustible gas rising from the evaporation chamber 216 to the combustion chamber 217 by the air injected at high pressure in the injection port 251a of the air nozzle 251 rotates in a spiral direction to generate a tornado, The air is uniformly mixed so that the combustible gas can be completely burned, and additional air is supplied to the center of the combustible gas which is rotated while causing the whirlwind inside the combustion chamber 217 using the auxiliary air supply pipe 253. Ensure that flammable gases are burned completely and smoothly.

Combustion device configured as described above, when the solid fuel is injected into the ignition burner 240 by inputting the solid fuel into the evaporation chamber 216 through the solid fuel inlet 214 using the solid fuel supply device 100, The solid fuel is discharged from the combustible gas through the heating-melting-vaporization process, and the hot combustible gas evaporated from the solid fuel is passed through the venturi part 213 and mixed with the air supplied through the air nozzle 251. After being raised and burned while generating a tornado, it is supplied to a boiler not shown through the exhaust port 215 and heat exchanged, thereby enabling heating or power generation. At this time, the residue of the burned solid fuel is discharged to the outside by the residue discharge device 300, the auxiliary air supply pipe 253 by additionally supplying air to the center of the combustible gas that is burned in the housing 210 To ensure that flammable gases are completely burned.

However, in the combustion device, since the auxiliary air supply pipe 253 protrudes into the housing 210, the auxiliary air supply pipe 253 is intensively heated by the combustion heat generated when the combustible gas is combusted. Accordingly, the service life of the auxiliary air supply pipe 253 is short, so that it is expensive to repair and maintain the auxiliary air supply pipe 253, and the operation of the combustion device must be frequently stopped to repair or maintain the auxiliary air supply pipe 253. There was this.

In addition, in order to completely burn the combustible gas discharged from the solid fuel, it is preferable that the mixed gas of the combustible gas and the air is maintained at a high temperature. However, in the conventional combustion apparatus, the exhaust port 215 is formed on the side of the combustion chamber 217. In addition, the flammable gas that is raised by the air supply device 250 and is not sufficiently stayed inside the combustion chamber 217 is discharged to the exhaust port 215, thereby making it difficult to achieve complete combustion.

In particular, when the combustible gas sufficiently stays inside the combustion chamber 217, the heat resistant wall 212 is continuously heated by the heat generated by the combustion of the combustible gas, and the combustion chamber is caused by the radiant heat generated by the heated heat resistant wall 212. 217, since the gas inside is heated, it is effective to raise the temperature of the exhaust gas supplied to the boiler through the exhaust port 215 as much as possible, but such a combustor is discharged through the exhaust port 215 at a fast time. In addition, it is difficult to sufficiently heat the heat resistant wall 212 or to increase the temperature of the exhaust gas by using the radiant heat generated from the heated heat resistant wall 212, resulting in a problem that the thermal efficiency is lowered.

The heat generated by the combustion of the combustible gas causes the heat-resistant wall 212 to be excessively heated to weaken the adhesive portion of the heat-resistant brick or the heat-resistant ceramic forming the heat-resistant wall 212, and thus heat-resistant the heat-resistant wall 212, in particular, the ceiling surface. There was a problem that the wall 212 could fall off.

The present invention is to solve the above problems, by using the radiant heat generated during the combustion of the combustible gas, while burning the combustible gas, at the same time increase the temperature of the exhaust gas as possible to increase the thermal efficiency, maintenance It is an object of the present invention to provide a combustion apparatus of a new configuration that is easy.

The present invention for achieving the above object,

A solid fuel supply device 100 for supplying solid fuel;

The combustor 200 has a long cylindrical shape in the vertical direction and is provided with a venturi portion 213 therein, a housing 210 having a solid fuel inlet 214 and an exhaust port 215 formed therein, and a housing 210. A pyrolysis combustion device 220 rotatably installed on the bottom surface of the combustion chamber 217 of the combustion chamber 217, and connected to the pyrolysis combustion device 220 and connected to the pyrolysis combustion device 220 to rotate the pyrolysis combustion device 220. An apparatus 230, an ignition burner 240 provided on one side of the housing 210 to ignite the solid fuel introduced into the combustion chamber 217, and a high pressure air provided in the housing 210 to the inside of the housing 210. Combustor 200 including an air supply device 250 for supplying;

In the combustion device configured to include; Residual discharge device 300 for discharging the residue of the burned solid fuel,

The inner ceiling surface 218 of the housing 210 is formed in a domed shape concave upward, the exhaust port 215 is formed on one side of the ceiling surface 218,

The air supply device 250 includes an air pump 255 for supplying high pressure air;

It is embedded in the wall surface of the housing 210 to be spirally wound along the circumferential surface of the housing 210 and both ends are connected to an air supply pipe 256a and an air supply pipe 256a connected to the air pump 255. It is a structure characterized in that it comprises a plurality of air nozzles (256b) is installed so that the end is directed toward the inside of the housing (210).

In the combustion apparatus according to the present invention, as the mixed gas of combustible gas and air combusted in the combustion chamber is rotated along the ceiling surface configured as a dome shape, the combustion gas stays in the combustion chamber for a long time, and the heat resistant wall is heated to generate radiant heat. Since is heated to a high temperature, it is possible to achieve complete combustion without using a separate auxiliary air supply pipe, easy maintenance, there is an advantage that the heat efficiency of the exhaust gas is increased to increase the thermal efficiency.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

3 to 7, the combustion apparatus according to the present invention includes a solid fuel supply device 100 for supplying solid fuel; The combustor 200 is formed in a long cylindrical shape in the vertical direction, the venturi portion 213 is provided therein, the housing 210, the solid fuel inlet 214 and the exhaust port 215 is formed on the circumferential surface, the housing ( A pyrolysis combustion device 220 rotatably installed on the bottom surface of the combustion chamber 217 of the combustion chamber 217 and provided outside the housing 210 and connected to the pyrolysis combustion device 220 to rotate the pyrolysis combustion device 220. An ignition burner 240 provided at one side of the driving device 230, the housing 210, and ignited the solid fuel introduced into the combustion chamber 217, and an air supply device for supplying high pressure air into the housing 210. A combustor 200 composed of 250; The residue discharge device 300 for discharging the residue of the burned solid fuel is the same as in the prior art.

At this time, the housing 210 is a heat-resistant wall formed by masonry or attaching the outer housing 211 of the metal material having an inner space having a long cylindrical shape in the vertical direction, and the heat-resistant brick 212a in the interior of the outer housing 211 ( 212, the venturi part 213 has an intermediate portion of the heat-resistant wall 212 of the housing 210 protruding in a ring shape into the housing 210 to narrow the inner diameter of the housing 210 and at the same time the housing 210. ) Is divided into an evaporation chamber 216 on the lower side and a combustion chamber 217 on the upper side. In addition, a solid fuel inlet 214 communicating with the evaporation chamber 216 and an exhaust port 215 communicating with the combustion chamber 217 are formed on the circumferential surface of the housing 210 to provide a solid fuel supply device 100. The solid fuel is introduced into the evaporation chamber 216 by using the same, and the combustible gas combusted in the combustion chamber 217 is configured to be supplied to the boiler not shown through the exhaust port 215.

And, in the combustion apparatus according to the present invention, as shown in Figure 4, the interior of the housing 210, the ceiling surface 218 is formed in a domed shape concave upward, the exhaust port 215 is a ceiling surface 218 It is formed on one side of.

To this end, of the heat resistant walls 212 forming the inner surface of the housing 210, each of the heat resistant bricks 212a constituting the heat resistant wall 212 of the inner ceiling surface 218 of the housing 210 has an outer housing 211. It is made of a wedge shape that is wider on the outer surface that is in close contact with the inner side and becomes narrower toward the inner side, and the heat-resistant bricks 212a formed in such a shape are stacked in a dome shape so as to fit with each other, thereby providing a ceiling surface of the heat-resistant wall 212. 218 forms an upward concave dome shape. In addition, the exhaust port 215 is formed in an inclined direction on one side of the ceiling surface 218 having a dome shape.

The air supply device 250 is an air pump 255 for supplying high pressure air, an air supply line 256 connected to the air pump 255 and installed in the venturi part 213, and an air pump 255. The auxiliary air supply line 257 is connected to the upper and lower portions of the air supply line 256.

The air supply line 256 is embedded in the housing 210 and is connected to the air supply pipe 256a connected to the air pump 255, and connected to the air supply pipe 256a, and an end of the air supply line 256 is connected to the inside of the housing 210. It consists of a plurality of air nozzles (256b) that are installed to face.

As shown in FIGS. 5 and 6, the air supply pipe 256a is wound inside the heat-resistant wall 212 of the housing 210, in particular, the venturi part 2 so as to be spirally wound along the circumferential surface of the housing 210. 213 is buried in the interior.

The air nozzle 256b is installed at regular intervals along the air supply pipe 256a so as to face the center of the spirally wound air supply pipe 256a, and the front end thereof faces the inner circumferential surface of the venturi part 213 in a radial direction. The high pressure air is injected into the combustible gas passing through the venturi part 213 to form a mixed gas in which the combustible gas and the air are mixed.

At this time, the air pump 255 is simultaneously connected to both ends of the air supply pipe (256a), by supplying air at both ends of the air supply pipe (256a) simultaneously, a plurality of air nozzles (connected to the air supply pipe (256a) ( Air is discharged at the same pressure in 256b).

The auxiliary air supply line 257 is formed in a ring shape to the heat-resistant wall 212 of the housing 210, in particular, the heat-resistant wall of the upper and lower sides of the venturi portion 213 to be located in the upper and lower portions of the air supply line (256) ( A plurality of auxiliary air nozzles (257b) installed in the air duct (257a) embedded in the 212 and connected to the air pump 255, and the air duct (257a) is installed so that the end is protruded to the inner peripheral surface of the housing 210. )

At this time, the auxiliary air nozzle 257b of the auxiliary air supply line 257 is formed so that the tip portion is inclined in the circumferential direction of the inner circumferential surface of the housing 210, as shown in Figure 7, the high pressure in the auxiliary air nozzle (257b) As the flammable gas rising from the evaporation chamber 216 to the combustion chamber 217 rotates in a spiral direction by the air injected into the gas, the tornado is generated, so that the combustible gas and the air are uniformly mixed so that the flammable gas can be completely burned. do.

The operation of the combustion device configured as described above is as follows.

First, when the solid fuel is introduced into the evaporation chamber 216 of the housing 210 by using the solid fuel supply device 100, and the pyrolysis combustion device 220 and the ignition burner 240 are operated, the solid fuel is Combustible gas is discharged through the process of heating-melting-vaporization, and the high temperature combustible gas evaporated from the solid fuel passes through the venturi part 213, and the air supplied by the air supply device 250 is mixed. Combustion flows into the combustion chamber 217 in the state of the mixer. At this time, the combustible gas rising from the evaporation chamber 216 to the combustion chamber 217 is rotated in a spiral direction by the air injected to be inclined in the circumferential direction of the housing 210 from the auxiliary air nozzle 257 to cause a whirlwind. Is raised.

In addition, the mixer in which the combustible gas and air are mixed gradually rises as it is combusted in the combustion chamber 217, and when the internal ceiling surface 218 of the combustion chamber 217 is reached, the mixer is rotated along the dome-shaped ceiling surface 218 to be combustible gas. And the air is smoothly mixed and at the same time stayed in the combustion chamber 217 for a long time and completely burned and then supplied to the boiler not shown through the exhaust port 215 to be heat exchanged. At this time, as the combustible gas is combusted, the dome-shaped ceiling surface 218 is sufficiently heated, and radiant heat is emitted from the heated ceiling surface 218, thereby increasing the mixed gas of combustible gas and air flowing into the combustion chamber 217. By heating to a temperature, the mixed gas of the combustible gas and the air is maintained at a high temperature to be more completely burned more smoothly, and at the same time to increase the temperature of the exhaust gas exhausted to the exhaust port (215).

Then, all of the solid fuel remaining after the combustible gas is evaporated is discharged to the outside by the residue discharge device 300 and processed.

The combustion device configured as described above has a dome shape in which the inner ceiling surface 218 is concave upward, so that the mixed gas of combustible gas and air circulates along the ceiling surface 218, so that the combustible gas and air are not only uniformly mixed, but also the combustion chamber. (217) Since it can stay for a long time inside, there is an advantage that the combustible gas can be completely burned. Therefore, as a result of the complete combustion without using a separate auxiliary air supply pipe for supplying additional air to the center of the combustible gas, the conventional combustion apparatus that requires a cost and time to maintain the auxiliary air supply pipe In contrast, there is an advantage that easy maintenance.

In particular, as the mixed gas is burned in the combustion chamber 217 for a long time, the ceiling surface 218 of the housing 210 having a dome shape, in particular, the heat resistant wall 212 is sufficiently heated to emit radiant heat. Accordingly, the mixed gas of the continuously supplied combustible gas and air is heated to a high temperature, thereby increasing the temperature of the exhaust gas exhausted through the exhaust port 215, thereby increasing the thermal efficiency.

In addition, the air supply line 256 of the air supply device 250 is composed of a spirally wound air supply pipe (256a), a plurality of air nozzles (256b) provided in the air supply pipe (256a), air supply Since the air supplied by the air pump 255 connected to both ends of the pipe (256a) is injected, the air nozzle (256b) as a whole to inject air at a uniform pressure, so that the air can be uniformly mixed with the combustible gas In addition, since the air supply pipe 256a is spirally wound to mount a plurality of air nozzles 256b on one air supply pipe 256a, the structure of the air supply line 256 is simplified. There is an advantage.

In addition, the heat-resistant brick 212a constituting the ceiling surface 218 of the heat-resistant wall 212 is composed of a wedge shape having a wide width of the outer surface and narrowing toward the inner side, such a heat-resistant brick 212a is a dome shape Since the ceiling surface 218 is stacked to form the ceiling surface 218, even if the heat-resistant walls 212 are heated to a high temperature to weaken the adhesive strength of each of the heat-resistant bricks 212a, the heat-resistant bricks 212a are interlocked with each other and do not collapse.

In addition, the upper and lower parts of the air supply line 256 is provided with an auxiliary air supply line 257 in which the auxiliary air nozzle 257b is inclined in the circumferential direction of the housing 210, so that the combustible gas rises while causing the whirlwind. As a result, the combustible gas and the air are uniformly mixed, and thus there is an advantage in that complete combustion can be achieved.

In the present embodiment, the heat-resistant wall 212 is configured by attaching or attaching the heat-resistant brick (212a), in addition to the heat-resistant brick (212a), any heat-resistant material capable of withstanding heat-resistant ceramic or other high temperature heat is available.

In addition, in the present embodiment, the exhaust port 215 is illustrated to be inclined to one side of the ceiling surface 218, if necessary, the exhaust port 215 in the vertical direction to the center or one side of the ceiling surface 218, if necessary It is also possible to install.

In this embodiment, the air supply line 256 is illustrated to be installed inside the venturi part 213, but the position of the air supply line 256 is not limited to the venturi part 213, and the housing If the position that can supply air to the inside of 210, the position can be adjusted as needed.

8 and 9 illustrate a second embodiment according to the present invention, in which the air nozzle 256 has a circumferential direction of the venturi part 213 on the inner circumferential surface of the venturi part 213. To be inclined. In addition, the air nozzle 256b includes a lower air nozzle 256c disposed to be inclined upward and an upper air nozzle 256d positioned above the lower air nozzle 256c and inclined downward.

In detail, the air nozzle 256b connected to the spirally wound air supply pipe 256a is divided into a lower lower air nozzle 256c and an upper upper air nozzle 256d according to a position. The air nozzle 256c and the upper air nozzle 256d are disposed to be inclined in the circumferential direction of the venturi part 213, and the lower air nozzle 256c is inclined upwardly, and the upper air nozzle 256d is lowered. To face.

Accordingly, the venturi part 213 is formed by the air discharged in the circumferential direction in an inclined state upward from the lower air nozzle 256c and the air discharged in the circumferential direction in an inclined direction downward in the upper air nozzle 256d. As the combustible gas passing through) is mixed up and down and rotates in a spiral direction with air, causing a tornado, the combustible gas and the air are mixed uniformly and completely burned, and the mixed gas of the combustible gas and air Since the combustion is rotated along the center of the interior of the housing 210, the combustion heat generated when the combustible gas is burned has an advantage of minimizing the transfer to the heat-resistant wall 212 in the housing 210.

At this time, the air nozzle (256b) is not disposed to be inclined in the circumferential direction as a whole, it is also possible to arrange a portion to face the center of the venturi 213.

FIG. 10 illustrates a third embodiment according to the present invention, wherein the air supply pipe 256a of the air supply line 256 includes a first air supply pipe 258a embedded in the venturi part 213. And a second air supply pipe 259a formed separately from the first air supply pipe 258a and embedded in the venturi part 213 to be positioned above the first air supply pipe 258a. The air nozzle 256b includes a plurality of first air nozzles 258b connected to the first air supply pipe 258a and a second air nozzle 259b connected to the second air supply pipe 259a.

At this time, the first air nozzle 258b is disposed to be inclined in the circumferential direction of the venturi part 213 to supply air to the combustible gas rising from the evaporation chamber 216 to the combustion chamber 217, and at the same time, the combustible gas Is rotated in a spiral direction to generate a whirlwind, and the second air nozzle 259b is connected radially to face the central portion of the venturi part 213 to cause a whirlwind to additionally supply air to the combustible gas that rises. It is configured to be.

As described above, the air supply line 256 may be divided into two or more, and as necessary, the first air supply pipe 258a, the first air nozzle 258b, and the second air supply pipe. The positions of the 259a and the second air nozzle 259b may be interchanged.

1 is a side configuration diagram showing a conventional combustion device,

Figure 2 is a plan view showing an air supply of a conventional combustion device,

3 is a side configuration view showing a combustion device according to the present invention;

4 is a side sectional view showing a combustion chamber of a combustion apparatus according to the present invention;

5 is a plan sectional view showing an air supply device of another combustion apparatus according to the present invention;

Figure 6 is a perspective view of the air supply of the combustion apparatus according to the present invention,

7 is a plan sectional view showing an auxiliary air supply line of a combustion apparatus according to the present invention;

8 is a plan sectional view showing a second embodiment according to the present invention;

9 is a side sectional view showing a second embodiment according to the present invention;

10 is a side sectional view showing a third embodiment according to the present invention.

Claims (5)

A solid fuel supply device 100 for supplying solid fuel; The combustor 200 has a long cylindrical shape in the vertical direction and is provided with a venturi portion 213 therein, a housing 210 having a solid fuel inlet 214 and an exhaust port 215 formed therein, and a housing 210. A pyrolysis combustion device 220 rotatably installed on the bottom surface of the combustion chamber 217 of the combustion chamber 217, and connected to the pyrolysis combustion device 220 and connected to the pyrolysis combustion device 220 to rotate the pyrolysis combustion device 220. An apparatus 230, an ignition burner 240 provided on one side of the housing 210 to ignite the solid fuel introduced into the combustion chamber 217, and a high pressure air provided in the housing 210 to the inside of the housing 210. Combustor 200 including an air supply device 250 for supplying; In the combustion device configured to include; Residual discharge device 300 for discharging the residue of the burned solid fuel, The inner ceiling surface 218 of the housing 210 is formed in a domed shape concave upward, the exhaust port 215 is formed on one side of the ceiling surface 218, The air supply device 250 includes an air pump 255 for supplying high pressure air; It is embedded in the wall surface of the housing 210 to be spirally wound along the circumferential surface of the housing 210 and both ends are connected to an air supply pipe 256a and an air supply pipe 256a connected to the air pump 255. Combustion apparatus comprising a; air supply line (256) having a plurality of air nozzles (256b) is installed so that the end is directed toward the inside of the housing (210). According to claim 1, wherein the inner surface of the housing 210 is made of a heat-resistant wall 212 configured by gluing or attaching a heat-resistant material, forming a heat-resistant wall 212 of the ceiling surface 218 inside the housing 210 Heat-resistant material is a combustion device, characterized in that the width of the outer surface is made of a wedge shape narrowing toward the inner side. The air nozzle (256b) of the air supply line 256 is inclined in the circumferential direction of the venturi portion 213 on the inner circumferential surface of the venturi portion 213, the venturi portion 213 Combustor characterized in that the combustible gas passing through is mixed with the air supplied through the injection port (257a) is rotated in a spiral direction. According to claim 1, wherein the air nozzle (256b) of the air supply line 256 is arranged to be inclined upward and the lower air nozzle 256c, the lower air nozzle (256c) is arranged to be inclined downward Combustion apparatus, characterized in that consisting of the upper air nozzle (256d). The air supply pipe (256a) of the air supply line (256) comprises: a first air supply pipe (258a) embedded in the venturi portion (213); A second air supply pipe 259a formed separately from the first air supply pipe 258a and embedded in the venturi part 213, A plurality of first air nozzles 258b connected to the first air supply pipe 258a and arranged to be inclined in the circumferential direction of the venturi part 213; And a second air nozzle (259b) connected to the second air supply pipe (259a) to face the central portion of the venturi part (213).

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