KR102131179B1 - An Incineration system with integrated dust collector having a combined heat and power generator - Google Patents

Abstract

The present invention discloses an integrated incinerator system capable of generating electricity. An incineration system capable of cogeneration in accordance with the present invention disclosed includes a combustion chamber that separates input waste from the outside; An air supply pipe disposed in the center of the combustion chamber to inject air into the combustion chamber; A stirring part rotating the supply pipe below the combustion chamber as a fixed shaft; A plurality of thermoelectric elements disposed along the periphery of the combustion chamber; An electric control device that regulates collecting or supplying electricity generated by the thermoelectric elements to the outside; A dust collecting device disposed above the fuel chamber and arranged to remove fine dust and air pollutants contained in exhaust gas discharged from the combustion chamber; A residue removal device that is drawn outward from the fuel chamber to remove residues; A heat recovery device disposed on one side outside the combustion chamber and recirculating exhaust gas discharged from the dust collecting device to the bottom of the combustion chamber; And a control device that controls the combustion chamber, the air injection of the supply pipe, the stirring part, the power generation device, the dust collecting device, and the residue removal device, wherein the electrical control device includes an electrical storage part and electricity generated from the thermoelectric element or the It characterized in that it comprises an electric supply control unit for controlling the supply of electricity supplied from the electrical storage to the outside.

Description

An incineration system with integrated dust collector having a combined heat and power generator}

The present invention relates to an incineration system, and more particularly, to an incineration system in which air pollutant emissions can be minimized and a dust collector is integrated while functioning as a power generation function using heat generated in a waste incineration process.

Rapid industrial development provided a new paradigm for human civilization such as society, economy, health care and life. However, along with this, various living, medical, and industrial wastes were generated in large quantities, making them a major social problem. Due to this, there is an increasing demand for methods and apparatus for treating living and industrial waste.

In general, the method of disposing of garbage or waste is carried out by dumping or incineration. Here, the incineration method is a method in which wastes and wastes collected and transported by local ministries are burned together with fuel in a large-scale incineration facility. However, such an incineration method has a problem in that it is not only large in initial cost for preparing a large incineration facility, but also requires considerable cost to operate and maintain the facility thereafter.

As a method for solving this problem, a small-scale industrial waste treatment device capable of mobile installation is attracting attention, and one of them is a low-temperature pyrolysis incinerator. In particular, the development of such a movable small-scale incineration device is required because medical waste, industrial waste, etc. are special wastes that must be incinerated.

This incineration device thermally decomposes various waste tires or industrial wastes at the dry body to vaporize the carbon materials of industrial waste to continuously generate gas that can be used as fuel, and supply the gas to the combustion chamber through an induction pipe. Therefore, it is introduced as incineration treatment without emission of air pollutants by making it completely burned.

However, the low-temperature pyrolysis and incineration apparatus having the above-described configuration, when burning chemical products such as vinyl and plastic, often causes a problem that the combustion chamber is overheated and causes severe fumes, and in case of waste with a high moisture content, becomes incomplete combustion. There are many cases, and there is the inconvenience of classifying and incinerating wastes by type.

Particularly, dioxin generated during combustion requires a separate secondary combustion device to be removed in parallel to the exhaust side, so energy consumption is high, and low-temperature pyrolysis has a long treatment time, which limits the daily treatment capacity.

As such, the incineration apparatus according to the prior art has a problem that unsafe incineration treatment occurs according to the type of waste, in addition to the large-scale incineration facility, which is generated by mobile, thereby increasing the generation of air pollutants.

Therefore, it is easy to move and can completely incinerate wastes regardless of the type of waste, and it has a complex function that can convert and use heat generated during incineration to other energy sources while minimizing air pollutants generated during the incineration process. Development of an incineration device is required.

Republic of Korea Registered Patent Publication No. 10-1799806

An object of the present invention, by allowing the nozzle portion of the nozzle disposed in the supply pipe located in the center of the combustion chamber to blow air at random, sufficient air is supplied to all areas of the combustion chamber to improve the incineration efficiency. To provide.

In addition, an object of the present invention is to provide a dust collector-integrated incineration system capable of generating power to reduce incineration residues generated in the incineration process by continuously stirring the waste (incineration products) during the incineration process in the combustion chamber. Is doing.

In addition, an object of the present invention is to provide an incineration system capable of cogeneration, capable of automatically removing incineration residues according to a size after an incineration process is completed in a combustion chamber according to a command of a control device.

In addition, the object of the present invention, by removing the air pollutants contained in the exhaust gas discharged from the combustion chamber by a dust collector disposed on the lead of the combustion chamber to recover the high-temperature exhaust gas again to supply to the combustion chamber thermal efficiency of the combustion chamber It is to provide a dust collector integrated incineration system capable of improving power generation.

In addition, an object of the present invention, by arranging a plurality of thermoelectric elements along the periphery of the combustion chamber, by collecting and supplying the electricity generated by the thermoelectric element to provide a dust collector integrated incineration system capable of generating power to utilize the thermal energy as electrical energy Is doing.

An incinerator integrated incineration system capable of developing the present invention for improving the prior art as described above, the combustion chamber to separate the input waste from the outside; An air supply pipe disposed in the center of the combustion chamber to inject air into the combustion chamber; A stirring part rotating the supply pipe below the combustion chamber as a fixed shaft; A plurality of thermoelectric elements disposed along the periphery of the combustion chamber; An electric control device that regulates collecting or supplying electricity generated by the thermoelectric elements to the outside; A dust collecting device disposed above the fuel chamber and arranged to remove fine dust and air pollutants contained in exhaust gas discharged from the combustion chamber; It is disposed under the fuel chamber to classify incineration residues according to their size during incineration processing in the fuel chamber, and after the incineration treatment is completed, remove residues that are drawn outward from the fuel chamber to remove residues Device; A heat recovery device disposed on one side outside the combustion chamber and recirculating exhaust gas discharged from the dust collecting device to the bottom of the combustion chamber; And a control device that controls the combustion chamber, the air injection of the supply pipe, the stirring part, the power generation device, the dust collecting device, and the residue removing device, wherein the electrical control device is an electrical storage part that stores electricity generated by the thermoelectric element. And, it characterized in that it comprises an electric supply control unit for controlling the supply of electricity generated from the thermoelectric element or the electricity supplied from the electrical storage to the outside.

Here, the supply pipe is a nozzle portion is disposed in the upper region, the central region and the lower region, the nozzle portion is composed of a plurality of air injection nozzles along the periphery of the supply pipe, the plurality of air injection nozzles are adjacent air minutes The air is injected in a different direction from the sano line, and the dust collecting device includes a centrifugal collecting part for collecting dust contained in the exhaust gas supplied from the combustion chamber, and fine dust from the exhaust gas in which the collecting process is completed in the centrifugal collecting part. It characterized in that it comprises a dust collecting reaction unit for removing, and a catalyst unit for removing nitrogen oxides from the exhaust gas passing through the dust collecting reaction unit.

In addition, the dust collecting device further comprises an exhaust part for supplying exhaust gas to the circulation unit after the exhaust gas is collected, and the dust collecting device receives exhaust gas through an exhaust part disposed at an upper side of the combustion chamber, and then collects dust. After proceeding, the exhaust gas is discharged to the circulation pipe through the discharge unit, and the residue removal device includes a mesh unit for filtering residues having a relatively large size, and a residue holder for collecting residues having a relatively small size. , An intake portion for removing residue remaining in the residue holder by an intake method.

In addition, the mesh portion of the residue removal device is drawn out from the combustion chamber, and then inclined at a predetermined angle and vibrates at regular intervals to remove the residue remaining in the mesh portion, and the incineration system supplies fuel to the combustion chamber. A fuel supply device further includes a fuel supply device for supplying fuel supplied from the fuel supply device to the inside of the combustion chamber, and a plurality of fuel injection nozzles are disposed at equal intervals in the fuel supply tube. It is characterized by.

The incineration system capable of generating electricity according to the present invention has the effect of improving the incineration efficiency by supplying sufficient air to all areas of the combustion chamber by randomly blowing out the nozzles of the nozzle units disposed in the supply pipe located at the center of the combustion chamber. have.

In addition, the incineration system capable of generating power according to the present invention has an effect of reducing the incineration residues generated in the incineration process by continuously stirring the waste (incineration products) in the incineration process in the combustion chamber.

In addition, the incineration system capable of generating power according to the present invention has an effect of automatically removing incineration residues according to a size according to a command of a control device.

In addition, the incineration system capable of generating electricity according to the present invention recovers high temperature exhaust gas again and supplies it to the combustion chamber while removing air pollutants contained in the exhaust gas discharged from the combustion chamber by a dust collecting device disposed on the lead of the combustion chamber. By doing so, there is an effect that can improve the thermal efficiency of the combustion chamber.

In addition, the incineration system capable of generating electricity according to the present invention has an effect of arranging a plurality of thermoelectric elements along the periphery of the combustion chamber, and collecting and supplying electricity generated by the thermoelectric elements to utilize thermal energy as electric energy.

1 is a view showing an incineration system capable of cogeneration in accordance with the present invention.
Figure 2 is a view showing the structure of the supply pipe and the fuel nozzle of the incineration system capable of cogeneration in accordance with the present invention.
3 is an enlarged view of area A of FIG. 2.
4 is a view showing the air flow inside the combustion chamber of the incineration system capable of cogeneration according to the present invention.
5A is a view for explaining the principle of generating electricity by a thermoelectric element of an incineration system capable of generating electricity according to the present invention.
5B is a view showing the structure of an electric control device for collecting and managing electricity generated in the thermoelectric element of FIG. 5A.
6 is a view showing the structure of a dust collector in an incineration system capable of cogeneration in accordance with the present invention.
7 is a view for explaining the dust collecting principle of the dust collecting device in the incineration system capable of cogeneration power generation according to the present invention.
8 is a view showing the structure of the residue removal device of the incineration system capable of cogeneration in accordance with the present invention.
9A to 9C are diagrams for explaining a process of removing residues of a residue removal device of an incineration system capable of cogeneration according to the present invention.

Advantages and features of the present invention, and methods for achieving them will be clarified with reference to embodiments described below in detail together with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in various different forms, and only the present embodiments allow the disclosure of the present invention to be complete, and the ordinary knowledge in the technical field to which the present invention pertains. It is provided to fully inform the holder of the scope of the invention, and the invention is only defined by the scope of the claims.

The shapes, sizes, ratios, angles, numbers, and the like disclosed in the drawings for describing the embodiments of the present invention are exemplary, and the present invention is not limited to the illustrated matters. The same reference numerals refer to the same components throughout the specification. In addition, in the description of the present invention, when it is determined that detailed descriptions of related known technologies may unnecessarily obscure the subject matter of the present invention, detailed descriptions thereof will be omitted.

When'include','have','consist of', etc. mentioned in the specification are used, other parts may be added unless'~man' is used. When a component is expressed as a singular number, the plural number is included unless otherwise specified.

In interpreting the components, it is interpreted as including the error range even if there is no explicit description.

In the case of the description of the positional relationship, for example, when the positional relationship of two parts is described as'~top','~upper','~bottom','~side', etc.,'right' Alternatively, one or more other parts may be located between the two parts unless'direct' is used.

In the case of a description of a time relationship, for example,'after','following','~after','~before', etc., when the temporal preliminary relationship is described,'right' or'directly' It may also include cases that are not continuous unless' is used.

The first, second, etc. are used to describe various components, but these components are not limited by these terms. These terms are only used to distinguish one component from another component. Therefore, the first component mentioned below may be the second component within the technical spirit of the present invention.

Each of the features of the various embodiments of the present invention may be partially or wholly combined or combined with each other, technically various interlocking and driving may be possible, and each of the embodiments may be independently implemented with respect to each other or may be implemented together in an associative relationship. It might be.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. And in the drawings, the size and thickness of the device may be exaggerated for convenience. Throughout the specification, the same reference numbers refer to the same components.

1 is a view showing an incineration system capable of cogeneration in accordance with the present invention.

Referring to FIG. 1, the incineration system 100 capable of cogeneration power generation according to the present invention includes a combustion chamber 102 in which waste or waste (incineration treatment products) is incinerated, and a heat recovery device disposed around the combustion chamber 102 ( 104) and a fuel supply device (106) for supplying fuel to the combustion chamber (102), a plurality of thermal elements (400) arranged along the outer periphery of the combustion chamber (102), and the thermal elements (400) It includes an electrical control device 280 and the control device 108 for collecting and controlling the electricity supplied from.

The inner and outer walls of the combustion chamber 102 are composed of a steel sheet finished with heat-resistant and acid-resistant materials, and in the center of the cylindrical combustion chamber 102, air is injected (injected) by force to improve combustion efficiency in the combustion chamber 102. The trachea 110 is arranged vertically. In addition, a lid (Lid: 112) is disposed on the upper side of the combustion chamber 102 to inject incineration treatment, for example, garbage or waste, and to block the outside of the combustion chamber 102 during the incineration process.

A fuel supply pipe 114 for promoting combustion is disposed radially between the upper side of the combustion chamber 102 and the lead 112. 158 illustrated in the drawing serves as a temperature sensor to sense the temperature of the combustion chamber 102. The control device 108 controls the temperature of the combustion chamber 102 based on the sensed temperature information.

It is preferable that the supply pipe 110 adopts a material that can withstand high temperatures of 1300° C. or higher, and the amount of oxygen introduced into the combustion chamber 102, the wind pressure, and the input direction are determined by its length and cross-sectional shape. The supply pipe 110 is disposed in the vertical region in the upper region, the central region, and the lower region, respectively, so that the air is circulated evenly in the entire area inside the combustion chamber 102. As illustrated in FIG. 2, the nozzle unit 116 may be composed of a plurality of air nozzles 116a.

In addition, a perforated plate 128 is disposed in the bottom area of the combustion chamber 102, and a stirring unit 130 in which a plurality of holes is formed is disposed under the supply pipe 110. The stirring unit 130 is formed in a streamlined structure to prevent the incineration treatment in the combustion chamber 102 from being biased to one side, and increases the contact surface with air to enable complete combustion.

A heat recovery device 104 is connected to one side of the combustion chamber 102 by a circulation pipe 148 to recover heat from the high temperature in the combustion chamber 102 and supply it to the combustion chamber 102 to minimize heat loss. . Therefore, the thermal efficiency of the combustion chamber 102 is increased by the heat recovery device 104. The feed pipe 150 is disposed in the circulation pipe 148 to allow high-temperature exhaust gas to circulate rapidly. 152 shown in the drawing serves to block the circulation pipe 148 when the lid 112 is opened as a valve.

In addition, since the exhaust gas of the combustion chamber 102 flowing into the circulation pipe 148 is a gas from which air pollutants are removed by the dust collector 300, the inside of the combustion chamber 102 is not polluted by the exhaust gas that is circulated. .

The lower part of the combustion chamber 102 is provided with a water-reducing portion 132, a belt 142, a driving motor 144, and a blowing fan 126 to rotate the stirring portion 130, and within the combustion chamber 102. Inject air.

In addition, the thermoelectric elements 400 are disposed along the outer wall circumference of the combustion chamber 102, and the thermoelectric elements 400 are connected to the electric control device 280. The electric control device 280, as shown in Figure 5b, the electrical storage unit 281 for storing the electricity supplied to the thermal elements 400 and the electricity supplied to the thermal elements 400 or the And an electricity supply control unit 282 that controls supply of electricity supplied from the electricity storage unit 281 to the outside.

In the present invention, it has been mainly described that the thermoelectric elements 400 are disposed along the outer wall of the combustion chamber 102, but this is not a fixed design structure. Accordingly, the thermoelectric elements 400 may be disposed not only around the outer wall of the combustion chamber, but also on the upper or lower side where the lid is disposed, and in some cases, may be disposed on the inner wall and the bottom of the combustion chamber 102.

In the present invention, high-temperature heat is generated while the incineration treatment is incinerated in the combustion chamber 102. Electricity is generated using the heat, and the generated electricity can be supplied to a home or industrial complex. Content related to this will be described in more detail in FIGS. 5A and 5B.

A dust collector 300 is disposed on the lead 112 of the combustion chamber 102. The dust collector 300 may be formed integrally with the lead 112.

The dust collector 300 is air pollutants contained in the exhaust gas discharged through the lead 112 of the combustion chamber 102, for example, NOx, Sox, HCL, dioxin, and fly ash, which are various harmful substances contained in the exhaust gas Remove (FLY ASH). The exhaust gas thus removed is supplied to the heat recovery device 104 through the circulation pipe 148 and then re-supplied to the combustion chamber 102 to improve the thermal efficiency in the combustion chamber 102. This will be described in detail in FIGS. 6 and 7.

In addition, a residue removal device 180 may be disposed between the combustion chamber 102 and the water storage unit 132. The residue removing device 180 collects unburned residue after the waste is burned in the combustion chamber 102, and then automatically removes the residue by the control of the control unit 108. 8 and 9A to 9C will be described in detail.

As described above, in the incineration system capable of cogeneration in accordance with the present invention, nozzles disposed in the supply pipe located at the center of the combustion chamber randomly blow out air, thereby sufficiently supplying air to all areas of the combustion chamber to improve incineration efficiency. It has an improved effect.

In addition, the incineration system capable of combined heat and power generation according to the present invention has an effect of reducing the incineration residue generated in the incineration process by continuously stirring the waste (incineration products) in the incineration process in the combustion chamber.

In addition, the incineration system capable of cogeneration in accordance with the present invention has an effect of automatically removing incineration residues according to a size according to a command of a control device.

In addition, the incineration system capable of combined heat and power generation according to the present invention removes air pollutants contained in the exhaust gas discharged from the combustion chamber by a dust collecting device disposed on the lead of the combustion chamber and recovers the high temperature exhaust gas again to the combustion chamber. By supplying it has the effect of improving the thermal efficiency of the combustion chamber.

In addition, the incineration system capable of combined heat and power generation according to the present invention has an effect of arranging a plurality of thermoelectric elements along the periphery of the combustion chamber and collecting and supplying electricity generated by the thermoelectric elements to utilize thermal energy as electric energy. .

2 is a view showing the structure of a supply pipe and a fuel nozzle of an incineration system capable of cogeneration according to the present invention, FIG. 3 is an enlarged view of area A of FIG. 2, and FIG. 4 is a cogeneration according to the present invention This is a diagram showing the air flow inside the combustion chamber of a possible incineration system.

Referring to FIGS. 2 to 4 together with FIG. 1, in the incineration system 100 capable of cogeneration in accordance with the present invention, the supply pipe 110 is disposed in the center of the combustion chamber 102. The supply pipe 110 increases the combustion efficiency by forcing air into the combustion chamber 102.

In the air supply pipe 110, nozzle portions 116 are disposed in the upper region, the central region, and the lower region, respectively, in the vertical direction. In addition, a fuel supply pipe 114 that receives fuel from the fuel supply device 106 and supplies fuel inside the combustion chamber 102 extends along the inner circumferential surface of the combustion chamber 102 above the supply pipe 110. Here, a plurality of fuel injection nozzles 118 are disposed at equal intervals.

Therefore, fuel can be uniformly supplied from the upper direction to the combustion chamber 102 through the fuel supply pipe 114 and the fuel injection nozzle 118. In the drawing, the fuel supply pipe 114 and the fuel injection nozzle are disposed above the combustion chamber 102, but this is not fixed. Therefore, it may be disposed on the inner circumferential side and the bottom surface of the combustion chamber 102. The fuel used in the present invention may be liquid fuel of waste oil or oil.

Referring to FIG. 3, the nozzle unit 116 disposed on the air supply pipe 110 includes a plurality of air injection nozzles 116a (A region). The air injection nozzles 116a are arranged in a circular shape along the outer circumferential surface of the air supply pipe 110, and the nozzle unit 116 may further include a rotating motor. The air injection nozzles 116a may move in different directions from adjacent nozzles to randomize the air injection direction in the combustion chamber 102. That is, the air injection nozzle 116a sprays air in a different direction from the adjacent air injection nozzle.

As shown in the figure, when the air injection nozzle 116a is operated, each of the air injection nozzles moves in a different direction from adjacent nozzles to allow air injection to circulate through the entire area of the combustion chamber 102.

Therefore, the air injection nozzles 116a may be driven by a rotating motor to move in a random direction.

Referring to FIG. 4, the air supply pipe 110 disposed in the center of the combustion chamber 102 injects air through the nozzles 116 respectively disposed in the upper region and the lower region of the central region. Looking at the direction of the injected air, it can be seen that air is also injected in the horizontal direction around the nozzle unit 116 and in the vertical direction based on the horizontal direction. Accordingly, air forcibly injected into the combustion chamber 102 is circulated through the entire area to increase combustion efficiency.

As described above, when the combustion rate in the combustion chamber 102 increases, there is an effect of reducing residues and harmful substances contained in exhaust gas generated by incineration treatment (waste) combustion.

Meanwhile, in the incineration process, powder may be generated depending on the end of the incineration treatment. In particular, in the process of burning animal carcasses or various bones, debris may be generated. The pulverized powder may not be completely burned and may be introduced into the air outlet of the air injection nozzle 116a while floating in the incinerator during the incineration process. Such a powder may block the air outlet of the air injection nozzle 116a to prevent smooth air discharge. To solve this problem, according to some embodiments, the injection pressure of air injected through the air injection nozzle 116a may be periodically increased. That is, the air injection pressure is increased for a predetermined period of time so that air can be rapidly output through the nozzle 116a. For example, air may be discharged at a first speed through the nozzle 116a, and then air may be discharged at a second speed faster than the first speed for a predetermined time at a specific time, and then air is discharged again at a first speed. Can be. Due to the high speed of air discharge, powder accumulated in the air discharge hole of the nozzle 116a may be discharged into the incinerator.

5A is a view for explaining the principle of generating electricity by a thermoelectric element of an incineration system capable of cogeneration, according to the present invention, and FIG. 5B is a structure of an electric control device for collecting and managing electricity generated in the thermoelectric element of FIG. 5A It is a diagram showing.

Referring to FIGS. 5A and 5B together with FIG. 1, in general, a thermoelectric element generally refers to an element that converts heat into electricity or obtains thermal energy by flowing a current. For example, the thermoelectric element is a thermistor, which is a thermoelectric element using a temperature change of electrical resistance, a thermoelectric element that uses the Seebeck effect, which is a phenomenon in which electromotive force is generated by a temperature difference, and a Peltier effect, which is a phenomenon in which heat is absorbed by a current. There is a Peltier element, a thermoelectric element. The types are divided into Mg2Si, Zn4Sb3, AgSbTe2, and Bi2Te3.

In the present invention, a description will be given focusing on a thermoelectric element using the Seebeck effect of converting the high temperature of the combustion chamber 102 into electrical energy among these thermoelectric elements.

The thermoelectric element 400 is divided into a semiconductor layer that converts thermal energy into electricity between an electrode in contact with high temperature heat and an electrode generating electricity. The principle of moving electrons from the electrode in the high temperature region to the electrode in the low temperature region is higher than that of the electrode in the semiconductor layer adjacent to the electrode in contact with the high temperature heat, because the average kinetic energy of the electron is high.

In the present invention, when a current is generated in a thermoelectric element due to high heat in the fuel chamber 102, it is connected to incubation (LOAD) of an electric device, a heating device, and the like, and has a feature of using thermal energy as electrical energy.

The electrical control device 280 controls the supply of electricity generated from the electrical storage unit 281 and the thermoelectric element 400, such as an ESS (Energy Storage System), or electricity supplied from the electrical storage unit 281 to the outside. It includes an electricity supply control unit 282.

Therefore, the incineration system capable of cogeneration is capable of storing or generating high-temperature heat generated during combustion of the incineration treatment in the form of electrical energy so that it can be supplied to a heating device or industrial equipment for heating. Improved energy efficiency.

6 is a view showing the structure of a dust collecting device in an incineration system capable of cogeneration power generation according to the present invention, and FIG. 7 is a view for explaining the dust collection principle of a dust collecting device in an incineration system capable of cogeneration power generation according to the present invention.

Referring to FIGS. 6 and 7 together with FIG. 1, the incineration system 100 capable of combined heat and power generation according to the present invention is integrated with or separated from the lead 112 disposed on the upper side of the combustion chamber 102 to collect the dust collector 300 ) Is placed.

An exhaust part 303 capable of discharging high temperature exhaust gas after the waste is burned is disposed above the combustion chamber 102, and the exhaust part 303 is connected to the dust collector 300. In addition, an exhaust unit 305 for discharging exhaust gas, which has been subjected to the exhaust gas dust collection process, is disposed on one side of the dust collector 300, and the exhaust unit 305 may be connected to the circulation pipe 148.

As illustrated in FIG. 7, the dust collecting device 300 of the present invention includes a centrifugal collecting part 310 for collecting dust contained in exhaust gas, and exhaust gas from which the collecting process is completed in the centrifugal collecting part 310. It may include a dust collecting reaction unit 320 for removing fine dust and a catalyst unit 330 for removing nitrogen oxides from the exhaust gas that has passed through the dust collecting reaction unit 320.

The centrifugal collecting part 310 includes a blade with a rotary blade and a guide tube for collecting dust to collect dust contained in exhaust gas of the combustion chamber 102 supplied through the exhaust part 303 can do. Therefore, while the exhaust gas passes through the wing, dust is separated from the exhaust gas and the separated dust is collected through the induction pipe.

As described above, when dust is primarily removed from the exhaust gas, the exhaust gas passes through a filter disposed in the dust collection reaction unit 320. The filter reacts with harmful substances such as dioxins, NOx and SOx contained in the exhaust gas and removes fine dust.

Then, as the exhaust gas passes through the catalyst unit 330 through which ammonia gas is introduced, nitrogen oxides contained in the exhaust gas are removed.

As described above, when harmful substances in the exhaust gas generated after burning the waste are removed, they are supplied to the heat recovery device 104 shown in FIG. 1 to improve the thermal efficiency of the combustion chamber 102. In particular, in the present invention, since the recovered exhaust gas is clean exhaust gas at a high temperature by the dust collector 300, secondary pollution of the combustion chamber 102 that may be generated in the heat recovery process can be removed.

8 is a view showing the structure of a residue removal device of an incineration system capable of cogeneration in accordance with the present invention, and FIGS. 9A to 9C are residues of a residue removal device of an incineration system capable of cogeneration in accordance with the present invention. It is a diagram for explaining the removal process.

Referring to FIGS. 8 to 9C together with FIG. 1, the incineration system 100 capable of cogeneration in accordance with the present invention, after incinerating the waste, a residue removal device for removing residues remaining in the combustion chamber 102 It may include (180).

The residue removing device 180 includes a residue holder 180a for collecting fine residues according to the size of the residue, a mesh portion 180b for filtering large residues, and residues collected in the residue holder 180a It includes an intake unit (180c) for removing. The residue removing device 180 is automatically operated after the waste incineration process is completed by the control of the control device 108 to remove the collected residue from the combustion chamber 102.

The operation of the residue removal device 180 is as follows.

When the waste incineration treatment is completed in the combustion chamber 102, the residue removal device 180 is slid according to the command of the control unit 108 to protrude outward from one side of the combustion chamber 102.

The residue removal device 180 has a structure in which a residue holder 180a with one side open and a separated mesh portion 180b disposed in an open area are assembled. Since the mesh portion 180b is configured with a mesh network so that the large diameter residue P2 can be filtered, large residue P2 remains on the mesh network.

In addition, the small sized residue P1 that has passed through the mesh portion 180b is located in the residue holder 180a. When the residue removing device 180 is slid outward from the combustion chamber 102 by the command of the control device 108, the mesh portion 180b is first inclined at a predetermined angle, and the residue remaining in the mesh network ( P2) is removed by gravity. At this time, the mesh network may be vibrated at predetermined time intervals to facilitate removal of residues.

As described above, when the residue in the mesh portion 180b is removed, the small-diameter residue collected in the residue holder 180a is removed by the operation of the intake portion 180c.

As described above, in the present invention, after the residue generated in the waste incineration process is automatically removed using the control device 108 and the residue removal device 180, the incineration residue is managed by sliding again to the lower side of the combustion chamber 102. There is an effect that can be easily.

In the incineration system capable of cogeneration in accordance with the present invention, the nozzles disposed in the supply pipe located in the center of the combustion chamber randomly blow out air, thereby sufficiently supplying air to all areas of the combustion chamber to improve incineration efficiency. There is.

In addition, the incineration system capable of cogeneration power generation according to the present invention has an effect of reducing the incineration residue generated in the incineration process by continuously stirring the waste (incineration products) in the incineration process in the combustion chamber.

In addition, the incineration system capable of cogeneration in accordance with the present invention has an effect of automatically removing incineration residues according to a size according to a command of a control device.

In addition, the incineration system capable of cogeneration in accordance with the present invention, by removing the air pollutants contained in the exhaust gas discharged from the combustion chamber by a dust collecting device disposed on the lead of the combustion chamber to recover the high-temperature exhaust gas again to the combustion chamber By supplying it has the effect of improving the thermal efficiency of the combustion chamber.

In addition, the incineration system capable of combined heat and power generation according to the present invention has an effect of arranging a plurality of thermoelectric elements along the periphery of the combustion chamber and collecting and supplying electricity generated by the thermoelectric elements to utilize thermal energy as electric energy. .

The above description and the accompanying drawings are merely illustrative of the technical spirit of the present invention, and those of ordinary skill in the art to which the present invention pertains combine combinations of configurations without departing from the essential characteristics of the present invention. , Various modifications and variations such as separation, substitution and change will be possible. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments. The scope of protection of the present invention should be interpreted by the claims below, and all technical spirits within the scope equivalent thereto should be interpreted as being included in the scope of the present invention.

100: incineration system 102: combustion chamber
104: heat recovery device 106: fuel supply device
108: control device 110: supply pipe
112: lead 114: fuel supply pipe
126: blowing fan 144: driving motor
158: temperature sensor 148: circulation pipe
180: residue removal device 280: electrical control device
281: electricity storage unit 282: electricity supply control unit
300: dust collector
400: thermoelectric element

Claims (6)

A combustion chamber to isolate the input waste from the outside;
An air supply pipe disposed in the center of the combustion chamber to inject air into the combustion chamber;
A stirring part rotating the supply pipe below the combustion chamber as a fixed shaft;
A plurality of thermoelectric elements disposed along the periphery of the combustion chamber;
An electric control device that regulates collecting or supplying electricity generated by the thermoelectric elements to the outside;
A dust collecting device disposed above the fuel chamber and arranged to remove fine dust and air pollutants contained in exhaust gas discharged from the combustion chamber;
An exhaust unit connecting the combustion chamber and the dust collector;
It is disposed under the fuel chamber to classify incineration residues according to the size during incineration processing in the fuel chamber, and after the incineration treatment is completed, remove residues that are withdrawn outward from the fuel chamber to remove residues Device;
A heat recovery device disposed on one side outside the combustion chamber and supplying exhaust gas discharged from the dust collector to the lower portion of the combustion chamber to recirculate in the combustion chamber; And
It includes a control device for controlling the combustion chamber, air injection of the supply pipe, agitator, electric control device, dust collecting device and residue removal device,
The heat recovery device includes a circulation pipe connected to the dust collector,
The electric control device includes an electric storage unit for storing electricity generated by the thermoelectric element, and an electric supply control unit for controlling supply of electricity generated by the thermoelectric element or electricity supplied from the electric storage unit to the outside,
The dust collecting device includes a centrifugal collecting part for collecting dust contained in the exhaust gas supplied through the exhaust part,
Dust collection reaction unit for removing the fine dust from the exhaust gas is collected in the centrifugal trapping process is completed,
And a catalyst unit for removing nitrogen oxides from the exhaust gas that has passed through the dust collection reaction unit.
The dust collecting device further comprises an exhaust part that supplies exhaust gas to the circulation pipe after the exhaust gas is collected.
The dust collecting device receives exhaust gas through the exhaust part disposed on the upper side of the combustion chamber, and then discharges exhaust gas through the exhaust part to the circulation pipe after the dust collection process is performed.
An incinerator system with integrated dust collector capable of cogeneration. delete According to claim 1,
The air supply pipe is capable of generating power, characterized in that a nozzle portion is disposed in an upper region, a central region, and a lower region, and the nozzle portion is composed of a plurality of air injection nozzles along the periphery of the air supply pipe.
The plurality of air injection nozzles are an incineration system of an integrated dust collector capable of cogeneration by spraying air in different directions from adjacent air injection nozzles. delete According to claim 1,
The residue removing device includes a mesh part for filtering residues having a relatively large size,
A residue holder for collecting residues of relatively small size,
It includes an intake portion for removing the residue remaining in the residue holder in an intake manner
The mesh part of the residue removal device, after withdrawing from the combustion chamber, is inclined at a predetermined angle and vibrates at regular intervals to remove residues remaining in the mesh part. According to claim 1,
The incineration system further includes a fuel supply device for supplying fuel to the combustion chamber
A fuel supply pipe for supplying fuel supplied from the fuel supply device to the inside of the combustion chamber is disposed above the fuel chamber, and a plurality of fuel injection nozzles are disposed at equal intervals in the fuel supply pipe to enable cogeneration. Incinerator system with integrated dust collector.

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