KR200445277Y1 - Combustor with improved heat recovery and durability - Google Patents

Abstract

The combustion apparatus of the present invention has a combustion cylinder that receives combustion air from the outside and combusts the fuel contained therein, and the combustion that recovers heat by discharging the high temperature combustion gas generated in the combustion cylinder to the boiler through the combustion gas discharge unit. In the apparatus, the combustion gas discharge portion is mounted on the upper portion of the combustion cylinder, the lower portion is in communication with the upper portion of the combustion cylinder, characterized in that a plurality of water pipes are built in the body of the combustion gas discharge portion.

Accordingly, an object of the present invention is to provide a combustion device having a combustion gas discharge part having improved durability and improving heat recovery rate and thermal efficiency.

Heat recovery, combustion gas discharge, water pipe, durability, combustion device

Description

Combustion device with improved heat recovery and durability {COMBUSTION APPARATUS WITH IMPROVED HEAT RECOVERY RATE AND DURABILITY}

The present invention relates to a heat recovery combustion device, and more particularly, to a heat recovery combustion device for recovering the heat of combustion generated by burning solid fuel and the like in the combustion chamber for use as energy.

In general, in industrial facilities that require industrial hot water, steam, or hot gas, a combustion device is used to generate thermal energy by igniting and burning fuel in a combustion cylinder to obtain thermal energy. As such, solid fuels such as RDF fueled with domestic waste or RPF fueled with waste plastics are widely used in terms of economic efficiency and resource recycling.

By the way, the conventional combustion device is a way to put a large amount of solid fuel, etc. in the lower part of the combustion cylinder and combusts, but the fuel is incompletely burned, resulting in waste of materials as well as low thermal efficiency, many ashes at once (re) This can be cumbersome because it is impossible to automate the remaining ash processing, and once combustion is completed, continuous combustion is difficult and the calorific value is not uniform.

In addition, the solid fuel has a problem in that a large amount of gas or particles that pollute the environment, such as dust, carbon monoxide, soot, gaseous HCL, SOx, NOx, dioxin during combustion.

In order to solve this problem, the combustion apparatus 1000 of FIG. 1 has been developed. The heat recovery combustion apparatus 1000 according to the related art generates a high temperature combustion gas by burning the solid fuel supplied from the fuel hopper 310 in the combustion cylinder 100. The air cooling chamber 150, the passage 140a of the middle wall 140, the swirl flow supply chamber 130, and the passage 120a of the inner wall 120 are supplied to the combustion chamber 110.

In addition, the high temperature combustion gas generated by burning the fuel in the combustion chamber 110 is supplied to a heat recovery means such as a boiler through the elbow-shaped combustion gas discharge pipe 400 to recover heat.

By the way, in the conventional combustion apparatus, the combustion gas discharge pipe 400 is made of a refractory wall, and due to the continuous contact with the high temperature combustion gas, it is not necessary to replace it for a long time due to cracks and the like. In addition, there is a problem that ash (ash), fine particles, etc. contained in the combustion gas bind to the fireproof wall and are difficult to remove.

In addition, when combustion air is supplied to the combustion chamber, the combustion air is supplied to the swirl flow supply chamber 130 through the passage 140a, and then directly supplied to the combustion chamber 110 through the passage 120a of the inner wall 120 to supply the swirl flow supply chamber. The air preheating function of the fall was a disadvantage.

The present invention has been made in order to solve the problems of the prior art, and has an object of providing a combustion device having a combustion gas discharge portion with improved durability, and improved heat recovery rate and thermal efficiency.

The combustion apparatus of the present invention has a combustion cylinder that receives combustion air from the outside and combusts the fuel contained therein, and the combustion that recovers heat by discharging the high temperature combustion gas generated in the combustion cylinder to the boiler through the combustion gas discharge unit. In the apparatus, the combustion gas discharge portion is mounted on the upper portion of the combustion cylinder, the lower portion is in communication with the upper portion of the combustion cylinder, characterized in that a plurality of water pipes are built in the body of the combustion gas discharge portion.

In addition, the combustion apparatus of the present invention is characterized in that a plurality of water pipes of the combustion gas discharge portion is formed on the body side wall and the upper wall of the combustion gas discharge portion.

In addition, the combustion apparatus of the present invention is characterized in that the water pipe outlet pipe for connecting the water pipe and the boiler of the combustion gas discharge unit is characterized in that the water circulated in the water pipe is introduced into the boiler.

In addition, the combustion apparatus of the present invention, one end is in communication with one end of the combustion gas discharge portion, the other end is further provided with a hollow combustion gas passing portion for communicating the one side of the boiler and the combustion gas flowing from the combustion gas discharge portion to the boiler. And, the body of the combustion gas passing portion is characterized in that a plurality of water pipes are built.

In addition, the combustion apparatus of the present invention is characterized in that the water pipe outlet pipe for connecting the water pipe and the boiler of the combustion gas passing portion is characterized in that the water circulated in the water pipe is introduced into the boiler.

In addition, the combustion apparatus of the present invention is characterized in that the combustion gas passing portion is provided with a redistribution pipe extending downwardly formed in the lower portion to discharge the ash contained in the combustion gas passing through the inside.

Combustion apparatus according to the present invention is provided with a combustion gas discharge portion with improved durability, there is an effect to improve the heat recovery rate and thermal efficiency.

Hereinafter, a combustion apparatus according to a first embodiment of the present invention will be described in detail with reference to the drawings.

2 is a longitudinal sectional view of a combustion apparatus according to a first embodiment of the present invention, FIG. 3 is a cross sectional view of a combustion gas discharge unit in FIG. 1, and FIG. 4 is a longitudinal sectional view of a combustion device according to a second embodiment of the present invention. .

Combustion apparatus 100 according to a first embodiment of the present invention comprises a combustion cylinder 10 for burning fuel therein, and a combustion gas discharge unit 30.

First, the combustion cylinder 10 has a cylindrical shape for accommodating and burning solid fuel therein. The combustion chamber 11 and the inner wall 12 which enclose the inner wall 12 in the combustion cylinder 10 to combust fuel, and the inner wall 12. A swirl flow supply chamber 13 formed at an outer periphery to supply combustion air into the combustion chamber 11 and combustion air supplied from the outside around the swirl flow supply chamber 13 and supplied from the outside; ) Is provided with an air cooling chamber 15 for supplying.

The upper one side of the combustion cylinder 10 is open to discharge the burned combustion gas, the lower edge is formed with a redistribution outlet 19 so that the ash of the burned solid fuel is discharged, the outer side is the outer wall ( It is formed surrounded by the 16, the middle wall 14 and the inner wall 12 is formed in sequence from the outer wall 16 to the inner side in order, and to receive and burn the solid fuel in the combustion chamber 11 surrounded by the inner wall (12). do.

The swirl flow supply chamber 13 is formed in the space between the inner wall 12 and the middle wall 14 of the combustion cylinder 10, and the swirl flow guide chamber 13 is provided with a swing guide vane so that the supplied combustion air can be turned better. 13a) is formed spirally from top to bottom. In addition, a combustion air supply passage 12a for injecting combustion air from the swirl flow supply chamber 13 into the combustion chamber 11 is formed at the lower end of the inner wall 12 of the combustion cylinder 10 in a circular shape.

An air cooling chamber 15 is formed in a space between the middle wall 14 and the outer wall 16 of the combustion cylinder 10, and the swirl flow supply chamber 13 is formed in the upper portion of the middle wall 14 of the combustion cylinder 10 from the air cooling chamber 15. An air supply passage 14a for supplying combustion air is formed.

Therefore, after the combustion air flowing into the air cooling chamber 15 moves to the upper part of the air cooling chamber 15, the combustion air flows from the upper portion to the lower portion of the swirl flow supply chamber 13 through the air supply passage 14a at the upper end of the middle wall 14. It is moved and supplied to the combustion chamber 11 through the lower combustion air supply passage 12a of the inner wall 12.

In addition, a combustion air upward guide plate 18a which is formed to be inclined upward toward the combustion chamber 11 is formed at an inner end portion of the flange 18 forming the bottom surface of the swirl flow supply chamber 13 so that combustion air is discharged from the swirl flow supply chamber 13. It is supplied inclined upward while rotating into the combustion chamber 11. When the solid fuel is first combusted, combustible gas is generated and rises to the upper side of the solid fuel. The combustion air upward guide plate 18a directly supplies the combustion air to the combustible gas to complete combustion of the combustible gas.

In addition, the lower portion of the combustion chamber 11 is provided with a rotatable grate 17 rotatably installed. The rotary grate 17 is for burning the solid fuel supplied to the upper surface thereof, and a fuel supply port 17a through which the solid fuel is supplied is formed in the center, and is inclined downward from the center to the edge. The rotary grate 17 is rotated by the roller 20 formed on the outside, the rotation speed is adjusted by the gear box 22 connected to the gear motor 21. By such a configuration, the solid fuel that is constantly supplied from the fuel supply port 17a gradually moves from the center of the upper surface of the rotary grate 17 to the outer edge, and the ash produced by burning while moving is the rotary grate 17. While rotating, it is discharged to the outside through the redistribution port 19 formed at the lower edge of the combustion chamber 11.

On the other hand, the combustion gas discharge unit 30 is mounted on the upper portion of the combustion cylinder 10 and has a hollow shape to the high temperature combustion gas generated by the combustion of the solid fuel in the combustion chamber 11 to the boiler 50 or the like. In order to supply, the lower portion of the combustion gas discharge unit 30 is in communication with the upper portion of the combustion cylinder 10, one side of the communication is in communication with the boiler 50, the combustion gas discharge unit 30 of the body 31 Inside the side wall 32 and the upper wall 33, a plurality of water pipes 34 are interconnected to each other. Multiple water pipes 34 may be interconnected in a zigzag fashion. In addition, the outlet pipe 35 is provided between the water pipe 34 and the boiler 50 so that water circulated in the water pipe 34 and circulated in the water pipe 34 flows into the boiler. The body 31 of the combustion gas discharge unit 30 is preferably made of steel (steel) material.

The combustion gas discharge unit 30 has such a configuration, so that the temperature can be lowered by the water pipe 34 inside the body 31 even if the combustion gas discharge unit 30 is in continuous contact with the hot combustion gas, thereby improving durability and at the same time improving the water pipe 34. By circulating by introducing the first preheated water into the boiler 50, there is an advantage to improve the heat recovery rate. In addition, the body 31 of the combustion gas discharge unit 30 is formed of a steel material can significantly lower the binding properties of the ash or fine particles in the combustion gas due to the heterogeneity of the material compared to the conventional device consisting of a conventional refractory wall. .

Hereinafter, a method of operating the combustion device 100 according to the first embodiment of the present invention configured as described above.

First, the solid fuel is constantly supplied from the fuel hopper 31 into the combustion chamber 11 and the solid fuel supplied into the combustion chamber 11 is preheated and ignited by a preheat burner and an ignition burner (not shown) to be combusted. The solid fuel supplied to the upper side of the rotary grate 17 is combusted and moved to the edge of the rotary grate 17 over time due to the continuous supply of fuel, and at the edge of the rotary grate 17 It is completely burned and turned into ash.

Then, the ash produced by burning the solid fuel is discharged to the outside through the redistribution outlet 19 while the rotary grate 17 rotates.

On the other hand, the combustion air required for burning the solid fuel is supplied from the outside in the tangential direction of the air cooling chamber 15 and the combustion air supplied to the air cooling chamber 15 moves to the upper portion of the air cooling chamber 15 to form the middle wall 14. Is supplied to the swirl flow supply chamber 13 again through the combustion air supply passage 14a. Combustion air supplied to the swirl flow supply chamber 13 is guided by the swing guide vanes 13a at the upper portion and moves downward while turning to the combustion chamber 11 through the combustion air supply passage 12a formed at the inner wall 12. It is supplied while rotating inside. Therefore, even when the combustion chamber 11 is small compared to when the combustion air is directly supplied to the fuel, the combustion air is in direct contact with most of the fuel, thereby lowering the manufacturing cost and improving the thermal efficiency. Further, it is supplied inclined upward into the combustion chamber by the combustion air upward guide plate 18a of the bottom flange 18 of the swirl flow supply chamber 13. Since the combustion air supplied from the outside is inclined upwardly from the lower side of the combustion chamber 11 and some air is supplied while rotating through the combustion chamber inner wall 12, the internal wall 12 is cooled to lower the temperature of the inner wall 12. There is an advantage that can be improved durability. At this time, the external air moves to the upper portion of the air cooling chamber 15 and then moves to the lower portion of the swirl flow supply chamber 13, whereby the moving distance becomes longer, thereby providing a more reliable preheating effect in the swirl flow supply chamber 13, and at the same time air cooling. The chamber 15 can more reliably perform the heat-blocking function from the swirl flow supply chamber 13 to the outside.

On the other hand, the high temperature combustion gas generated by the combustion of the solid fuel in the combustion chamber 11 is introduced into the combustion gas discharge unit 30 through the open upper portion of the combustion chamber 11 and then introduced into the boiler 50. At this time, the combustion gas discharge unit 30 has a plurality of water pipes 34 interconnected inside the body 31 is installed to lower the temperature of the body 31 to improve durability, circulated by the water pipe 34 While the preheated water is introduced into the boiler 50, the heat recovery rate may be improved. The hot combustion gas supplied to the boiler 50 is used to generate industrial hot water or steam by heat exchange.

Next, a heat recovery combustion apparatus 1 'according to a second embodiment of the present invention will be described with reference to the drawings.

4 is a longitudinal cross-sectional view of the combustion device 1 'according to the second embodiment of the present invention, and FIG. 5 is a cross-sectional view of FIG.

The configuration of the heat recovery combustion apparatus 1 ′ according to the second embodiment of the present invention will be described only with differences from the first embodiment. In the heat recovery combustion apparatus 1 ′ according to the second embodiment, a combustion gas passing portion 40 is further provided between the combustion gas discharge unit 30 and the boiler 50 as compared with the first embodiment.

Combustion gas passing portion 40 is the combustion gas flows from the combustion gas discharge unit 30 flows into the boiler 50 through the combustion gas passage 40, the combustion gas passage 40 is made of a hollow shape, One end 47 is in communication with one end of the combustion gas discharge unit 30, the other end 48 is in communication with one side of the boiler (50). In addition, a plurality of water pipes 44 interconnected are installed in the body 41 of the combustion gas passing part 40, and an outlet pipe connecting the water pipe 44 of the combustion gas passing part 40 to the boiler 50 ( 45 is provided so that the water circulated in the water pipe 44 is introduced into the boiler 50, thereby lowering the body temperature of the combustion gas passing portion and improving the heat recovery rate.

In addition, the combustion gas passing portion 40 is provided with a redistribution pipe 46 extending downward in the lower portion so as to discharge the ash contained in the combustion gas passing through the combustion gas. Therefore, the ash generated after the combustion of fuel in the combustion chamber 11 is mostly discharged through the redistribution outlet 19 of the combustion chamber 11, but the small-size ash remaining in the combustion gas is the redistribution pipe of the combustion gas passage 40. Can be discharged through the 46 can reduce the amount of contaminants, such as ash contained in the combustion gas flowing into the boiler (50).

The operation method of the second embodiment is the same as that of the first embodiment.

As described above, the combustion device as a preferred embodiment of the present invention has been described with reference to an example using a solid fuel, but the combustion device of the present invention is not limited to a solid fuel, and it is obvious that the combustion device can be applied to gas fuel and liquid fuel. In this embodiment, the boiler is exemplified as a heat recovery means, but any means may be used to recover heat from a high temperature combustion gas through heat exchange. In addition, those skilled in the art will readily appreciate that various modifications are possible without departing from the spirit of the invention as set forth in the claims below.

1 is a view showing a combustion apparatus according to the prior art,

2 is a view showing a combustion apparatus according to the first embodiment of the present invention;

3 is a cross-sectional view of the combustion gas discharge unit in FIG.

4 is a view showing a combustion device according to a second embodiment of the present invention;

5 is a cross-sectional view of the combustion gas passage in FIG.

<Description of the symbols for the main parts of the drawings>

1, 1 ': combustion apparatus 10: combustion cylinder

11: combustion chamber 12: inner wall

13: swirl flow supply room 14: middle wall

15: air cooling chamber 16: outer wall

17: rotary grate

31: fuel hopper

30: combustion gas discharge unit

40: combustion gas passing part

Claims (10)

delete delete delete delete In the combustion apparatus having a combustion cylinder for supplying combustion air from the outside to combust the fuel contained therein, and the combustion gas generated by burning the fuel in the combustion cylinder discharges the combustion gas generated by the combustion gas discharge unit to the boiler to recover heat. The combustion gas discharge portion is mounted on the upper portion of the combustion cylinder, the lower portion is in communication with the upper portion of the combustion cylinder, a number of water pipes are built in the body of the combustion gas discharge portion, One end is further in communication with one end of the combustion gas discharge portion, the other end is further provided with a hollow combustion gas passage for communicating the one side of the boiler and the combustion gas flowing from the combustion gas discharge portion to the boiler, the body of the combustion gas passage portion A combustion apparatus, characterized in that a plurality of water pipes are built in. The method of claim 5, And a discharge pipe connecting the water pipe of the combustion gas discharge part and the water pipe of the combustion gas passage part to the boiler so that water circulated in the water pipe of the combustion gas discharge part and the combustion gas passage part flows into the boiler. The method according to claim 5 or 6, The combustion gas passing portion is provided with a combustion device characterized in that the redistribution pipe is formed extending downward in the lower portion so as to discharge the ash contained in the combustion gas passing through the inside. The method of claim 5, The combustion cylinder, A combustion chamber configured to burn fuel by being surrounded by an inner wall in the combustion cylinder; A swirl flow supply chamber formed around an outer side of the inner wall to supply combustion air to the combustion chamber; It is formed around the outer side of the swirl flow supply chamber and comprises an air cooling chamber for supplying the combustion air supplied from the outside to the swirl flow supply chamber, A middle wall having an air supply passage formed at an upper end is formed between the swirl flow supply chamber and the air cooling chamber, and the combustion air flowing into the air cooling chamber moves to an upper portion of the air cooling chamber, and then through the air supply passage at the upper end of the middle wall of the swirl flow supply chamber. And a combustion device which is moved from the upper part to the lower part and is supplied to the combustion chamber through the combustion air supply passage at the lower end of the inner wall. The method of claim 8, The swirl flow supply chamber is provided with a swivel guide wing formed in a spiral shape from the top to the bottom so that the combustion air is guided by the swivel guide wing and is supplied to the combustion chamber while rotating. The method of claim 8, Combustion air upward guide plate which is formed to be inclined upwardly inward is formed at the end of the flange forming the bottom surface of the swirl flow supply chamber so that the combustion air from the swirl flow supply chamber is inclined upwardly into the combustion chamber.

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