KR20110027896A - Combustion apparatus with improved heat efficiency - Google Patents

Abstract

PURPOSE: A combustion apparatus with improved thermal efficiency is provided to improve durability by lowering the temperature of the inner wall of a combustion chamber exposed to high-temperature combustion gas. CONSTITUTION: A combustion apparatus with improved thermal efficiency comprises a combustion chamber(11), a cooling chamber(13), and a side combustion air supply chamber(15). The combustion chamber is covered with an inner wall(12) in a combustion container(100). The middle wall(14) of the cooling chamber has a cooling water outlet and a cooling water inlet. Cooling water, flowing into a gap between the inner wall and the middle wall, cools the inner wall of the combustion chamber. A combustion air supply hole(16a) is formed in a tangential direction of an outer wall(16) of the side combustion air supply chamber. Combustion air, flowing from the combustion air supply hole, is supplied to the combustion chamber.

Description

Combustion device with improved thermal efficiency {COMBUSTION APPARATUS WITH IMPROVED HEAT EFFICIENCY}

The present invention relates to a heat recovery combustion apparatus, and more particularly, to a heat recovery combustion apparatus 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, combustion air is supplied only to the outside of the solid fuel loaded in the combustion chamber, so that the outer portion of the solid fuel is well burned, but the solid fuel therein is difficult to contact with the combustion air, resulting in incomplete combustion. There was this. In addition, since the inner wall of the combustion chamber is continuously exposed to high temperature combustion gas, deformation or cracking occurs during long-term use, resulting in a decrease in durability.

The present invention has been made to solve the problems of the prior art to achieve the complete combustion of the solid fuel loaded in the combustion chamber and to reduce the heat loss to improve the thermal efficiency and to increase the temperature of the combustion chamber inner wall continuously exposed to high temperature combustion gas It is an object to provide a combustion apparatus which improves durability by lowering.

In the combustion apparatus of the present invention, a combustion apparatus including a combustion cylinder receiving combustion air from the outside and combusting the fuel supplied by the fuel supply unit, the combustion apparatus comprising: a cylindrical combustion chamber configured to burn fuel by being surrounded by an inner wall in the combustion cylinder; The inner wall of the combustion chamber is formed to be spaced apart from each other, and the upper and lower sides of the inner wall are provided with a coolant outlet and a coolant inlet formed therein to cool the inner wall. The outer wall is provided with a cooling chamber formed on the outer circumference of the combustion chamber and an outer wall formed on the outer side of the middle wall of the cooling chamber and a combustion air supply port through which the combustion air is supplied from the outside. Combustion air supplied through the combustion air supply port formed as After falling while turning the space so that the combustion air supplied into the combustion chamber with an open bottom characterized in that comprises the side combustion air supply chamber formed on the outer circumference of the compartment.

In addition, the present invention includes a boiler having a water pipe for supplying the combustion gas generated by burning the fuel in the combustion chamber to recover heat from the combustion gas, the cooling water flowing out from the cooling water outlet of the cooling chamber is the combustion It is characterized in that it is connected to the water pipe of the boiler through a connecting pipe to be used for recovering heat from the combustion gas generated by the device.

In addition, the present invention preferably the connection pipe is made of a first and second connection pipe, the boiler water tank is provided between the first and second connection pipe, the coolant flowing out from the cooling water outlet of the cooling chamber of the boiler water tank It is introduced into the water pipe of the boiler via.

In addition, the combustion apparatus of the present invention is provided with a spiral cooling water guide plate so that the cooling water flowing from the cooling water inlet in the cooling chamber is raised while turning.

In addition, the combustion apparatus of the present invention has a lower combustion air supply pipe which is formed in a concentric shape with a diameter larger than that of the fuel supply pipe to which the fuel is supplied to the fuel supply pipe is provided in the combustion chamber through the air supply means It is characterized by supplying combustion air to the bottom of the fuel.

In addition, the present invention includes an enlarged diameter portion protruding into the combustion chamber from the fuel supply pipe is gradually increased in diameter toward the upper side, and the inclined guide portion is bent downward from the end of the enlarged diameter portion to be inclined downward.

In addition, the present invention preferably has an upper end portion protruding into the combustion chamber from the lower combustion air supply pipe is provided with an air supply enlargement portion that gradually increases in diameter toward the upper side is located below the enlarged portion of the fuel supply pipe, the enlarged portion of the fuel supply pipe There are a plurality of air supply nozzles are formed in the combustion air supplied from the lower combustion air supply pipe into the combustion chamber.

In addition, in the combustion apparatus of the present invention, the upper end of the air supply expansion portion of the lower combustion air supply pipe is preferably closed by the inclined guide portion of the fuel supply pipe.

In addition, the combustion apparatus of the present invention further comprises an upper combustion air supply chamber for supplying combustion air to the upper portion of the combustion chamber, the upper combustion air supply chamber is formed spaced apart from the outer side of the upper inner wall surrounding the upper inner side of the combustion chamber A swirl flow supply chamber for supplying combustion air to an upper portion of the combustion chamber with an upper middle wall having an air passage formed at an upper end thereof, and an upper air supply spaced apart from the outside of the upper middle wall and supplied with combustion air from the outside to the lower portion; The preheating chamber includes combustion preheating chamber introduced into the preheating chamber through an upper air supply port of the upper outer wall, including a preheating chamber formed on an outer circumference of the swirl flow supply chamber having a cylindrical upper outer wall formed in a tangential direction. After moving upwardly by turning upward, it moves from the upper part to the lower part of the swirl flow supply chamber through the air passage at the upper part of the upper middle wall. Through the combustion air supply passage formed in the lower end of the upper wall is supplied to the combustion chamber.

In addition, the combustion apparatus of the present invention is provided with a rotatable rotatable grate is supplied to the upper surface of the fuel supplied through the fuel supply pipe in the bottom of the combustion chamber, both sides of the rotatable grate is preferably formed in a V-shape. Do.

According to the present invention, a combustion apparatus which improves thermal efficiency and improves durability by achieving complete combustion of fuel loaded in a combustion chamber and reducing heat loss to the outside.

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

Figure 2 is a longitudinal cross-sectional view of the combustion apparatus according to an embodiment of the present invention, Figure 3 is a view showing one side cross section of the combustion cylinder, Figure 4 is a process of cooling water flowing out of the cooling chamber of the combustion cylinder flows into the boiler. 5 is a view showing a cross section of the fuel supply unit.

Combustion apparatus according to a preferred embodiment of the present invention is provided with a combustion cylinder 100 to burn fuel therein to generate a high temperature combustion gas and a combustion apparatus for recovering heat using the high temperature combustion gas using a boiler or the like. to be.

First, the combustion cylinder 100 is formed in a cylindrical shape for accommodating and burning solid fuel therein. The combustion chamber 11 and the combustion chamber 11, which are surrounded by an inner wall 12 in the combustion cylinder 100 to combust fuel, It comprises a cooling chamber 13 for cooling the inner wall (12) and the side combustion air supply chamber 15 formed on the side of the combustion chamber 11 for supplying combustion air from the outside to the combustion chamber (11).

The cooling chamber 13 is for lowering the temperature of the inner wall 12 which is in continuous contact with the hot combustion gas, and is spaced apart from the inner wall 12 of the cylinder whose inner diameter is narrowed upward as shown in FIG. 3. Cooling water outlets 14b and cooling water inlets 14a are formed in the space between the formed middle wall 14 and the inner wall 12, and the coolant flows in and out of the middle wall 14. Cooling water inlet 14a is formed in the tangential direction of the cylindrical middle wall (14). And, inside the middle wall 14 of the cooling chamber 13 is provided with a cooling water guide plate (13a) is formed spirally wound as shown in Figure 3, the cooling water introduced through the cooling water inlet 14a, the cooling water guide plate As it rotates along 13a, it rises and flows out through the coolant outlet 14b formed above the middle wall 14. As shown in FIG. The coolant flowing out through the coolant outlet 14b is passed to the boiler 60 for use to recover heat from the hot combustion gas generated in the combustion chamber 11 through the connecting pipes 62 and 63 as shown in FIG. Inflow. In the present embodiment, the first feed pipe 62 is introduced into the boiler feed tank 61 and then flows into the water pipe 60a of the boiler 60 through the second connect pipe 63.

The side combustion air supply chamber 15 is formed in a space between the outer wall 16 and the middle wall 14 spaced apart from the middle wall 14 and air for supplying combustion air from the outside to the upper side of the outer wall 16. The supply port 16a is formed and the lower part 12a is open. The air supply port 16a is formed in the tangential direction of the cylindrical outer wall 16 so that the supplied combustion air descends inside the side combustion air supply chamber 15 and then into the combustion chamber 11 through the opened lower portion 12a. Will be supplied.

In addition, an upper combustion air supply chamber 20 for supplying combustion air from the upper side is formed around the upper portion of the combustion chamber 11. The upper combustion air supply chamber 20 is coupled to the upper side of the cooling chamber 13 and the side combustion air supply chamber 15 by the flange 18, and the upper inner wall 22 of the cylinder surrounding the upper inner side of the combustion chamber 11. A swirl flow supply chamber 23 formed at an outer periphery and supplying combustion air to an upper inside of the combustion chamber 11, and combustion air supplied from the outside around the swirl flow supply chamber 23 and supplied from the outside; 23 is a preheating chamber 25 for supplying.

The swirl flow supply chamber 23 is formed in a space between the upper middle wall 24 and the upper inner wall 22 which are formed to be spaced apart from the upper inner wall 22, and the preheating chamber 25 is formed of the upper middle wall 24. It is formed in the space between the upper outer wall 26 and the upper middle wall 24 which are formed spaced apart from the outside. An upper air supply port 26a is formed in a tangential direction of the upper outer wall 26 so that the lower side of the upper outer wall 26 is supplied to the preheating chamber 25 while turning combustion air from the outside. An air passage 24a is formed at the upper end, and the combustion air flowing into the preheating chamber 25 turns upwardly to the upper portion of the preheating chamber 25, and then the swirling flow through the air passage 24a at the top of the upper middle wall 24. Combustion air is supplied from the upper part of the supply chamber 23 to the upper part of the combustion chamber 11 through the combustion air supply passage 22a formed in the lower end of the upper inner wall 22.

The upper part of the combustion cylinder 100 is open to discharge the hot combustion gas burned, and the discharged hot combustion gas flows into the boiler 60 through a combustion gas discharge pipe (not shown) to recover heat. do. The boiler 60 recovers heat from the introduced high temperature combustion gas and obtains high temperature steam. At this time, the coolant introduced from the coolant outlet 14b flows into the boiler 60 through the boiler feed tank 61. It is converted to steam or the like by using the heat of the combustion gas.

On the other hand, on the lower edge of the combustion cylinder 100, the redistribution port 19 is formed so that the ash of the solid fuel burned can be discharged.

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 in the shape of a disc, and is inclined upward again after being inclined downward from the center to form a V-shape. In the center of the rotary grate 17, a fuel supply unit 40 for supplying solid fuel is formed.

The fuel supply unit 40 has a fuel supply port 44 formed at one lower side thereof, and is provided with a fuel supply pipe 41 for supplying solid fuel into the combustion chamber 11 by a vertical transfer screw (not shown). The outer side of the supply pipe 41 has a larger diameter than the fuel supply pipe 41 and is formed concentrically and for supplying combustion air from the lower part of the combustion chamber 11 to the combustion chamber 11 by air supply means 45 such as a ring blower. Lower combustion air supply pipe 43 is formed.

An inclined guide portion 41b which is bent downward at an end of the enlarged diameter portion 41a and the enlarged diameter portion 41a, the upper end portion protruding into the combustion chamber 11 from the fuel supply pipe 41 gradually increasing upward. ) Is formed. In addition, a plurality of air supply nozzles 41c into which the combustion air supplied from the lower combustion air supply pipe 43 flows are formed in the enlarged diameter portion 41a in the circumferential direction.

In addition, the upper end portion protruding into the combustion chamber 11 from the lower combustion air supply pipe 43 is provided with an air supply expansion portion 43a, the diameter of which gradually increases toward the upper side, and is located below the expansion portion 41a of the fuel supply pipe 41. The upper end of the air supply expanding portion 43a is closed by the inclined guide portion 41b of the fuel supply pipe 41. Therefore, the combustion air supplied through the lower combustion air supply pipe 43 is guided by the air supply expanding portion 43a to supply fuel through the air supply nozzle 41c formed in the expanding portion 41a of the fuel supply pipe 41 formed on the upper side. It will be fed to the bottom of.

On the other hand, although not shown in the figure, the fuel to supply the combustion air through the fuel supply pipe 41 to prevent backfire from the solid fuel burned in the combustion chamber 11 to the solid fuel existing in the fuel supply pipe 41. The other side of the lower portion of the supply pipe 41 may be provided with an air supply means such as a ring blower.

With the above configuration, the solid fuel is supplied to the center of the upper surface of the rotary grate 17 by the fuel supply pipe 41, and the air supply nozzle supply nozzle 41c formed in the enlarged portion 41a of the fuel supply pipe 41 is opened. Combustion air is supplied directly to the bottom of the solid fuel.

Hereinafter will be described a method of operating a combustion apparatus according to an embodiment of the present invention configured as described above.

First, the solid fuel is continuously supplied from the fuel hopper (not shown) into the combustion chamber 11 through the fuel supply pipe 41 and the solid fuel supplied into the combustion chamber 11 is supplied to the preheat burner and the ignition burner (not shown). Preheating and ignition cause combustion. Then, the solid fuel supplied to the upper side of the rotary grate 17 is combusted and moves to the edge of the rotary grate 17 over time due to the continuous supply of fuel. The changed fuel is burned while staying at the V-shaped bone, the cross section of the grate. As a result, when the cross section of the grate is inclined to one side, the problem that the liquid fuel generated during the combustion flows down to one side is solved. At the edge of the rotary grate 17, the ash produced by burning the fuel is discharged through the redistribution outlet 19 while the rotary grate 17 rotates.

Meanwhile, while the solid fuel is combusted in the combustion chamber 11, the coolant is introduced through the coolant inlet 14a of the cooling chamber 13 formed around the inner wall 12 and the coolant guide plate 13a is introduced. The inner wall 12 is cooled while being rotated up by), and then flows out through the cooling water outlet 14b. Then, the cooling water discharged from the cooling chamber 13 is stored in the boiler feed tank 61 through the connecting pipe 62 and then flows into the boiler 60 to recover heat from the hot combustion gas by heat exchange. Thus, the present invention is provided with a cooling chamber 13 on the outer circumference of the inner wall 12 to prevent the degradation of durability due to excessive temperature rise of the inner wall 12 of the combustion chamber 11 and at the same time by heat exchange with the inner wall 12 Deformation caused by continuous exposure of the inner wall 12 of the combustion chamber 11 to the hot combustion gas by recovering heat from the hot combustion gas generated by the combustion apparatus after the coolant is preheated again and then flowed back into the boiler 60. In addition, the thermal efficiency is improved by preventing unnecessary heat loss while preventing durability degradation due to deterioration or cracking.

And, the combustion air required to burn the solid fuel is supplied to the combustion chamber 11 through the side combustion air supply chamber 15, the upper combustion air supply chamber 20 and the lower combustion air supply pipe 43 from the outside, first, the side combustion In the air supply chamber 15, the lower part 12a opened after the combustion air supplied through the air supply port 16a tangentially formed on the upper portion of the circular outer wall 16 is turned down inside the side combustion air supply chamber 15. It is supplied into the combustion chamber 11 through. Therefore, the combustion air is supplied from the side combustion air supply chamber 15 while the combustion air is rotated on the side of the combustion chamber 11, so that even though the combustion chamber 11 is small, the combustion air is supplied to most of the fuel even though the combustion chamber 11 is small. Direct contact improves thermal efficiency while lowering manufacturing costs.

In the upper combustion air supply chamber 20, the combustion air supplied to the preheating chamber 25 and supplied to the preheating chamber 25 through the upper air supply port 26a formed in a tangential direction on the circular upper outer wall 26. The upper portion of the preheating chamber 25 is supplied to the swirl flow supply chamber 23 through the air passage 24a of the upper middle wall 24. The combustion air supplied to the swirl flow supply chamber 23 moves from the upper side to the lower side and then rotates inward from the upper side of the combustion chamber 11 through the combustion air supply passage 22a formed in the upper inner wall 22. Therefore, the external air is moved from the upper combustion air supply chamber 20 to the upper portion of the preheating chamber 25 and then moved to the lower portion of the swirl flow supply chamber 23 so that the moving distance is longer, so that the preheating of the swirl flow supply chamber 23 is more reliable. At the same time, the preheating chamber 25 can also perform a heat-blocking function from the swirl flow supply chamber 13 to the outside. In addition, the combustion air supplied by the side combustion air supply chamber 15 directly burns the solid fuel loaded on the grate 17, and the combustion air supplied by the upper combustion air supply chamber 20 does not completely burn and rises. It plays a role of combusting incomplete combustion product to achieve complete combustion of fuel.

Next, the combustion air is injected by the lower combustion air supply pipe 43, and the combustion air supplied by the lower combustion air supply pipe 43 formed on the outside of the fuel supply pipe 41 is formed in the fuel supply pipe 41. Solid fuel existing in the lower part and the interior as well as the outside of the solid fuel loaded by supplying combustion air to the lower part of the solid fuel supplied through the air supply nozzle 41c formed in the enlarged diameter part 41a and loaded in the combustion chamber 11. It also burns smoothly, improving thermal efficiency.

Meanwhile, the high temperature combustion gas generated by burning the solid fuel in the combustion chamber 11 is introduced into the boiler 60 through the open upper portion of the combustion chamber 11, and the high temperature combustion gas supplied to the boiler 60 is heat exchanged. It is used to generate industrial hot water or steam by.

As described above, the combustion device as a preferred embodiment of the present invention has been described with reference to an example using solid fuel, but the combustion device of the present invention is not limited to solid fuel, and it is natural that the combustion device is applicable to gas fuel and liquid fuel. Those skilled in the art will readily appreciate that various modifications may be made 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 an embodiment of the present invention,

Figure 3 is a view showing one side cross section of the combustion cylinder,

4 is a view illustrating a process in which the leaked coolant flows into a boiler;

5 is a cross-sectional view showing a fuel supply unit.

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

100: combustion cylinder

11: combustion chamber 12: inner wall

13: cooling chamber 14: middle wall

15: side combustion air supply room 16: outer wall

17: rotary type grate 20: upper combustion air supply room

40: fuel supply unit 41: fuel supply pipe

43: lower combustion air supply pipe

Claims (10)

A combustion apparatus comprising a combustion cylinder that receives combustion air from outside and combusts fuel supplied by a fuel supply unit, A cylindrical combustion chamber configured to burn fuel by being surrounded by an inner wall in the combustion cylinder; The inner wall of the combustion chamber is formed to be spaced apart from the inner wall, and the upper and lower sides of the inner wall are provided with a coolant inlet and a coolant inlet and a coolant inlet, respectively. A cooling chamber formed outside the circumference of the combustion chamber to cool; Combustion air supplied through the combustion air supply port formed in the tangential direction of the cylindrical outer wall is provided with an outer wall formed to be spaced apart from the outside of the middle wall of the cooling chamber and a combustion air supply port through which the combustion air is supplied from the outside. And a side combustion air supply chamber formed outside the circumference of the cooling chamber so that combustion air is supplied into the combustion chamber to the open lower portion after descending while turning the space between the middle wall and the outer wall. The method of claim 1, A boiler having a water pipe for supplying combustion gas generated by burning fuel in the combustion chamber to recover heat from the combustion gas, And a cooling water flowing from the cooling water outlet of the cooling chamber is connected to the water pipe of the boiler through a connecting pipe so as to be used to recover heat from the combustion gas generated by the combustion cylinder. The method of claim 2, The connecting pipe is composed of first and second connecting pipes, and a boiler water supply tank is provided between the first and second connection pipes so that the coolant flowing out of the cooling water outlet of the cooling chamber flows into the water pipe of the boiler via the boiler water supply tank. Combustion device with improved thermal efficiency. The method of claim 3, And a spiral cooling water guide plate is provided in the cooling chamber so that the cooling water introduced from the cooling water inlet rises while turning. The method according to any one of claims 1 to 4, The fuel supply unit installed at the lower portion of the combustion cylinder has a lower combustion air supply pipe having a diameter larger than that of the fuel supply pipe to which fuel is supplied and is formed concentrically to supply combustion air from the lower part of the combustion chamber to the bottom of the fuel through an air supply means. Combustion device with improved thermal efficiency. The method of claim 5, And an upper end portion protruding into the combustion chamber from the fuel supply pipe, the enlarged diameter portion gradually increasing toward an upper side, and an inclined guide portion bent downward from an end portion of the enlarged diameter portion to be inclined downward. The method of claim 6, The upper end portion protruding into the combustion chamber from the lower combustion air supply pipe is provided with an air supply enlargement portion which gradually increases in diameter toward the upper side, and is located below the enlarged portion of the fuel supply pipe. And a plurality of air supply nozzles are formed in the enlarged portion of the fuel supply pipe so that combustion air supplied from the lower combustion air supply pipe is introduced into the combustion chamber. The method of claim 7, wherein The upper end of the air supply expansion portion of the lower combustion air supply pipe combustion apparatus is improved thermal efficiency is closed by the inclined guide of the fuel supply pipe. The method of claim 8, It is formed around the upper portion of the combustion chamber further comprises an upper combustion air supply chamber for supplying combustion air to the upper portion of the combustion chamber, wherein the upper combustion air supply chamber A swirl flow supply chamber having an upper middle wall spaced apart from an upper inner wall surrounding an upper inner side of the combustion chamber and having an air passage formed at an upper end thereof to supply combustion air to the upper portion of the combustion chamber; And a preheating chamber formed at an outer circumference of the swirl flow supply chamber, the upper air supply port being spaced apart and having an upper air supply port through which the combustion air is supplied from the outside in a tangential direction. The combustion air introduced into the preheating chamber through the upper air supply port of the upper outer wall moves upwardly to the upper part of the preheating chamber, and then moves from the upper portion of the swirling flow supply chamber to the lower portion through the air passage at the upper end of the upper middle wall. A combustion device with improved thermal efficiency, characterized in that it is supplied to the combustion chamber through the combustion air supply passage formed on the bottom of the inner wall. 10. The method of claim 9, The bottom of the combustion chamber is provided with a rotatable rotatable grate for supplying the fuel supplied through the fuel supply pipe to the upper surface, both sides of the rotatable grate is formed in a V-shaped combustion efficiency improved combustion apparatus.

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