KR102210782B1 - Rotary Incinerator - Google Patents

Abstract

The present invention provides a rotary incinerator capable of improving the incineration performance while improving the reduction performance of harmful gases. According to the present invention, the rotary incinerator comprises: an incinerator in which a burner is installed at one end and a waste input portion is connected to the other end, and the waste supplied through the waste input portion is transferred to the burner side while rotating inside to be incinerated; an exhaust unit communicating with the incinerator to forcibly exhaust combustion gas generated inside the incinerator; a dust collecting unit installed between the incinerator and the exhaust unit to remove foreign substances contained in the combustion gas; and a cooling unit disposed between the dust collecting unit and the incinerator to cool the supplied combustion gas.

Description

Rotary Incinerator {Rotary Incinerator}

The present invention relates to a rotary incinerator, and more particularly, to a rotary incinerator for incineration while moving the input waste through a rotating incinerator.

In general, incineration devices are applied in various fields. For example, a waste incinerator is used to burn and treat various household and industrial wastes as well as even waste livestock carcasses.

With the development of various industries in recent years, not only industrial wastes but also various kinds of wastes such as household wastes are generated in large quantities along with the improvement of the standard of living, becoming a major factor of environmental pollution.

Some of these wastes are recyclable, but most are landfilled or incinerated. Meanwhile, as an incinerator for incineration of waste, a vertically arranged incinerator was used. Such a vertically arranged aqueduct has the following problems.

First of all, the conventional vertical array incinerator has a problem that the incinerator and dust collector are easily oxidized or corroded by heat, which shortens the life of the device. It is difficult to reduce the size of the device and the size of the facility becomes large. During incineration, a large amount of toxic gases such as dioxins are generated, and the technology to effectively reduce them is insufficient.

Meanwhile, in the related art, a horizontal incineration apparatus is also disclosed. The conventional horizontal incineration apparatus is provided in a structure in which the incinerator and the dust collector are in communication with each other through a transfer pipe and a heat recovery pipe.

Specifically, the incinerator includes a conveyor through which waste is transferred and a hopper into which the waste is put. In addition, a blower and a burner are mounted on one side of the incinerator, and the blower and burner are driven through a distribution board. Meanwhile, a collection plate having a certain inclination is mounted inside the incinerator, and the completely incinerated ash is discharged through the suction hole in the center.

In addition, a combustion chamber is formed inside the dust collecting furnace, and a burner is mounted on one side to burn waste in the combustion chamber. A plurality of barrier walls are mounted inside the combustion chamber, and a number of light oil holes are formed in the barrier walls.

In the conventional waste apparatus having such a configuration, the incineration process of the waste and the process of collecting and decomposing toxic gases generated during incineration are simultaneously performed. Therefore, the conventional waste incineration apparatus has a limitation in improving incineration performance as a configuration that depends only on the thermal power of the burner. In addition, when incineration of waste livestock or waste with high moisture content, the burner's thermal power incinerates only the surface (outer) of the waste in the form of lumps, and the incineration heat cannot be transferred to the inside. Problems that are difficult to incinerate are often raised.

In addition, since the conventional waste incineration system relies on the burner's thermal power to incinerate the waste, the fuel cost is relatively high due to the continuous operation of the burner during incineration, and furthermore, the incineration ash (carbonized ash) generated by incomplete combustion during incineration It is difficult to treat, and it is difficult to purify harmful gases (dioxin, soot from incomplete combustion, etc.) contained in the combustion gas.

<Prior literature 1>: Republic of Korea utility model registration No. 0184761 (announcement date: June 1, 2000)

The present invention has been invented to solve the above problems, and an object of the present invention is to provide a rotary incineration apparatus capable of improving incineration performance while also improving the reduction performance of harmful gases.

According to an embodiment of the present invention for achieving the above object, a burner is installed at one end and a waste input unit is connected to the other end, so that the waste supplied through the waste input unit is rotated inside and transferred to the burner side and incinerated. incinerator; An exhaust part communicating with the incinerator to forcibly exhaust the combustion gas generated inside the incinerator; A dust collecting unit installed between the incinerator and the exhaust unit to remove foreign substances contained in the combustion gas; And a cooling unit disposed between the dust collecting unit and the incinerator to cool the supplied combustion gas.

Inside the incinerator, a plurality of transfer blocks are arranged in a spiral shape to transfer the waste to the burner, and the exhaust unit is connected in a direction opposite to the burner to forcibly exhaust the combustion gas in a direction opposite to the transfer direction of the waste. Can be.

The incinerator, a drying area formed in a partial area of the incinerator in which the waste input unit is installed to dry the inputted waste, an incineration area formed in a partial area of the incinerator in which the burner is installed to incinerate the moved waste, and the It may include a gasification region formed between the drying region and the incineration region to generate combustion gas while the waste is burned.

It may further include an outside air supply unit disposed on the outer circumference of the incinerator at regular intervals to supply outside air to the inside of the incinerator.

The outside air supply unit may include a supply channel pipe formed in an annular shape on an outer peripheral surface of the incinerator and supplied with the outside air; It may include a supply line connected by the supply channel pipe and vertically connected to the inside of the incinerator.

According to the present invention, incineration is performed while moving the input waste in one direction by placing a transfer block in a spiral on the inner circumference of the rotating incinerator, and configured to forcibly exhaust the combustion gas inside the incinerator through the exhaust pipe, and the drying process Since the over-incineration process is performed in one incinerator, there is an effect of securing high incineration performance even for waste with high moisture content.

In addition, since it is possible to utilize the combustion heat of combustion gas as well as the burner's thermal power in the incinerator, harmful substances such as dioxins and soot generated during the waste incineration process are extinguished by high-temperature heat and can be discharged to the outside through a dust collection process. There is an effect that can prevent contamination.

1 is a schematic configuration diagram of a rotary incineration apparatus according to an embodiment of the present invention,
2 is a plan view of a rotary incineration apparatus according to an embodiment of the present invention,
Figure 3 is a state diagram showing the installation state of the outside air supply unit of the rotary incinerator according to an embodiment of the present invention,
Figure 4 is a cross-sectional view showing the internal configuration of the rotary incineration apparatus according to an embodiment of the present invention, and
5 is a partially enlarged view showing the configuration of an external air supply unit of a rotary incinerator according to an embodiment of the present invention.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings. Prior to this, terms or words used in the specification and claims should not be construed as being limited to their usual or dictionary meanings, and the inventors appropriately explain the concept of terms in order to explain their own invention in the best way. Based on the principle that it can be defined, it should be interpreted as a meaning and concept consistent with the technical idea of the present invention. In addition, unless otherwise defined, technical terms and scientific terms used have the meanings commonly understood by those of ordinary skill in the art to which this invention belongs. In the following description and accompanying drawings, descriptions of known functions and configurations that may unnecessarily obscure the subject matter of the present invention will be omitted. The accompanying drawings are provided as an example in order to sufficiently convey the spirit of the present invention to those skilled in the art. Accordingly, the present invention is not limited to the drawings presented below and may be embodied in other forms. In addition, the same reference numbers throughout the specification indicate the same elements. It should be noted that the same elements in the drawings are indicated by the same reference numerals wherever possible.

First of all, rotary incinerators were often used for drying, which is a pre-incineration process rather than incineration treatment. For complete incineration, the diameter of the incinerator must be increased or the length of the incinerator must be lengthened, so there is a problem in that installation cost is greater than incineration efficiency. In addition, if the incinerator is lengthened, it is difficult to supply combustion air to the inside of the incinerator, so incomplete combustion occurs and foreign substances (soot, etc.) are generated inside the incinerator, which causes a problem that creates a load or clogs the dust collection facility. .

To this end, the rotary incineration apparatus of the present invention provides the following technical considerations. Referring to Figure 1, the rotary incinerator of the present invention is formed in a cylindrical incinerator 50 is configured to rotate by a drive motor. Specifically, the cylindrical incinerator 50 on the base frame 100 installed on the ground as shown in FIG. 3 is configured to rotate in one direction.

Meanwhile, in the incinerator 50, as shown in FIG. 1, a burner B for supplying thermal power into the incinerator 50 is installed at the front end side. In addition, a waste input unit 60 is connected to the end of the incinerator 50. At this time, the waste input unit 60 may crush and supply various wastes.

In addition, inside the incinerator 50, a plurality of transfer blocks 51 are arranged in a spiral shape as shown in FIG. 4. Accordingly, when the incinerator 50 is rotated in one direction, the wastes injected therein are moved to one side (the left side of the incinerator based on FIG. 1) by these transfer blocks 51. That is, the waste supplied through the waste input unit 60 has a conveying direction D1 of the waste conveyed to the burner B side by the conveying block 51 inside the rotating incinerator 50.

Meanwhile, a plurality of retarding blocks 52a and 52b are formed in a region in which the burner B is installed in the incinerator 50. Specifically, the delay blocks 52a and 52b are disposed in a circular band in the incinerator 50, respectively, and the installation intervals are narrower than the transfer blocks 51.

Therefore, the transfer block 51 arranged in a spiral shape serves to transfer the inputted waste in one direction, whereas the retard blocks 52a and 52b transfer the transferred waste to be exposed to the front of the burner (B) for a longer period of time. It plays a role in slowing down the speed. Accordingly, the incineration efficiency can be further improved by exposing the waste transferred to the burner (B) to the flame of the burner (B) for a longer period of time.

At this time, on one side of the incinerator 50 in which the burner (B) is installed, an incineration ash discharge unit 56 (FIG. 4) from which completely incinerated ash is discharged is formed. In addition, temperature sensors S1 and S2 are installed on both walls of the incinerator 50 to measure the internal temperature to control the operation of the burner B.

Meanwhile, an exhaust pipe 70 is connected to the front end side of the incinerator 50 (the side wall opposite to the side wall of the burner installation end). An exhaust part 90 is connected to the exhaust pipe 70 to forcibly exhaust the combustion gas inside the incinerator 50. At this time, the combustion gas inside the incinerator 50 has a moving direction D2 of the combustion gas from the burner B side toward the exhaust part 90.

That is, as shown in FIG. 1, the moving direction D1 of the waste and the moving direction D2 of the combustion gas are opposite to each other. Accordingly, the waste supplied through the waste input unit 60 is first dried by an incinerator (high temperature combustion gas) exhausted from the drying area A1 side of the incinerator 50, and then the transfer block 51 ), the wastes are gradually conveyed toward the burner (B), and the wastes start to be burned by the flame of the burner, thereby forming combustion gas (gasification zone; forming A2).

Wastes passing through this gasification zone (A2) are incinerated directly in front of the burner (B) to complete incineration (especially in the retard block; complete combustion in 52a, 52b), and the completely incinerated ash is discharged from the incinerator ( 56) is discharged to the outside of the incinerator 50.

As described above, the rotary incineration apparatus of the present invention constitutes a drying area (A1) and an incineration area (A3) inside the incinerator 50, and a drying process is performed prior to the input waste, and then the incineration process is performed. Even when waste and inorganic waste are mixed, smooth incineration performance can be expected. In other words, high incineration performance can be expected even for waste with high moisture content.

In addition, since the heat of combustion of wastes inside the incinerator 50 can be applied to the drying process or the incineration process, the incineration performance can be significantly improved by utilizing the combustion heat of the waste itself as well as the thermal power of the burner (B).

Meanwhile, on the outside of the incinerator 50, a plurality of external air supply units 65a, 65b, and 65c are disposed at regular intervals. Specifically, in the external air supply units 65a, 65b, 65c, a channel member 67 having a supply channel 68 having a predetermined space therein as shown in FIG. 6 is disposed in an annular strip shape on the outer peripheral surface of the incinerator 50, A supply line 68a communicating from the supply channel 68 and extending through the wall of the incinerator 50 is formed. In addition, a fixing member 66 is installed outside the supply channel 68. At this time, the fixing member 66 is installed in a state fixed to the base frame 100 (FIG. 3), and the channel member 67 is fixedly installed on the outer circumferential surface of the incinerator 50. Accordingly, when the incinerator 50 is rotated, the channel member 67 also rotates. At this time, the channel member 67 is in a state in which portions of both sides are engaged with the fixing member 66 (ie, the supply channel; 68 is sealed). Is configured to rotate.

In addition, as shown in FIG. 3, a supply pipe 61 is connected to the supply channel 68 to supply outside air to the supply channel 68, and the supplied outside air is supplied to the inside of the incinerator 50 through the supply line 68a. Can be. At this time, the supply line 68a is evenly arranged at regular intervals throughout the incinerator 50 so that combustion air required for combustion may be sufficiently and evenly provided to the inside of the incinerator 50.

Referring back to FIG. 1, the first cooling unit 71 is connected to the exhaust pipe 70. Accordingly, primary cooling of the high-temperature combustion gas exhausted from the incinerator 50 is performed. For example, if the temperature of the exhausted combustion gas is about 1100°C, it is cooled to about 800°C. A part of the primary cooled combustion gas in this way is partially recovered to the waste heat recovery pipe 76 through the waste heat recovery unit 75 and provided to the incinerator 50 again. In this way, the present invention can further improve incineration performance by recovering the waste heat exhausted through the waste heat recovery unit 75.

Meanwhile, the remaining part of the combustion gas passing through the waste heat recovery unit 75 is cooled to about 200°C through the second cooling unit 72. The provision of the multi-stage cooling units 71 and 72 as described above is intended to solve the problem of damage to the filter or deterioration of the durability of the device by the high-temperature combustion gas in the subsequent dust collection process. That is, by lowering the high-temperature combustion gas forcibly exhausted from the incinerator 50 to about 200°C through the multi-stage cooling units 71 and 72, it is possible to prevent the problem of damage to the dust collection filter.

In addition, the combustion gas is discharged to the atmosphere through the exhaust unit 90 in a state in which harmful substances (dioxin, soot, etc.) in the combustion gas are removed through the multi-stage dust collecting units 81 and 82.

In this way, the present invention is incinerated while moving the input waste in one direction by arranging the transfer block 51 in a spiral on the inner circumferential surface of the rotating incinerator 50, and through the exhaust pipe 70, the inside of the incinerator 50 It is configured to forcibly exhaust the combustion gas. Accordingly, since the drying process and the incineration process are performed in one incinerator 50, high incineration performance can be secured even for wastes having a high moisture content.

In addition, since it is possible to utilize the combustion heat of the combustion gas as well as the thermal power of the burner (B) in the incinerator 50, harmful substances such as dioxin and soot generated during the waste incineration process are extinguished by high temperature heat. It can be discharged to prevent environmental pollution.

Meanwhile, when the incineration process of the present invention is described as an example, first, the burner B is operated to preheat the temperature in the incinerator 50 to, for example, 1000°C. After preheating, when the waste is put into the inside of the incinerator 50, the incinerator 50 rotates and the inputted waste is transferred in one direction to incinerate. At this time, the waste is first dried in the drying area (A1), followed by partial combustion in the gasification area (A2) and complete incineration in the incineration area (A3), and the incineration ash generated at this time is the incineration ash discharge unit 56 ) Through.

Meanwhile, the combustion gas generated in the incineration process has a flow that is forcibly exhausted to the exhaust pipe 70. Accordingly, the high-temperature combustion gas is used in the drying process for the input waste, and helps to increase the overall incineration performance. Therefore, if the high-temperature combustion gas generated in the incineration process is properly controlled, even after the burner B stops operating after the initial preheating, incineration can be performed using its own combustion heat. Accordingly, the operating cost of the incinerator can be significantly reduced.

Meanwhile, the combustion gas discharged through the exhaust pipe 70 is discharged to the atmosphere in a state in which harmful substances (dioxin, soot, etc.) contained in the combustion gas are removed through the dust collectors 81 and 82 after the multi-stage cooling process. Can be reduced.

In the above, the present invention has been illustrated and described with respect to specific embodiments, but the present invention is not limited to the above-described embodiments, and those of ordinary skill in the art to which the present invention pertains, the present invention described in the following claims. It will be possible to implement it with any number of various changes without departing from the gist of the technical idea of the invention.

50: incinerator
51: transfer block
52a, 52b: delay block
56: incineration ash discharge unit
60: waste input
61: supply pipe
65a: first outdoor air supply unit
65b: second outside air supply unit
65c: 3rd outside air supply
66: fixing member
67: channel member
68a: supply line
70: exhaust pipe
71a: exhaust port
71: first cooling unit
72: second cooling unit
81: first dust collector
82: second dust collector
90: exhaust
100: base frame

Claims (5)

An incinerator that has a burner installed at one end and a waste input unit connected to the other end, and transfers the waste supplied through the waste input unit to the burner side while rotating inside and incinerates it;
An exhaust part communicating with the incinerator to forcibly exhaust the combustion gas generated inside the incinerator;
A dust collecting unit installed between the incinerator and the exhaust unit to remove foreign substances contained in the combustion gas; And
And a cooling unit disposed between the dust collecting unit and the incinerator to cool the supplied combustion gas,
A plurality of transfer blocks are arranged in a spiral shape inside the incinerator to transfer the waste to the burner side,
The exhaust unit is connected in a direction opposite to the burner to exhaust the combustion gas in a direction opposite to the conveying direction of the waste,
A plurality of retarding blocks arranged in a circular strip shape are installed at regular intervals in a part of the incinerator in which the burner is installed to retard the conveying speed of the inputted waste, and the retarding blocks are installed at regular intervals. The installation gap in the circumferential direction is arranged narrowly,
A plurality of external air supply units supplying external air to the inside of the incinerator are installed on the outer circumferential surface of the incinerator,
The outside air supply unit includes a channel member formed in an annular strip on the outer circumferential surface of the incinerator and provided with a supply channel through which the outside air is supplied, a supply line vertically communicating from the supply channel to the inside of the incinerator, and connected to the outer circumference of the channel member. A rotary incineration apparatus comprising a fixing member. The method of claim 1,
The incinerator,
A drying area formed in a partial area of the incinerator in which the waste input unit is installed to dry the inputted waste,
An incineration area formed in a partial area of the incinerator in which the burner is installed to incinerate the transferred waste, and
And a gasification region formed between the drying region and the incineration region to generate combustion gas while the waste is combusted. delete delete delete

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