KR20210031295A - System for incinerating waste - Google Patents

Abstract

Disclosed is a waste incineration system that can improve incineration performance and increase energy efficiency to relatively lower maintenance costs, improve construction performance, and significantly improve incineration capacity. According to the present invention, the waste incineration system comprises: a waste supply unit for supplying waste; an incinerator in which the waste supply unit is connected to input the waste and rotates the inputted waste toward the burner side; and an exhaust unit connected to the incinerator and exhausting the heat inside the incinerator to the outside. The transport direction of the waste of the incinerator and the exhaust direction of the heat are opposite to each other.

Description

Waste incineration system {System for incinerating waste}

The present invention relates to a waste incineration system, and more particularly, to a waste incineration system that incinerates waste using a rotating incinerator.

In general, a waste incinerator is a device that burns and decomposes various household and industrial wastes to treat them.

In recent years, various industries have been developed and, along with the improvement of living standards, various kinds of wastes such as household wastes and industrial wastes are generated in large quantities, acting as a major factor in polluting the environment.

Some of these wastes are recyclable, but most of them are landfilled or incinerated. In particular, conventional waste incinerators are mainly devices to which a vertically-arranged incinerator is applied, and such a vertically-arranged incinerator has the following disadvantages.

First, conventional vertical incinerators are easily oxidized/corroded by heat, such as incinerators and dust collectors, which shortens the service life, increases the size of the facility, increases the manufacturing cost, and is poisonous such as a large amount of dioxin during incineration. There is a problem of releasing gas.

To this end, conventionally, a waste incinerator to which a horizontal incinerator is applied is disclosed. A conventional waste incineration apparatus includes an incinerator for incineration of waste, and a multi-stage dust collector for burning various toxic gases collected by receiving heat from the incinerator.

1 is a block diagram showing the configuration of a conventional waste incineration apparatus. Referring to FIG. 1, a conventional waste incineration apparatus is installed in a state in which the incinerator 10 and the dust collecting furnace 12 are in communication with each other through a transfer pipe 26 and a heat recovery pipe 30.

Among the above configurations, the incinerator 10 includes a conveyor 20 through which waste is transferred and a hopper 18 into which the waste is introduced. In addition, a blower 16 and a burner 14 are mounted on one side of the incinerator 10, and the blower 16 and the burner 14 are driven through the distribution board 40. A collection plate 22 having a certain inclination is mounted inside the incinerator 10, and the incinerated ash is stored in the lower part through the suction holes 42, 34, and 32 in the center.

Meanwhile, the dust collecting furnace 12 has a combustion chamber 24 therein, and a burner 14 is mounted on one side thereof to perform combustion therein. In addition, a plurality of barrier walls 28 are mounted in the combustion chamber 24, and a plurality of light oil holes 36 are formed in the barrier walls 28.

The conventional waste incineration apparatus configured as described above can simultaneously proceed with the incineration process of waste and the process of collecting and decomposing toxic gases generated during incineration by combustion. Therefore, there is a problem in that the incineration efficiency is deteriorated because only the incineration of waste is performed.

In addition, for wastes having a high moisture content, incineration on the outside of the waste may be performed, but heat cannot be transmitted to the inside and carbonized, resulting in a problem that it is difficult to secure good incineration performance.

In addition, in the conventional waste incineration apparatus, since the waste is incinerated by relying on the thermal power of the burner 14, the problem of lowering efficiency has been raised due to relatively high maintenance costs such as fuel costs.

<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 provides a waste incineration system that can improve incineration performance and increase energy efficiency to relatively lower maintenance costs, improve construction performance, and significantly improve incineration capacity. It aims to do.

According to an embodiment of the present invention for achieving the above object, a waste supply unit for supplying waste; An incinerator that is connected to the waste supply unit to insert the waste and moves the inputted waste toward the burner while rotating it therein; And an exhaust unit connected to the incinerator and exhausting heat from the inside of the incinerator to the outside, wherein the conveying direction of the waste and the exhausting direction of the heat of the incinerator are opposite to each other.

The incinerator is formed in the vicinity of a location where the waste is put into, and is formed in a drying area in which the waste is dried by heat transmitted through the burner, and the incinerator is formed in the vicinity of the burner and is transported inside the incinerator and passes through the drying area. Thus, it may be made including an incineration area in which the dried waste is directly incinerated.

In the incineration zone, the waste is incinerated by the thermal power of the burner, and on/off control of the burner is performed by sensing a temperature of the incineration zone.

At least one retarding block for slowing the transfer speed of the waste may be formed in the incineration area.

The incinerator may be provided with a combustion air supply unit installed at predetermined intervals along a length direction of the incinerator to supply combustion air into the incinerator.

In the incinerator, a plurality of guide blocks are arranged to form a spiral so as to transfer the waste toward the burner, and the guide blocks are made of refractory bricks to store heat inside the incinerator, and when the waste is transferred by rotation of the incinerator It can be something that provides a lasting impact.

The combustion air supply unit is a fixed plate fixed along the outer circumferential surface of the incinerator, a moving plate rotatably connected through a connecting rib with the fixed plate and provided with a channel space portion for moving combustion air therein, and the moving plate is communicated at the tip of the incinerator. It may be made including an extension line communicating to the inner circumferential surface of the incinerator.

According to the present invention, the direction of movement of the waste injected into the incinerator and the direction of heat generated from the burner are opposite to each other, so that the drying and incineration of the waste are performed together, thereby improving overall incineration performance. In addition, combustion efficiency can be improved by providing sufficient combustion air to the entire interior of the incinerator. In addition, by installing a retarding block inside the incinerator, sufficient incineration performance can be expected even for waste with high moisture content.

1 is a block diagram showing the configuration of a conventional waste incineration apparatus,
2 is a perspective view of a waste incineration system according to an embodiment of the present invention,
3 is a plan view of a waste incineration system according to an embodiment of the present invention,
4 is a perspective view showing a waste incineration system according to an embodiment of the present invention from the front,
5 is a partially enlarged view of an enlarged internal configuration of an incinerator of the waste incineration system according to an embodiment of the present invention;
6 is a partial enlarged view of an enlarged internal configuration (burner side) of the incinerator of the waste incineration system according to an embodiment of the present invention;
7 is a partial cross-sectional view showing a configuration of a combustion air channel of a waste incineration system according to an embodiment of the present invention, and
8 is a partial cross-sectional view showing an exhaust state of incineration heat of the waste incineration system 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, a description 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 examples 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 components in the drawings are denoted by the same reference numerals wherever possible.

2 and 3, the present invention includes a waste supply unit 60, an incinerator 50, and an exhaust unit 110 (see FIG. 8).

In the above configuration, the waste supply unit 60 is connected to the storage 61 in which waste is stored, as shown in FIG. 4, the transfer conveyor 62 through which the waste stored in the storage 61 is transferred, and the transfer conveyor 62 It is made, including a hopper (63) for putting waste into the incinerator (50).

Meanwhile, a burner B is mounted on the end side of the incinerator 50 as shown in FIG. 2, and an air supply unit 70 is connected to supply combustion air into the incinerator 50. At this time, a first supply pipe 71 for providing combustion air to the burner B and a second supply pipe 72 for supplying combustion air into the incinerator 50 are branched to the air supply unit 70.

In addition, in the incinerator 50 in which the burner (B) is installed, a plurality of cooling supply pipes (75a, 75b) are installed to cool the heat generated in the incineration process to a certain range. In addition, the incinerator 50 is automatically rotated in a predetermined direction by a motor connected to the driving gear unit 51. At this time, for smooth rotation of the incinerator 50, guide portions 53a and 53b are formed on the outer circumferential surface of the incinerator 50, and the guide portions 53a and 53b include a first roller R1 and a second roller R2. It is seated on the top and serves to guide the rotation of the incinerator 50.

In addition, combustion air channels 52a are formed on the outer circumferential surface of the incinerator 50 at regular intervals. At this time, the combustion air channel 52a serves to supply smooth combustion air to the entire section of the incinerator 50 formed to have a predetermined length. That is, the distribution supply pipe 74 is connected to the combustion air channels 52a and 52b, respectively, so that combustion air supplied through the main supply pipe 73 can be widely provided to the inside of the incinerator 50.

Referring to FIG. 8, the incinerator 50 includes a drying area for removing moisture from an input waste and an incineration area for incineration of the dried waste by being transported from the inside of the incinerator 50.

Specifically, a plurality of guide blocks 92 are formed in the incinerator 50 so as to form a spiral. Accordingly, when the incinerator 50 is rotated, the input waste moves along the guide block 92 toward the burner B. At this time, the internal heat of the incinerator 50 has a flow in a direction opposite to the movement direction of the waste through the exhaust unit 110 (flow in the direction of the arrow in FIG. 8 ).

Meanwhile, the waste injected into the supply unit 60 has a drying process in the first certain section due to the heat of the burner (B). That is, the waste containing moisture is dried through the heat of the burner (B). The waste is dried for a certain period by applying heat from the burner (B) to the waste input as described above, and the waste that is moved along the guide block 92 is part of the waste after the drying state depending on the moisture content of the individual waste. It is ignited and has an incineration process. At this time, the heat of self-ignition of the waste serves to further increase the heat inside the incinerator, thereby increasing the incineration performance of the incinerator 50.

In addition, a plurality of retarding blocks 91 are provided inside the incinerator 50. The retarding block 91 is installed in a different arrangement pattern and installation interval from the guide block 92. This retarding block 91 has a function of significantly lowering the moving speed of the waste to be moved to relatively increase the time exposed to the heat of the burner (B). In other words, wastes with high moisture content (such as construction waste or sludge) are not completely incinerated due to delayed incineration due to moisture inside even after passing through the drying section. There is a problem).

To this end, the present invention installs a circular band-improving retarding block 91 in the middle of the guide block 92 to significantly lower the transfer speed of the waste transferred at a constant speed, thereby reducing the waste against the burner (B) and internal heat. It will secure enough exposure time. Accordingly, sufficient incineration performance can be secured even for wastes with relatively high water content.

Referring to FIG. 6, an outlet 93 of a predetermined space is formed under the burner mounting hole 85 of the incinerator 50. The discharge port 93 may discharge the incinerated ash in the interior of the incinerator 50 and be stored in the lower storage box 94. In addition, a transmission window 82 and a temperature sensor 83 for measuring the temperature inside are installed so that the inside of the incinerator 50 can be observed from the outside.

Referring to FIG. 7, combustion air channels 52a and 52b are provided in the incinerator 50 at regular intervals to provide sufficient combustion air throughout the incinerator 50 provided in a long cylindrical shape. Specifically, the combustion air channels 52a and 52b include a fixed plate 52e to which the distribution supply pipe 74 is connected, and a moving plate 52f having a channel space 52h formed therein. Among them, the fixed plate 52e has a distribution supply pipe 74 in communication and connection ribs 52s are formed on both sides. In addition, the moving plate 52f has a channel space portion 52h formed therein, and a connection line 53h is connected to the bottom surface to penetrate the inside of the incinerator 50. In addition, the moving plate 52f is connected to the upper side of the connecting rib 52s of the fixed plate 52e so that the moving plate 52f can be rotated with respect to the fixed plate 52e. That is, the fixed plate 52e is installed in a fixed state on the outside of the incinerator 50, and the moving plate 52f is installed on the outer circumferential surface of the incinerator 50 and rotates together with the rotation of the incinerator 50, and moves accordingly. The plate 52f is rotatable with respect to the fixed plate 52e.

The combustion air channels 52a and 52b configured as described above receive combustion air provided through the distribution supply pipe 74 through the channel space 52h, and are connected to the lower part of the moving plate 52f. It can be uniformly supplied to the inside of (50). Accordingly, it is possible to solve the problem of deteriorating combustion efficiency due to insufficient combustion air in a part of the incinerator 50 during the incineration process.

As described above, the present invention has a configuration in which the incinerator 50 rotates and moves the waste to the burner B so that the drying process of the waste is preceded in the first predetermined section, and then the waste is incinerated. In addition, in order to increase the incineration efficiency for wastes with high moisture content, a retard block 91 is formed inside the incinerator 50 to ensure sufficient heat exposure time for wastes with high moisture content, thereby improving the incineration performance of the overall device. I can.

In addition, the present invention can control the on/off of the burner (B) by sensing the temperature of the incineration area of the incinerator (50). That is, according to the present invention, when waste is put into the incinerator 50, it is burned inside the incinerator 50 after a drying process, thereby increasing the incineration temperature of the incinerator 50. Therefore, when the internal temperature of the incinerator 50 is higher than a certain temperature through the temperature sensor 83, the burner B is turned off and a continuous incineration process is performed through the waste combustion heat in the incinerator 50. Through this, the incinerator can be continuously operated without fully operating the burner (B) (always operating), thereby greatly improving operating costs and operating efficiency.

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: drive gear unit
52a, 52b: combustion air channel
53a, 53b: information
60: waste supply
70: air supply
71: first supply pipe
72: second supply pipe
73: main supply pipe
74: distribution supply pipe
75a,75b: cooling supply pipe
78: combustion air supply pipe
81: supply port
82: transmission window
83: temperature sensor
85: burner mounting hole
91: delay block
92: guide block
93: exit
110: exhaust system
120: exhaust pipe
130: connection

Claims (7)

A waste supply unit for supplying waste;
An incinerator that is connected to the waste supply unit to insert the waste and moves the inputted waste toward the burner while rotating it therein; And
An exhaust unit connected to the incinerator and exhausting heat from the inside of the incinerator to the outside,
Waste incineration system, characterized in that the conveying direction of the waste in the incinerator and the exhausting direction of the heat are opposite to each other. The method of claim 1,
The incinerator,
A drying area formed near a location where the waste is input to dry the waste by heat transmitted through the burner, and
A waste incineration system comprising an incineration area formed in the vicinity of the burner, transferred inside the incinerator, and passed through the drying area to directly incinerate the dried waste. The method of claim 2,
The incineration zone is a waste incineration system, characterized in that incineration of the waste is performed by the thermal power of the burner, and on/off control of the burner is performed by sensing a temperature of the incineration zone. The method of claim 3,
In the incineration area,
Waste incineration system, characterized in that at least one retarding block is formed for slowing the transfer speed of the waste. According to 3,
In the incinerator,
A waste incineration system, characterized in that a combustion air supply unit installed at regular intervals along the longitudinal direction of the incinerator is formed to supply combustion air into the incinerator. According to 1,
In the incinerator,
A plurality of guide blocks are arranged to form a spiral so as to transfer the waste to the burner side,
The guide block is a waste incineration system, characterized in that it is made of refractory bricks, heats up heat inside the incinerator, and provides a continuous impact when the waste is transported by the rotation of the incinerator. The method of claim 5,
The combustion air supply unit,
A fixed plate fixed along the outer circumferential surface of the incinerator,
A moving plate rotatably connected through the fixing plate and a connecting rib and provided with a channel space portion through which combustion air moves, and
A waste incineration system comprising an extension line that is communicated with the moving plate at a tip end to communicate with the inner circumferential surface of the incinerator.

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