KR101754784B1 - Waste incinerator - Google Patents

Abstract

The present invention relates to a waste incineration apparatus capable of increasing the incineration efficiency and reducing the generation of clinker by injecting the incineration process liquid at an appropriate position of the incinerator into which the waste is incinerated. The waste incinerator according to the present invention comprises a primary combustion chamber in which waste is charged and waste is firstly combusted, and a primary combustion chamber connected to the primary combustion chamber for secondary combustion of the primary combustible material generated by combustion of the waste in the primary combustion chamber A nozzle connected to a connection portion of the primary combustion chamber and the secondary combustion chamber; a pump connected to the nozzle so as to pressurize the incineration process solution with the nozzle; and a nozzle connected to the nozzle, And an air compressor connected to the compressor. The nozzle has an injection port for an incineration process for injecting the incineration process liquid between the primary combustion chamber and the secondary combustion chamber and an air injection port for injecting air between the primary combustion chamber and the secondary combustion chamber to form an air curtain.

Description

{WASTE INCINERATOR}

The present invention relates to a waste incineration apparatus, and more particularly, to a waste incineration apparatus capable of reducing the generation of clinker by increasing the incineration efficiency by spraying an incineration process liquid such as sewage sludge condensed sewage water at a high concentration at an appropriate position of an incinerator into which waste is injected and incinerated To a waste incineration apparatus.

Various wastes including wastes have been treated by landfill in the past, but in recent years, they have gradually been changed to incineration due to the difficulty of selecting a landfill.

In the method of incineration of waste, a method of charging wastes into the incinerator and supplying air and burning the waste is mainly used.

If the waste is incinerated, exhaust gas is generated in the combustion process. Exhaust gas contains air pollutants such as dust, hydrogen chloride (HCl), sulfur oxides (SOx), nitrogen oxides (NOx), heavy metals including mercury, or dioxins. These harmful components must be removed for environmental protection.

 These harmful substances pollute the soil as well as the atmosphere and water quality, and also the health of the residents near the incinerator and the safety of pets and trees. Therefore, a device for removing harmful substances from the exhaust gas is installed in the incinerator dedicated to household garbage.

In general incinerators for household garbage, leachate is sprayed with a nozzle to regulate the temperature of the exhaust gas, and nitrogen oxides contained in the exhaust gas are designed to be removed by catalytic reaction by injecting ammonia into a selective catalytic reduction reactor (SCR) .

As an example of such an incineration apparatus, Japanese Patent Registration No. 1056662 (Aug. 12, 2011) discloses incineration plants in which a primary combustion chamber and a secondary combustion chamber are arranged vertically. The incinerator disclosed in the above publication includes an incinerator for incineration of waste, a primary combustion chamber provided at one side of the incinerator for burning heat or flame incinerated in the incinerator in a primary combustion, a primary combustion chamber disposed in the upper portion of the primary combustion chamber, And a secondary combustion chamber which completely burns the primary waste heat again. In the secondary combustion chamber, an injection nozzle for injecting urea water reducing agent as a nitrogen oxide reduction device is installed.

However, when the incineration process liquid (urea water reducing agent or the like) is injected directly into the secondary combustion chamber as in the conventional incineration apparatus described above, clinker is likely to form on the wall surface of the secondary combustion chamber, and such clinker promotes deterioration of the wall surface of the secondary combustion chamber . Therefore, the combustion efficiency in the secondary combustion chamber is lowered and the refractory is detached due to the deterioration of the wall, so that the water tube is likely to be exposed in the secondary combustion chamber.

On the other hand, when the incineration process liquid is injected into the primary combustion chamber, there arises a problem that the waste in the primary combustion chamber becomes wet and the incineration efficiency becomes poor.

Patent Registration No. 1056662 (Aug. 12, 2011)

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned problems of the prior art, and it is an object of the present invention to provide an incineration process solution such as a sewage sludge condensate wastewater of a high concentration which can lower the temperature of combustion gas and reduce the production of nitrogen oxides, And to provide a waste incineration plant capable of reducing the generation of clinker in the secondary combustion chamber and reducing the generation of nitrogen oxides.

In order to achieve the above object, the present invention provides a waste incinerator comprising: a primary combustion chamber in which waste is charged and waste is primarily combusted; A secondary combustion chamber disposed above the primary combustion chamber so as to be connected to the primary combustion chamber for secondary combustion of the primary combustion product generated when the waste is combusted in the primary combustion chamber; An incinerating process liquid jetting port provided at a connecting portion between the primary combustion chamber and the secondary combustion chamber and injecting an incineration process liquid between the primary combustion chamber and the secondary combustion chamber and an air injection port between the primary combustion chamber and the secondary combustion chamber A nozzle having an air ejection port forming an air curtain; A pump connected to the nozzle so as to pressurize the incineration process liquid with the nozzle; And an air compressor connected to the nozzle so as to pressurize the air with the nozzle.

The air injection port of the nozzle may be provided so as to surround the injection port of the incineration process.

The nozzle may include a jetting portion that is exposed to the inside of the incinerator in a bent shape corresponding to an inner surface of the incinerator, and the jetting port and the air jetting port may be respectively disposed in the jetting portion.

The plurality of incineration process liquid ejection openings and the air ejection openings provided in the nozzles may be arranged alternately one by one right and left.

The waste incinerator according to the present invention forms an air curtain in which the incineration process liquid is distributed between the primary combustion chamber and the secondary combustion chamber by injecting the incineration process liquid between the primary combustion chamber and the secondary combustion chamber of the incinerator with nozzles. These air curtains allow the air in the primary combustion chamber to remain in the primary combustion chamber sufficiently to increase the waste combustion efficiency in the primary combustion chamber.

In addition, since the waste incinerator according to the present invention sufficiently mixes with the air while passing through the air curtain in the process of entering the secondary combustion chamber such as the combustion gas generated in the primary combustion chamber, the combustion efficiency of the primary combustion in the secondary combustion chamber . In addition, since the high-temperature combustion gas rising from the primary combustion chamber to the secondary combustion chamber passes uniformly through the air curtain while being evenly mixed with the incineration process liquid, the generation of nitrogen oxides is suppressed and the problem of generating clinker in the secondary combustion chamber is reduced .

In addition, since the waste incinerator according to the present invention ejects the incineration process liquid from the liquid injection opening of the nozzle, and air is injected from the air injection port (secondary air), the air injected from the air injection opening cools the nozzle . Therefore, there is no need for a separate cooling device for cooling the nozzle for spraying the incineration process liquid as in the conventional case.

1 is a schematic view of a waste incineration plant according to an embodiment of the present invention.
2 is a cross-sectional view illustrating a connection between a primary combustion chamber and a secondary combustion chamber of an incinerator of a waste incineration system according to an embodiment of the present invention.
3 is a cross-sectional view illustrating a connection between a primary combustion chamber and a secondary combustion chamber of an incinerator of a waste incineration apparatus according to another embodiment of the present invention.
4 is a cross-sectional view illustrating a connection between a primary combustion chamber and a secondary combustion chamber of an incinerator of a waste incineration system according to another embodiment of the present invention.

Hereinafter, the waste incineration plant according to the present invention will be described in detail with reference to the drawings.

FIG. 1 is a schematic view of a waste incineration plant according to an embodiment of the present invention. FIG. 2 is a cross-sectional view of a waste incinerator according to an embodiment of the present invention, showing a connection between a primary combustion chamber and a secondary combustion chamber of an incinerator, will be.

As shown in FIGS. 1 and 2, the waste incineration apparatus 100 according to an embodiment of the present invention includes an incinerator 110 in which waste is injected into a primary incinerator and a secondary incinerator, A pump 130 for supplying an incineration process liquid to the nozzle 120, and an air supply unit 130 for supplying air to the nozzle 120. The nozzle 120 is provided in the middle of the incinerator 110 to supply air, And a compressor (140). Here, the incineration process liquid may be various liquids that can be injected into the incinerator 110 to lower the temperature of the combustion gas or cause a catalytic reaction in the combustion gas to reduce the production of nitrogen oxides.

The incinerator 110 is for incinerating the waste, and includes a lower primary combustion chamber 111 and an upper secondary combustion chamber 112. The waste is firstly combusted in the primary combustion chamber 111, and the primary combustible material such as combustion gas generated by combustion of the waste in the primary combustion chamber 111 is secondarily combusted in the secondary combustion chamber 111.

The primary combustion chamber 111 is disposed below the incinerator 110 and primarily burns the spent waste. The waste injection unit 113 is connected to one side of the primary combustion chamber 111. Waste can be introduced into the primary combustion chamber 111 through the waste input portion 113. An incinerator discharge portion 114 is connected to the other side of the primary combustion chamber 111. The solid incineration products that have been burned in the primary combustion chamber 111 can be discharged through the incineration water discharge section 114. The bottom surface of the primary combustion chamber 111 is disposed downwardly from the waste input portion 113 toward the incineration water discharge portion 114. A primary combustion air supply zone 115 is provided on the bottom surface side of the primary combustion chamber 111 and air can be supplied to the primary combustion chamber 111 through the primary combustion air supply zone 115.

The secondary combustion chamber 112 is disposed above the primary combustion chamber 111 so as to be connected to the primary combustion chamber 111. The secondary combustion chamber 112 secondary combusts the primary combustible material generated by combustion of the waste in the primary combustion chamber 111. The secondary combustion chamber 112 is provided with an exhaust gas discharge portion 116 for discharging exhaust gas resulting from combustion of waste. The exhaust gas discharge portion 116 may be connected to an exhaust gas filtering device (gas phase and particulate matter removal device) capable of filtering the exhaust gas.

A water pipe for recovering waste heat from the waste combustion heat may be installed on the wall of the incinerator 110 surrounding the primary combustion chamber 111 and the secondary combustion chamber 112. A refractory capable of withstanding high temperatures is disposed on the inner surface of the incinerator 110 to protect the water pipe.

The nozzle 120 is installed in the incinerator 110 and injects the incineration process liquid and air into the incinerator 110. The nozzle 120 is connected to the pump 130 so as to inject the incineration process solution. The pump 130 pumps the incineration process solution to the nozzle 120 through the incineration process solution supply pipe 131. The nozzle 120 is connected to the air compressor 140 so as to inject air. The air compressor 140 pumps air to the nozzle 120 through the air supply pipe 141.

The nozzle 120 is disposed between the primary combustion chamber 111 and the secondary combustion chamber 112 of the incinerator 110, that is, the portion where the primary combustion chamber 111 and the secondary combustion chamber 112 are connected. In the conventional incinerator, the incineration process liquid such as urea water reducer and waste leachate was injected directly into the secondary combustion chamber. In this case, the clinker is likely to be formed on the wall surface of the secondary combustion chamber, the deterioration of the wall surface of the secondary combustion chamber is promoted, the combustion efficiency in the secondary combustion chamber is lowered, and the refractory is detached due to deterioration of the wall and the water tube is exposed to the secondary combustion chamber . The nozzle 120 may be disposed at the connection portion between the primary combustion chamber 111 and the secondary combustion chamber 112 so that the injection region of the incineration process liquid may flow between the primary combustion chamber 111 and the secondary combustion chamber 112 The problem as in the prior art can be solved.

The nozzle 120 has a jetting portion 121 exposed to a connection space between the primary combustion chamber 111 and the secondary combustion chamber 112 inside the incinerator 110. The jetting section 121 is provided with an incinerating process liquid jetting section 122 for jetting the incineration process liquid and an air jetting port 124 for jetting air. The incinerating process liquid injecting section 122 is projected to the inside of the incinerator 110 more than the portion where the air injection port 124 is formed on the injecting section 121 and the incinerating process liquid injecting opening 123 is formed in the incinerating process liquid injecting section 122 Respectively.

The air jet opening 124 is disposed so as to surround the incinerating process liquid jetting section 122. The air injection port 124 injects air around the incineration process liquid injection port 123 so that the incineration process liquid injected from the incineration process liquid injection port 123 is uniformly mixed in the air injected from the air injection port 124, 111) and the secondary combustion chamber (112). Air is supplied into the incinerator 110 through the air injection port 124 of the nozzle 120 so that a secondary combustion air supply zone 117 is formed at the connection between the primary combustion chamber 111 and the secondary combustion chamber 112 . Air can be supplied evenly from the lower side of the secondary combustion chamber 112 to the secondary combustion chamber 112 through the secondary combustion air supply zone 117.

 The air injected through the air injection port 124 forms an air curtain C1 between the primary combustion chamber 111 and the secondary combustion chamber 112. The air curtain (C1) allows the air in the primary combustion chamber (111) to sufficiently stay in the primary combustion chamber (111), thereby improving the combustion efficiency in the primary combustion chamber (111). In addition, primary combustion products such as combustion gases generated in the primary combustion chamber 111 are sufficiently mixed with the air while passing through the air curtain C1, thereby improving the combustion efficiency in the secondary combustion chamber 112. Also, the high-temperature combustion gas rising from the primary combustion chamber 111 to the secondary combustion chamber 112 can be cooled while being mixed with the incineration process liquid while passing through the air curtain C1. Therefore, the generation of nitrogen oxides in the secondary combustion chamber 112 is suppressed, and the problem of generating clinker in the secondary combustion chamber 112 is reduced.

In the waste cautery apparatus 100 according to the present invention, the secondary air injected through the air injection port 124 cools the incinerating process liquid spraying unit 122. Therefore, there is no need for a separate cooling device for cooling the nozzle for spraying the incineration process liquid as in the conventional case.

Hereinafter, the operation of the waste incineration apparatus 100 according to an embodiment of the present invention will be described.

Air is supplied to the primary combustion chamber 111 through the primary combustion air supply zone 115 when the waste is introduced into the primary combustion chamber 111 of the incinerator 110 through the waste input portion 113, The waste is firstly combusted in the combustion chamber 111. The waste material is burnt and the remaining combustible material is transferred to the incineration water discharge part 114 on one side of the primary combustion chamber 111 and discharged through the incineration water discharge part 114. In addition, the high-temperature primary combustible material such as the combustion gas generated by combustion of the waste in the primary combustion chamber 111 rises toward the secondary combustion chamber 112.

On the other hand, when the waste is firstly combusted in the primary combustion chamber 111, the incineration process liquid and air are injected between the primary combustion chamber 111 and the secondary combustion chamber 112 through the nozzle 120, An air curtain C1 containing an incineration process liquid is formed between the secondary combustion chamber 111 and the secondary combustion chamber 112. [ The air curtain C1 allows the air to be supplied to the primary combustion chamber 111 from the primary combustion air supply zone 115 to sufficiently stay in the primary combustion chamber 111 to improve the waste combustion efficiency in the primary combustion chamber 111 Increase.

The primary combustible material generated in the primary combustion chamber 111 flows into the secondary combustion chamber 112 through the air curtain C1. The combustion efficiency of the secondary combustion chamber 112 is improved by flowing the primary combustible material into the secondary combustion chamber 112 while being mixed with air while passing through the air curtain C1. Also, the high-temperature combustion gas rising from the primary combustion chamber 111 to the secondary combustion chamber 112 can be evenly cooled while being mixed with the incineration process liquid while passing through the air curtain C1. Thus, the generation of nitrogen oxides in the secondary combustion chamber 112 is suppressed and the problem of generating clinker is reduced.

The exhaust gas remaining after the primary combustion in the secondary combustion chamber 112 is burned secondarily is discharged through the exhaust gas discharge portion 116 on one side of the secondary combustion chamber 112.

3 is a cross-sectional view illustrating a connection between a primary combustion chamber and a secondary combustion chamber of an incinerator of a waste incinerator according to another embodiment of the present invention.

The waste incinerating apparatus 200 shown in FIG. 3 is a modification of the structure of the nozzle 210 as compared with the waste incineration apparatus 100 described above.

The nozzle 210 shown in FIG. 3 is connected to the pump 130 (see FIG. 1) through the incineration process liquid supply pipe 131 and to the air compressor 140 (see FIG. 1) through the air supply pipe 141. The nozzle 210 has a jetting portion 211 exposed to the inside of the incinerator 110. The jetting section (211) is formed in a bent shape corresponding to the inner surface of the incinerator (110). The jetting section (211) is provided with a plurality of incineration process liquid jetting ports (212) for jetting the incineration process liquid and a plurality of air jetting ports (213) for jetting air. When a plurality of incineration process liquid ejection openings 212 and a plurality of air ejection openings 213 are disposed in the bent portion 211 corresponding to the inner surface of the incinerator 110 as described above, And the angle of ejection of the air ejection openings 213 can be varied. Therefore, the incineration process liquid and air can be more uniformly injected into the space between the primary combustion chamber 111 and the secondary combustion chamber 112, and a more uniform air curtain C2 can be formed.

As shown in the drawing, the incineration process liquid ejection port 212 and the air ejection port 213 are alternately disposed one on the left and one on the right. When the incineration process liquid injection port 212 and the air injection port 213 are alternately arranged, the incineration process liquid injected from the incineration process liquid injection port 212 can be evenly mixed in the air injected from the air injection port 213, It is possible to more evenly distribute the incineration process liquid in the air curtain C2 formed by injection. Of course, the number of the incineration process liquid ejection openings 212, the number of the air ejection openings 213, and the arrangement structure may be variously changed on the ejection section 211.

4 is a cross-sectional view illustrating a connection between a primary combustion chamber and a secondary combustion chamber of an incinerator of a waste incineration apparatus according to another embodiment of the present invention.

The waste incinerator 300 shown in Fig. 4 has a nozzle 310 of another structure.

The nozzle 310 shown in FIG. 4 is connected to the pump 130 (see FIG. 1) through the incineration process liquid supply pipe 131 and to the air compressor 140 (see FIG. 1) through the air supply pipe 141. The nozzle 310 has a jetting section 311 exposed to the inside of the incinerator 110. The jetting section 311 is formed in a bent shape corresponding to the inner surface of the incinerator 110. The jetting section 311 is provided with an incinerating process liquid jetting section 312 for jetting the incineration process liquid and an air jetting port 314 for jetting air. The incinerating process liquid spraying section 312 protrudes inside the incinerator 110 more than the portion where the air jetting port 314 is formed on the jetting section 311 and the incinerating process liquid jetting port 313 is formed in the incinerating process liquid jetting section 312 Respectively. By disposing the incineration process liquid ejection port 313 and the air ejection port 314 in the bent portion 311 corresponding to the inner surface of the incinerator 110 as described above, the ejection angle of the incineration process liquid ejection ports 313 It is possible to vary the injection angle of the air ejection holes 314. Therefore, the incineration process liquid and air can be more uniformly injected into the space between the primary combustion chamber 111 and the secondary combustion chamber 112, and a more uniform air curtain C3 can be formed.

As shown in the drawing, the air injection ports 314 are arranged so as to surround the incineration process liquid injection portion 312 so that the air injection port 314 injects air around the plurality of incineration process liquid injection ports 313, The incineration process liquid injected from the process liquid injection ports 313 can be evenly mixed in the air injected from the air injection holes 314 and spread evenly in the space between the primary combustion chamber 111 and the secondary combustion chamber 112. Of course, the number of the incineration process liquid ejection openings 313 and the number of the air ejection openings 314, and the arrangement structure may be variously changed on the ejection section 311.

Although the preferred embodiments of the present invention have been described above, the scope of the present invention is not limited to those described and illustrated above.

For example, although one nozzle is disposed between the primary combustion chamber 111 and the secondary combustion chamber 112 of the incinerator 110, the primary combustion chamber 111 and the secondary combustion chamber 112 are shown in the figure, The number of nozzles provided in the connection portion between the nozzle and the nozzle may be variously changed.

Also, the number of process liquid ejection openings and air ejection openings provided in the nozzle is not limited to the illustrated one, and may be changed to one or more various numbers.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. Those skilled in the art will appreciate that numerous modifications and variations can be made in the present invention without departing from the spirit and scope of the appended claims.

100, 200, 300: waste incinerator 110: incinerator
111: primary combustion chamber 112: secondary combustion chamber
113: Waste input part 114: Incineration water discharge part
115: Primary combustion air supply zone 116: Exhaust gas outlet
117: secondary combustion air supply zone 120, 210, 310: nozzle
121, 211, 311: jetting section 122, 312: incinerating process liquid jetting section
123, 212, 313: Incinerating process liquid jetting port 124, 213, 314: Air jetting port
130: Pump 131: Incineration process liquid supply pipe
140: air compressor 141: air supply pipe
C1, C2, C3: Air curtain

Claims (4)

A primary combustion chamber in which waste is charged and the waste is primarily combusted;
A secondary combustion chamber disposed above the primary combustion chamber so as to be connected to the primary combustion chamber for secondary combustion of the primary combustion product generated when the waste is combusted in the primary combustion chamber;
An incinerating process liquid jetting port provided at a connecting portion between the primary combustion chamber and the secondary combustion chamber and injecting an incineration process liquid between the primary combustion chamber and the secondary combustion chamber and an air injection port between the primary combustion chamber and the secondary combustion chamber A nozzle having an air ejection port forming an air curtain;
A pump connected to the nozzle so that the incineration process liquid can be sent to the nozzle; And
And an air compressor connected to the nozzle so as to pressurize the air with the nozzle,
Wherein the air injection port of the nozzle is provided so as to surround the injection port of the incineration process so that the injection port of the incineration process is cooled,
The formed air curtain is mixed with air while passing through the primary combustible gas containing the combustion gas generated in the primary combustion chamber to increase the combustion efficiency in the secondary combustion chamber and increase the combustion efficiency of the high- Wherein the combustion gas is uniformly mixed with the incineration process liquid while passing through the incinerator.
delete A primary combustion chamber in which waste is charged and the waste is primarily combusted;
A secondary combustion chamber disposed above the primary combustion chamber so as to be connected to the primary combustion chamber for secondary combustion of the primary combustion product generated when the waste is combusted in the primary combustion chamber;
An incinerating process liquid jetting port provided at a connecting portion between the primary combustion chamber and the secondary combustion chamber and injecting an incineration process liquid between the primary combustion chamber and the secondary combustion chamber and an air injection port between the primary combustion chamber and the secondary combustion chamber A nozzle having an air ejection port forming an air curtain;
A pump connected to the nozzle so that the incineration process liquid can be sent to the nozzle; And
And an air compressor connected to the nozzle so as to pressurize the air with the nozzle,
Wherein the nozzle has a jetting portion that is exposed to the inside of the incinerator in a bent shape corresponding to an inner surface of the incinerator, and the jetting portion is provided with a jetting port Respectively,
The formed air curtain is mixed with air while passing through the primary combustible gas containing the combustion gas generated in the primary combustion chamber to increase the combustion efficiency in the secondary combustion chamber and increase the combustion efficiency of the high- Wherein the combustion gas is uniformly mixed with the incineration process liquid while passing through the incinerator.
The method of claim 3,
Wherein a plurality of burning process liquid ejection openings and a plurality of air ejecting openings provided in the nozzle are arranged alternately one on the left and one on the right.

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