KR101806297B1 - Incinerator for low nox combustion - Google Patents

Abstract

The present invention relates to a garbage incinerating device for reducing nitrogen oxide. The present invention provides a garbage incinerating device for reducing nitrogen oxide, capable of remarkably reducing a generation rate of nitrogen oxide (NOx) which is a pollutant while completely combusting wastes during a waste incinerating process. The garbage incinerating device for reducing nitrogen oxide includes: a waste insertion unit inserting waste; a solid body combustion unit including a stairs type combustion plate combusting the waste inserted during a moving process of the inserted waste; a gas induction heating and partial combustion section separated from the solid body combustion unit to induce heating circulation for preheating organic gas generated during a combustion process of the inserted waste; a gas combustor heating or combusting the organic gas during a circulation induction process in the purpose of preheating; a gas heating unit including an air mixer mixing the combustion air during the circulation induction process; and a gas discharge unit discharging mixed combustion gas in which the heated gas and the combustion air are mixed during the circulation induction process.

Description

{INCINERATOR FOR LOW NOX COMBUSTION}

The present invention relates to a waste incineration technology for reducing rust, and more particularly, to a waste incineration technology for waste incineration which is capable of completely burning waste in the incineration process of garbage and reducing the amount of generated knock (nitrogen oxides, NOx) And an incinerator.

Many pollutants are contained in the combustion gas generated in the process of incineration of waste discharged from urban life, factories and enterprises. Dioxin- (HCl) -PCDDs and dibenzofuran-PCBs, carbon monoxide-CO, nitrogen oxides- (NOx), sulfur oxides- (SOx) and odors are representative pollutants. As described above, the conventional incineration technology of waste incites environmental pollution due to the emission of pollutants generated in incineration of waste. Accordingly, there is a continuing need to develop incineration technology capable of reducing pollutant emissions.

The prior art uses a combustion method in which waste is burned to reduce the volume of waste, and the waste is reduced and deformed into a re-state. For this purpose, the garbage is injected through a single inlet, and a large amount of waste is injected into the front of the incinerator combustion chamber, and the waste is dried and preheated by using the radiant heat inside. Such a combustion method evaporates a lot of water according to the drying of the inside and causes moisture to be combined with the combustion flame and the exhaust gas to obstruct the complete combustion. As a result, harmful toxicity such as dioxins, NOx, SOx, CO and HCl Gas is generated and dust emission is generated in a large amount. Further, when the concentration of oxygen is high in the combustion process, there is a problem that the amount of NOx generated increases. Accordingly, there is a demand for development of an environmentally friendly incineration technology capable of reducing the internal oxygen concentration to reduce the amount of the knock generated.

Korean Patent Laid-Open Publication No. 10-1998-0074713 (1998.11.05) relates to a pyrolytic cylindrical incineration apparatus for pyrolysis combined with a multistage cyclone combustion system, comprising a pyrolysis chamber (24) for pyrolyzing waste, a pyrolysis chamber A primary combustion chamber 25 for combusting gas, residual carbon, and unburned fuel generated in the combustion chamber 24; A secondary combustion chamber (40) for completely burning the unburned gas that has not been combusted in the primary combustion chamber (25); A cyclone 60 for treating the dust in the exhaust gas, and an ejector 65 connected to the outlet of the cyclone for preventing backfire and for introducing the combustion gas.

Korean Patent Registration No. 10-0874986 (Dec. 12, 2008) discloses a combustion furnace in which the inner wall is formed of a refractory material, a grate for forming a solid fuel is provided at one end, and an exhaust port for discharging a combustion gas is formed at the opposite side. A plurality of injection devices installed in each of the grate of the combustion furnace formed to inject solid fuel remaining in each stage into the next stage, and a plurality of injection devices which are formed by projecting toward the center from the ceiling side of the combustion furnace at the end where the grate A partition wall made of a refractory for dividing the inside of the combustion chamber into a primary combustion chamber and a secondary combustion chamber; a cooling water pipe arranged in a state of being arranged close to the inner wall of the combustion furnace; There is provided an incinerator heat recovery type combustion apparatus including a plurality of air outlets for ejecting compressed air.

1. Korean Published Patent Application No. 10-1998-0074713 (1998.11.05) 2. Korean Patent No. 10-0874986 (Dec. 12, 2008)

One embodiment of the present invention provides a rust reducing incineration apparatus capable of remarkably reducing the amount of generated knots (nitrogen oxides, NOx) as pollutants while completely burning the garbage in the process of incinerating the rubbish.

An embodiment of the present invention provides a burning incineration apparatus for reducing rust which can circulate a gas generated in a process of burning a waste, thereby completely combusting, burning, and pyrolyzing a large amount of combustible materials and contaminants contained in the gas.

An embodiment of the present invention provides a knock reduction incineration apparatus capable of reducing the occurrence of knocks by controlling and maintaining the concentration of oxygen contained in the gas subjected to combustion and the temperature (850 ° C) of the knock generation reduction condition do.

Among the embodiments, the knock reduction incineration apparatus comprises a waste incineration section for introducing waste, a solid waste incineration section including a stepped combustion plate for combusting the waste incinerated during the movement of the waste, A gas induction heating and a combustion zone spaced apart from the solids combustion zone to induce heating circulation for preheating the organic gas generated in the combustion process of the combustion zone, and a gas for heating or burning the organic gas in the circulation induction process for the preheating purpose A gas heating unit including a combustor and an air mixer for mixing the combustion air in the circulation induction process; and a gas discharge unit for discharging the mixed combustion gas in which the heated gas and the combustion air are mixed in the circulation induction process in the reverse circulation direction .

The gas induction heating and the partial combustion section may gradually reduce the space in which the organic gas and the mixed combustion gas are merged to form the starting region of the circulation inducing process to a specific section.

The gas heating unit further includes a spring-type boiler water pipe connected between the extension structure of the step-like combustion plate and the gas induction heating and a part of the combustion zone and absorbing the heat of the mixed combustion gas during the circulation induction process to reduce the knock .

The gas induction heating and a part of the combustion section may form a gas induction wall vertically formed in the gas heating section from a region where the organic gas and the mixed combustion gas meet to a region where the gas combustor is installed.

Wherein the gas induction heating and a portion of the combustion zone include a first direction inducing wall for inducing the organic gas in a first direction, a second direction that is guided in the first direction and induces gas heated by the gas combustor in a second direction An induction wall, and a third direction inducing wall that induces the gas introduced in the second direction and mixed by the air mixer in a third direction.

Wherein the air mixer includes a combustion air supply member for inputting the combustion air, an oxygen concentration sensor member for sensing an oxygen concentration in the gas heating unit, and an oxygen concentration sensor member for sensing the oxygen concentration, And a combustion air control member for controlling the amount of combustion air introduced into the combustion air supply member.

The air mixer may burn at least a part of the combusted gas by burning at a temperature of 1,000 ° C. or higher within a predetermined time in the course of mixing with the combustion air using the heated gas.

Wherein the stepped combustion plate comprises a drying plate member for drying the drawn-in waste, a pyrolysis substrate member for pyrolyzing the dried waste, at least one combustion plate member for burning the pyrolyzed waste, and a radiant heat generated in the circulation induction process To completely burn at least a part of the waste moved from the at least one combustion plate by using the carbon combustion plate member.

The disclosed technique may have the following effects. It is to be understood, however, that the scope of the disclosed technology is not to be construed as limited thereby, as it is not meant to imply that a particular embodiment should include all of the following effects or only the following effects.

The incineration apparatus for reducing rust according to an embodiment of the present invention can completely reduce the amount of generated nitric oxide (NOx), which is a pollutant, while completely burning the refuse in the incineration process of the refuse.

The rust reducing incinerator according to an embodiment of the present invention circulates and induces the gas generated in the process of burning the waste, thereby completely burning, burning, and pyrolyzing a large amount of combustible materials and contaminants contained in the gas.

The knock reduction incinerator according to an embodiment of the present invention can reduce the occurrence of knocks by controlling and maintaining the concentration of oxygen contained in the gas subjected to combustion and the temperature (850 ° C) of the knock generation reduction condition .

1 is a view for explaining an incinerator for reducing rust according to an embodiment of the present invention.
FIG. 2 is a flowchart for explaining an embodiment of a process of incinerating garbage in the incineration apparatus for reducing rust in FIG.
FIG. 3 is a flowchart for explaining another embodiment of the process of burning garbage in the rust reducing incineration apparatus of FIG.

The description of the present invention is merely an example for structural or functional explanation, and the scope of the present invention should not be construed as being limited by the embodiments described in the text. That is, the embodiments are to be construed as being variously embodied and having various forms, so that the scope of the present invention should be understood to include equivalents capable of realizing technical ideas. Also, the purpose or effect of the present invention should not be construed as limiting the scope of the present invention, since it does not mean that a specific embodiment should include all or only such effect.

Meanwhile, the meaning of the terms described in the present application should be understood as follows.

The terms "first "," second ", and the like are intended to distinguish one element from another, and the scope of the right should not be limited by these terms. For example, the first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component.

It is to be understood that when an element is referred to as being "connected" to another element, it may be directly connected to the other element, but there may be other elements in between. On the other hand, when an element is referred to as being "directly connected" to another element, it should be understood that there are no other elements in between. On the other hand, other expressions that describe the relationship between components, such as "between" and "between" or "neighboring to" and "directly adjacent to" should be interpreted as well.

It is to be understood that the singular " include " or "have" are to be construed as including the stated feature, number, step, operation, It is to be understood that the combination is intended to specify that it does not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

In each step, the identification code (e.g., a, b, c, etc.) is used for convenience of explanation, the identification code does not describe the order of each step, Unless otherwise stated, it may occur differently from the stated order. That is, each step may occur in the same order as described, may be performed substantially concurrently, or may be performed in reverse order.

All terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs, unless otherwise defined. Commonly used predefined terms should be interpreted to be consistent with the meanings in the context of the related art and can not be interpreted as having ideal or overly formal meaning unless explicitly defined in the present application.

1 is a view for explaining an incinerator for reducing rust according to an embodiment of the present invention.

Referring to FIG. 1, the knock reduction incinerator 100 includes a waste inlet 110, a solid combustor 120, a gas heating unit 130, a gas discharge unit 140, and a reprocessing unit 150 .

The garbage inlet portion 110 can draw the garbage 160 therein. In one embodiment, the waste inlet 110 can temporarily store the waste 160 and move it to the solid combustor 120 by a certain amount.

The garbage inlet unit 110 may include a temporary storage unit 112, an inlet switch 114, and a charging unit 116.

The temporary storage device 112 may temporarily store the waste 160. [

The withdrawal switch 114 is formed at the lower end of the temporary storage unit 112 and is openable and closable. The inlet switch 114 can control opening and closing at a specific cycle and can automatically adjust the opening and closing cycle according to the temperature inside the gas heating unit 130 and the gas combustion chamber. In one embodiment, when the withdrawal switch 114 is opened, the draft 160 stored in the temporary storage 112 may be drawn.

The injector 116 can move the drawn-in garbage 160 to the solids burning unit 120. More specifically, the dispenser 116 can reciprocate back and forth at regular intervals, and can push the drawn-out garbage 160 and move it to the solid-matter burning unit 120.

The solid combustor 120 can combust the drawn-in waste 160. The solids burner 120 includes a stepped combustion plate 121. The stepped combustion plate 121 can burn the garbage 160 that is drawn in during the movement of the drawn-in garbage 160. In one embodiment, the stepped combustion plate 121 may be formed in a stepped shape to burn the introduced refuse 160 step by step.

The stepped combustion plate 121 may include a dry plate member 122, a thermal decomposition substrate member 123, at least one combustion plate member 124, and a carbon combustion plate member 125. The drying plate member 122 can dry the drawn-in garbage 160. The pyrolysis substrate member 123 can pyrolyze the dried refuse 160. The combustion plate member 124 can combust the pyrolysed refuse 160. The carbon combustion plate member 125 can completely burn at least a part of the garbage 160 moved from the at least one combustion plate member 124 by using radiant heat generated in the circulation induction process. The carbon combustion plate member 125 can completely burn remaining residual combustible objects and carbon components using such radiant heat.

In one embodiment, the stepped combustion plate 121 can more completely burn the waste 160 in accordance with such stepwise combustion, and can reduce the phenomenon that a large amount of dust is generated while the combustion is incomplete or incompletely combusted have.

The gas heating unit 130 may heat (preheat), burn, or circulate the organic gas 170 generated during the combustion process of the drawn-in garbage 160. In one embodiment, the organic gas 170 corresponds to the organic gas 170 generated during the drying, pyrolysis and combustion of the drawn-in garbage 160 by the solids burning unit 120. In one embodiment, the gas heating unit 130 may induce such preheating and complete combustion of the organic gas 170, and in this process, the heated gas 175, which is newly generated or converted from the organic gas 170, The circulation of the convection flow to the combustion air 180 and the mixed combustion gas 185 and the like can be induced.

The gas heating section 130 may include gas induction heating and some combustion section 131, at least one gas combustor 132, at least one air mixer 133 and a spring-type boiler water pipe 137.

The gas induction heating and some combustion sections 131 are separated from the solids burning section 120 so as to circulate the organic gas 170 generated in the combustion process of the drawn-in refuse 160. In one embodiment, the gas induction heating and some combustion zones 131 may be formed to include a passage to allow the circulation of the organic gas 170 on the upper portion, and may be formed by the stepped combustion plate 121 formed at the lower portion. So that the organic gas 170 which is not combusted can be guided into the gas combustion chamber.

The gas induction heating and the partial combustion section 131 may gradually reduce the space 139 in which the organic gas 170 and the mixed combustion gas 185 join to form the starting region of the circulation induction process to a specific section. In one embodiment, the gas induction heating and some of the combustion zones 131 are formed such that the volume of the gas which can come into contact with the space 139 forming the start region of the circulation inducing process is larger as the volume is lowered, Can be formed. The shape of the gas induction heating and the partial combustion section 131 makes the pressure of the space 139 forming the starting region of the circulation induction relatively lower than that of the upper part, Induction heating and some empty space of the combustion section 131, thereby inducing circulation.

Gas induction heating and gas induction heating are performed in the gas heating unit 130 of the partial combustion zone 131 from the region where the organic gas 170 and the mixed combustion gas 185 meet to the region where the gas combustor 132 is installed, (138) can be formed. Accordingly, the gas induction heating and the partial combustion section 131 can induce the organic gas 170 into the gas heating section 130 more efficiently.

The structure of the gas induction heating and the partial combustion section 131 may include a first direction induction wall 131a, a second direction induction wall 131b and a third direction induction wall 131c. The first direction inducing wall 131a can induce the organic gas 170 in the first direction. The second direction inducing wall 131b can direct the gas 175 that is directed in the first direction and heated by the gas combustor 132 in the second direction. The third direction inducing wall 131c can guide the mixed combustion gas 185 induced in the second direction and mixed by the air mixer 133 in the third direction.

In one embodiment, the first direction inducing wall 131a, the second direction inducing wall 131b, and the third direction inducing wall 131c are connected to each other in a protruded and bent form, And the organic gas 170 in the third direction.

In another embodiment, the gas heating unit 130 may include a first direction inducing wall 131a, a second direction inducing wall 131b, and a third direction inducing wall 131c that do not protrude outward . At least two of the first direction, the second direction and the third direction, which are respectively guided by the first direction inducing wall 131a, the second direction inducing wall 131b and the third direction inducing wall 131c, May be identical to each other. More specifically, the upper part of the gas heating part 130 can be connected to the upper extension structure of the waste inlet part 110 and the upper extension structure of the discharge outlet 142, and can be formed flat without protruding outward do.

The gas combustor 132 may combust the organic gas 170 during the circulation induction process. In one embodiment, the gas combustor 132 is formed at one end of the gas heating unit 130, and the organic gas 170 induced by the gas heating unit 130 is heated to a predetermined temperature or higher, It can be burned at a low temperature, and the heated gas 175 can be generated in this process. Here, the meaning of generating may be applied not only to generate a new one, but also to a concept that includes both a component or a molecular connection structure to another gas or to apply a temperature difference to an existing gas. In one embodiment, the gas combustor 132 may preheat the organic gas 170 to a temperature above a certain level to produce a heated gas 175, thereby forming a gas 175 in the air mixer 133, Can be more easily and rapidly burned at a high temperature so as to be able to perform complete combustion.

In one embodiment, the gas combustor 132 may be formed at one end of the second direction inducing wall 131b and may burn the induced organic gas 170 in the second direction. The gas combustor 132 can cause the induction circulation process of the gas heating unit 130 to proceed more easily through the difference in pressure generated in this process.

The air mixer 133 may mix the combustion air 180 during the circulation induction process. The air mixer 133 is spaced apart from the gas combustor 132 and formed at one end of the upper portion of the gas heating section 130 so as not to cross the inside of the gas heating section 130, 130 and the combustion gas 180 is mixed with the heated gas 175 generated by the gas combustor 132 to generate the mixed combustion gas 185. The heated gas 175 Can be completely burned. In one embodiment, the combustion air 180 may correspond to compressed air entering from the outside, and may correspond to air heated to a high temperature above a certain temperature. In one embodiment, the mixed combustion gases 185 may comprise residual gases after mixing by the air mixer 133. [

The air mixer 133 is absent in order to strongly induce the gas to the lower end together with the combustion air introduction, and may be configured to include an oxygen concentration sensor member and a combustion air control member.

The combustion air supply member can introduce the combustion air (180). In one embodiment, the combustion air input member includes an air distributor that includes a plurality of air nozzles corresponding to holes that inject combustion air 180 into the gas heating portion 130, And an air supply unit capable of supplying the air supply unit 180.

The oxygen concentration sensor member can sense the oxygen concentration in the gas heating unit 130 or the outlet 142. In one embodiment, the oxygen concentration sensor member can detect the concentration of oxygen (O ₂ ) gas contained in the combusted gas through the gas heating unit 130 through the ultrasonic sensor and the sensor.

The combustion air control member passes through the gas heating unit 130 based on the result of sensing by the oxygen concentration sensor member, and supplies the combustion air 180 of the combustion air input member to the input amount Can be controlled. In one embodiment, the combustion air control member is configured to control the amount of combustion air 180 injected by the combustion air input member when the resultant concentration of the sensed oxygen gas is above a certain concentration (e.g., about 6-9%) The amount of oxygen gas can be controlled so that the concentration of oxygen gas can be kept below the concentration. Since the rust and carbon monoxide are generated due to the excessive supply of oxygen gas, the air mixer 133 can remarkably reduce the occurrence of the rust by controlling the amount of the combustion air 180 input.

The air mixer 133 is capable of burning at least a part of the heated gas 175 by burning within a specified time at a temperature of 1000 ° C or higher by mixing the heated gas 175 with the combustion air 180.

The gas heating unit 130 may further include at least one gas stable combustion tile member 190 formed at one end thereof and capable of burning the heated gas 175 or the mixed combustion gas 185. In one embodiment, the gas-stable combustion tile member 190 may be formed at one end of the gas heating unit 130, which can abut the area where the mixed combustion gas 185 is generated by the air mixer 133, The air mixer 133 is capable of stably and completely burning the heated gas 175 through the gas-stable combustion tile member. In one embodiment, the number of gas combustors 132 and gas-stable combustion tile members 190 may be the same.

The gas heating unit 130 may heat the oxygen gas in the combustion process to reduce the oxygen concentration, thereby reducing the amount of the rust.

The spring-type boiler water pipe 137 is connected between the extension structure of the step-like combustion plate 121 and the gas induction heating and a part of the combustion section 132, and absorbs the heat of the mixed combustion gas 185 The spring-type boiler water pipe 137 can absorb a part of the combustion heat of the mixed combustion gas 185 to control the ambient temperature so that it does not rise above a certain temperature. In one embodiment, The boiler water pipe 137 can control the ambient temperature to not rise by more than 1200 ° C. through the endothermic process. More specifically, in order to significantly reduce the amount of generated SOx and NOx, (For example, 1050 ° C to 1150 ° C) within a certain range (for example, ± 50 ° C) at 1100 ° C.

The spring-type boiler water pipe 137 may include a spring-type water pipe formed in the form of a spring. In one embodiment, the spring-type boiler water pipe 137 may be configured in the form of a matrix in which a plurality of spring-type water pipes are spaced apart at regular intervals. Such a spring-type boiler water pipe 137 can have a larger surface area in a limited space inside the knock reduction incineration apparatus 100 and can absorb the heat of the mixed combustion gas 185 to lower the temperature . Accordingly, the spring-type boiler water pipe 137 has an advantage that it can have remarkably higher energy efficiency than the straight boiler water pipe.

The spring-type water pipes of the spring-type boiler water pipe 137 can be configured to be assembled. In one embodiment, the extension structure of the stepped combustion plate 121 and the connecting portion of the spring-type boiler water pipe 137 abutting the gas induction heating and the respective combustion sections 132, respectively, are assembled and disassembled with respect to one spring- And at least one thread or hook and latch for enabling the user to operate the apparatus. In one embodiment, each of the spring-like water pipes includes a plurality of water pipe connecting units, which can be connected to each other in a vertical direction, and each of the water pipe connecting units is provided with at least One thread or hook and latch.

According to the above-described embodiments, the spring-type boiler water pipe 137 is not configured as a buried and welded type but can be constructed as an assembled type that can be disassembled and replaced, thereby facilitating maintenance work. In the process of incinerating the refuse 160, salt is often contained in the refuse 160, and at least a part of the spring-type boiler water pipe 137 may be corroded by the salt. In the case of such salt corrosion, a small hole may be partially formed in the spring-type boiler water pipe 137. In one embodiment, the spring-type boiler water pipe 137 can disassemble only the water-pipe connecting unit of the corroded spring-type water pipe or the spring-type water pipe without replacing the whole for the partial corrosion forming the small hole, There is an advantage that the replacement operation can be completed simply.

The gas discharge unit 140 may discharge the mixed combustion gas 185 in which the heated gas 175 and the combustion air 180 are mixed during the circulation induction process in the reverse circulation direction. In an embodiment, the gas discharging part 140 may be formed to be spaced away from the garbage inlet part 110 with the gas heating part 130 interposed therebetween.

The gas discharge portion 140 may include an outlet 142 and a gas discharge guide wall 144. The discharge port 142 is openable and closable to the outside so as to discharge the mixed combustion gas 185. The gas discharge induction wall 144 may be formed vertically from the region where the mixed combustion gas 185 is discharged to the lower portion. In one embodiment, the gas discharge guide wall 144 may be formed to intercept some sections between the discharge port 142 and the gas heating section 130 and to open the remaining sections. Accordingly, the gas discharging part 140 may apply a physical resistance to the flow of the surrounding fluid including the mixed combustion gas 185 to delay the discharge time of the mixed combustion gas 185, The gas 185 can be burned for a longer time to reduce CO gas and O 2 remaining in the mixed combustion gas 185.

The reprocessing unit 150 may combust the waste 160 formed at one end of the stepped combustion plate 121 and moved from the stepped combustion plate 121. More specifically, the reprocessing unit 150 can reprocess a part of the waste 160 that has been moved from the stepped combustion plate 121 and that has not been burned, and can move the remnant remaining after a certain period of time to a specific space And can be opened and closed so as to be taken out to the outside.

FIG. 2 is a flowchart for explaining an embodiment of a process of incinerating garbage in the incineration apparatus for reducing rust in FIG.

In FIG. 2, the process of incinerating the refuse 160 in the rust reducing incinerator 100 may include the following steps.

The garbage inlet portion 110 can draw the garbage 160 therein. When the refuse 160 is drawn in, the stepped combustion plate 121 of the solid combustor 120 can burn the refuse 160 that is introduced during the movement of the refused refuse 160 (step S210).

The gas induction heating and the partial combustion section 131 may induce the circulation of the organic gas 170 generated in the pyrolysis and combustion process of the drawn-in garbage 160 (step S220).

The gas combustor 132 can burn the organic gas 170 in a state where it is possible to increase the combustion efficiency in the preheated state during the circulation induction process (step S230).

The air mixer 133 may mix the combustion air 180 in the circulation induction process (step S240).

Here, the structure of the air mixer 133 has a composite structure capable of controlling the rising temperature by using the fuel supply for the required temperature rise and the water at the time of overheating

The gas discharge unit 140 may discharge the mixed combustion gas 185 in which the heated gas 175 and the combustion air 180 are mixed in the circulation induction process in the reverse circulation direction (step S250).

The mixed combustion gas 185 in which the heated gas 175 and the combustion air 180 are mixed can be circulated in the course of gas induction heating and circulation induction of the partial combustion section 131. [ In one embodiment, a certain proportion (e.g., 40%) or more of the mixed combustion gas 185 joins the organic gas 170 in the space 139 forming the start region of the circulation induction process, In a clockwise direction). Through such a process, the above steps can be repeated and the length of each guide wall is structured such that the gas guide wall 138 is made shorter than the gas exit guide wall 144.

FIG. 3 is a flowchart for explaining another embodiment of the process of burning garbage in the rust reducing incineration apparatus of FIG.

3, the process of incinerating the refuse 160 in the rust reducing incinerator 100 may include the following steps.

The trash inlet 110 can temporarily store the trash 160 and can move the trash 160 to the solids burning unit 120 by a predetermined amount (step S310). The garbage inlet part 110 can automatically control the opening and closing cycle according to the temperature inside the gas heating part 130.

The stepped combustion plate 121 of the solid combustor 120 may be formed in a stepped shape so as to burn the entered refuse 160 in stages (step S320). Stepwise combustion includes a drying plate member 122 for drying the drawn-in garbage 160, a pyrolysis substrate member 123 for pyrolyzing the dried garbage 160, a plurality of combustion plate members for burning the pyrolysed garbage 160 And a carbon combustion plate member 125 capable of completely burning the residual combustible object and carbon components of the moved refuse 160 using the radiant heat generated in the circulation induction process do. Through such stepwise combustion, the complete combustion of the refuse 160 can be increased and the occurrence of dust can be reduced.

The gas heating unit 130 may heat, partially burn, and circulate the organic gas 170 generated during the combustion process of the drawn-in garbage 160 (step S330). The space 139 in which the gas 170 heated by passing through the gas induction heating and the partial combustion section 131 and the mixed combustion gas 185 join to form the start region of the circulation induction process is gradually reduced to a specific section And the organic gas 170 can be moved to the gas induction heating and the empty space of the partial combustion section 131 according to the pressure difference to induce the circulation. In addition, the gas induction heating and some combustion section 131 can guide the organic gas 170, which has been raised by convection by heat through the gas induction wall 138, into the gas heating section 130 better. The gas combustor 132 may be formed at one end of the second direction inducing wall 131b to burn the induced organic gas 170 in the second direction and apply heat to the induced organic gas 170 It may be preheated or burned to a temperature above a certain level. In the process of mixing the heated gas 175 with the combustion air 180, it is possible to burn at least a part of the heated gas 175 completely within a certain time at 1000 ° C or higher.

The air mixer 133 may control the amount of the combustion air 180 to be supplied so that the oxygen concentration of the discharge portion is kept below a specified level (Step S340). The air mixer 133 can significantly reduce the occurrence of the knocking by controlling the amount of the combustion air 180 input.

The spring-type boiler water pipe 137 can absorb a part of the combustion heat of the mixed combustion gas 185 to control the ambient temperature to not rise above a specific temperature (for example, 1000 ° C) (Step S350).

The gas discharge part 140 may apply a physical resistance to the flow of the surrounding fluid including the mixed combustion gas 185 through the gas discharge induction wall 144 to delay the discharge time of the mixed combustion gas 185, In this delay process, the mixed combustion gas 185 can be burned longer to reduce the CO gas remaining in the mixed combustion gas 185 (step S360).

The gas discharge unit 140 can discharge the mixed combustion gas 185 in which the heated gas 175 and the combustion air 180 are mixed in the circulating induction process in the reverse circulation direction, 131 may circulate the mixed combustion gas 185 in which the heated gas 175 and the combustion air 180 are mixed in the circulation induction process. Through the above process, the above steps can be repeated.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the present invention as defined by the following claims It can be understood that

100: Knock reduction incinerator
110: garbage inlet portion 112: temporary storage device
114: Inlet switch 116:
120: solid combustor part 121: stepped combustion plate
122: Dry plate member 123: Pyrolysis substrate member
124: combustion plate member 125: carbon combustion plate member
130: gas heating unit 131: gas induction heating and some combustion zone
132: gas combustor 133: air mixer
137: Spring type boiler water pipe
138: gas guide wall 140: gas outlet
142: Outlet 144: Gas discharge guide wall
150: Reprocessing section 160: Trash
170: Organic gas generated in pyrolysis and combustion process of incoming garbage
175: heated gas 180: combustion air
185: mixed combustion gas 190: gas-stable combustion tile member

Claims (8)

A trash inlet for receiving trash;
A solid combustor including a stepped combustion plate for combusting the drawn-in garbage during the movement of the drawn-in garbage;
Heating the organic gas in the course of gas induction heating spaced apart from the solids burning portion to induce heating circulation for preheating the organic gas generated in the combustion process of the introduced garbage, An air mixer for mixing the combustion air in the circulation induction process, and an air mixer connected between the extension structure of the stepped combustion plate and the gas induction heating and a part of the combustion zone to absorb heat of the mixed combustion gas in the circulation induction process A gas heating unit including a spring-type boiler water pipe for reducing the knock; And
And a gas discharge unit for discharging the mixed combustion gas, which is a mixture of the heated gas and the combustion air, in a circulating direction in a circulating direction.
The method of claim 1, wherein the gas induction heating and some combustion zones
Wherein the flow path width or length of the space forming the start region of the circulation induction process by the merging of the organic gas and the mixed combustion gas is gradually reduced to a specific section.
delete The method of claim 1, wherein the gas induction heating and some combustion zones
Wherein the gas induction wall is formed vertically in the gas heating unit from a region where the organic gas and the mixed combustion gas meet to a region where the gas combustor is installed.
The method of claim 1, wherein the gas induction heating and some combustion zones
A first direction inducing wall for guiding the organic gas in a first direction, a second direction inducing wall for inducing a gas guided in the first direction and heated by the gas combustor in a second direction, And a third direction inducing wall for guiding the gas mixed by the air mixer in a third direction.
The air conditioner according to claim 1, wherein the air mixer
An oxygen concentration sensor member for sensing the oxygen concentration inside the gas heating unit; and a sensor for detecting the concentration of oxygen in the gas heating unit based on the sensed result, And a combustion air control member for controlling the amount of combustion air to be injected into the combustion chamber.
The air conditioner according to claim 6, wherein the air mixer
Wherein the combustion gas is burned at a temperature of 1,000 ° C or higher within a predetermined time in the process of mixing the heated gas with the combustion air to completely burn at least a part of the combusted gas.
The method as claimed in claim 1, wherein the stepped combustion plate
A pyrolysis substrate member for pyrolyzing the dried refuse, at least one combustion plate member for combusting the pyrolysed refuse, and a radiant heat generated in the circulation induction process, And a carbon combustion plate member for completely burning at least a part of the garbage moved from the combustion plate of the knock reduction burning incinerator.

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