KR19990078857A - Combustion Apparatus Having a Heating Body for Complete Combustion of the First Combustion Gas - Google Patents

Abstract

Secondary combustion device according to the present invention is the outer case is made of steel and the inner side of the secondary combustion furnace (3) formed with a heat insulating layer; A heating element (10) installed in the internal combustion chamber (5) of the secondary combustion furnace to completely burn the primary combustion gas; A burner device having a torch extending into the combustion chamber 5 and injecting fuel and air to generate a flame; And means for supplying air into the burner device (1) and the second combustion furnace (3), and receives the first combustion gas from the incinerator primary combustion device and receives the second combustion. It is characterized by complete combustion in the combustion chamber of the furnace. In the heating element according to the present invention, a plurality of perforated cylinders of different diameters are arranged concentrically, and the torch end is installed to be opened by a supporting member, and the opposite end is provided with a blocking plate, and the outer cylinder surface A plurality of isolation support for fixing the heating element to the heat insulation layer is formed.

Description

Second combustion device having a heating element for completely burning the first combustion gas of the incinerator {Combustion Apparatus Having a Heating Body for Complete Combustion of the First Combustion Gas}

Field of invention

The present invention relates to an incinerator. More specifically, the present invention relates to a secondary combustion device provided with a heating element in the combustion chamber of the secondary combustion furnace in order to completely burn the combustion gas (primary combustion gas) generated in the incinerator.

Background of the Invention

One of the problems that humanity faces today is how to deal with the waste generated. Various wastes, wastes and the like are disposed of by landfilling or burning. Various incinerators are installed and used to burn various kinds of garbage and wastes.

Incinerators have the advantage of being able to use the heat of combustion from combustion of objects and no residue.

However, the generation of soot and toxic gases generated during combustion causes another air pollution. In particular, the burning of chemicals such as synthetic resins cause serious problems such as the generation of dioxin.

When burning in an incinerator, soot or toxic gas is generated because it is not able to completely burn the object to be burned or to burn the gas generated at the time of burning completely.

In general, in case of first combustion of an object to be burned such as garbage, a lot of soot and toxic gas are generated. Conventional incinerators equipped only with combustion chambers can no longer be used because severe fumes and toxic gases are released into the atmosphere.

Therefore, in order to completely burn the primary combustion gas generated in the conventional incinerator again, an incinerator having a secondary combustion furnace is installed and used.

Incinerators equipped with the secondary combustion furnaces up to now are combusting the primary combustion gas again by introducing the combustion gas generated during the primary combustion into the secondary combustion furnace and generating a spark by the burner in the secondary combustion chamber.

In order to completely burn the primary combustion gas, the temperature in the secondary combustion furnace must be maintained at a significant temperature, for example 800-900 ° C. A method of using electricity to maintain such a high temperature is known, but it is not economical because a lot of power costs because it must maintain a high temperature. In general, when using a burner that injects liquid fuel, it is difficult to maintain a high temperature of 800 to 950 ° C. at all times due to mixing of the burner flame and the incoming primary combustion gas inside the secondary combustion chamber. The conventional incinerators up to now maintain the temperature of 400-500 degreeC normally in a secondary combustion chamber. At these temperatures, the primary combustion gas is not completely burned. Therefore, smoke, toxic gas, etc., which are not completely burned, are released into the atmosphere, causing air pollution. Of course, the secondary combustion gas is less smoke or toxic than the primary combustion gas, but it is difficult to completely burn out, it is difficult to discharge a non-toxic, pollution-free gas through perfect combustion.

The present inventors recognize the problems of the conventional incinerator as described above, and the second combustion device of the present invention capable of releasing pollution-free, non-toxic combustion gas into the atmosphere by completely burning the primary combustion gas generated from the incinerator. It is early to develop.

An object of the present invention is to provide a secondary combustion device capable of completely burning the primary combustion gas of an incinerator.

Another object of the present invention is to provide a secondary combustion apparatus capable of discharging pollution-free, non-toxic combustion gas into the atmosphere by completely burning the primary combustion gas of an incinerator.

Still another object of the present invention is to provide a secondary combustion apparatus that can be installed in a conventional incinerator having only a primary combustion function.

Still another object of the present invention is to provide a secondary combustion apparatus capable of installing a heating element according to the present invention in a secondary combustion furnace of an incinerator having conventional primary and secondary combustion functions.

Still another object of the present invention is to provide a secondary combustion device which is economical in operating cost by using a conventional fuel burner device.

Still another object of the present invention is to provide a secondary combustion device capable of keeping the temperature of the combustion chamber of the secondary combustion furnace constant at 800 to 950 ° C.

Still another object of the present invention is to provide a secondary combustion device capable of completely burning the primary combustion gas by injecting air into the combustion chamber as appropriate.

It is a further object of the present invention to provide a secondary combustion device with a short initial time to reach the required high temperature.

The above and other objects of the present invention can be achieved by the present invention described below.

1 is a schematic cross-sectional view of a secondary combustion device in which a heating element is installed in a combustion chamber of a secondary combustion furnace in order to completely burn the primary combustion gas of an incinerator according to the present invention.

2 is a schematic left side perspective view of a heating element installed in a combustion chamber of a secondary combustion furnace according to the present invention;

3 is a schematic right side perspective view of a heating element installed in a combustion chamber of a secondary combustion furnace according to the present invention.

* Brief description of the major symbols in the drawings *

1: Burner device 2: Air fan

3: secondary combustion furnace 4: inlet

5: combustion chamber 6: outlet

7: heat insulation layer 8: torch (torch)

10: heating element 11: first drilling cylinder

12: second drill cylinder 13: third drill cylinder

14 fourth drilling cylinder 15 blocking plate

16: spacing support 17: support member

18: perforation

19: circumferential outer passage

20: fuel hose 21, 22, 23, 24: pipe

25 pipe 26, 27, 28 valve

30: endoscope

The secondary combustion device of the present invention is a device for completely burning in the combustion chamber of the secondary combustion furnace by receiving the primary combustion gas from the primary combustion device incinerator, the outer case is made of steel and the insulation layer inside The secondary combustion furnace has a heating element installed in the internal combustion chamber of the secondary combustion furnace to completely burn the primary combustion gas, and a torch extending into the combustion chamber to inject fuel and air. And a means for supplying air into the burner device and the secondary combustion furnace.

In the heating element according to the present invention, a plurality of perforated cylinders of different diameters are arranged concentrically, and the torch end is installed to be opened by a supporting member, and the opposite end is provided with a blocking plate, and the outer cylinder surface A plurality of isolation support for fixing the heating element to the heat insulation layer is formed.

Hereinafter, with reference to the accompanying drawings will be described in detail the contents of the present invention.

The secondary combustion device of the present invention is a device for completely burning in the combustion chamber of the secondary combustion furnace by receiving the primary combustion gas from the incinerator primary combustion device.

The conventional secondary combustion device is equipped with a burner device (1) equipped with a torch (8) for burning the primary combustion gas coming into the combustion chamber again, and there is no installation inside the combustion chamber. That is, only the flame exists inside the combustion chamber 5, and the primary combustion gas had to be burned by the flame. In such a conventional structure, first, the inside of the combustion chamber cannot be maintained at a high temperature necessary for complete combustion, that is, a temperature of 800 to 950 ° C., and since the gas must be burned only with a flame, the residence time is short, so that the complete combustion of the gas is impossible. In the present invention, it is possible to completely solve the drawbacks of the conventional incinerator, to maintain the high temperature necessary for complete combustion, and to pass the primary combustion gas through the heating element covered with the flame flame and for a sufficient time so that the primary combustion gas is sufficiently filled. We have developed a perfect secondary combustion device that can burn completely.

1 is a schematic cross-sectional view of a secondary combustion device in which a heating element 10 is installed in the combustion chamber 5 of the secondary combustion furnace 3 in order to completely burn the primary combustion gas of the incinerator according to the present invention.

In the secondary combustion furnace 2, the outer wall is made of steel, and the heat insulation layer is formed inside the inner wall. This thermal insulation layer has been used in conventional combustion furnaces and can be easily implemented by those skilled in the art.

Although the thickness of a heat insulation layer changes with the size of an incinerator, the range of 10-30 cm is preferable normally. The heat insulation layer adheres and fires the refractory mortar to the inside of the combustion furnace 2.

The heating element 10 is installed in the combustion chamber 5 of the secondary combustion furnace 3 in the horizontal direction. The heating element 10 arranges a plurality of perforated cylinders of different diameters concentrically. 2 is a schematic left side perspective view of the heating element 10, and FIG. 3 is a schematic right side perspective view. The heating elements shown in FIGS. 1 to 3 are composed of four first to fourth perforated cylinders 11, 12, 13, and 14.

However, the number of the perforated cylinders need not be limited to four, and may vary depending on the capacity of the incinerator, but usually about 3 to 6 may be appropriate.

Torch 8 side end portion of the heating element 10 is coupled to open by the support member (17). The primary combustion gas injected through the inlet 4 is burned together with the flame of the torch 8 and enters the heating element 10. The blocking plate 15 is attached to the opposite end of the heating element 10. The heating element 10 may maintain a reddish state by the flame of the torch 8 and thus maintain a constant high temperature.

Gas burned while moving into the heating element 10 can no longer proceed due to the blocking plate 15 and moves to the outer side of the heating element, that is, toward the first drilling cylinder, and thus the circumference between the heat insulating layer 7 and the first drilling cylinder 11. It is discharged toward the outlet 6 through the outer passage 19 and discharged to the atmosphere.

In order to form a circumferential outer passage 19 between the first drilling cylinder 11 and the heat insulating layer 7, a plurality of isolation supports 16 are formed on the first drilling cylinder 11. Of course, the isolation support 16 may be installed on the lower and both sides of the first drilling cylinder 11, it may not be installed on the top. The length of the isolation support 16 is equal to the distance between the first drilling cylinder 11 and the heat insulation layer 7.

This interval varies depending on the capacity of the incinerator, but it is usually preferable to maintain an interval of 3 to 20 cm.

The heating element 10 is usually made of stainless steel, and preferably has a thickness of 0.5 ~ 2.0mm, the surface should be perforated at regular intervals to facilitate the flow of gas.

The size of the heating element 10 may vary depending on the capacity of the incinerator.

Usually, the length is preferably in the range of 1000 to 1500 mm. In the case of an incinerator having an incineration amount of 50 kg per hour, the diameter of the first drilling cylinder is 400 mm, the diameter of the second drilling cylinder is 300 mm, the diameter of the third drilling cylinder is 200 mm, and the diameter of the fourth drilling cylinder is preferably 100 mm. Do. When the incineration throughput is 50 kg / hr, the distance between the adjacent perforations 18 and the perforations 18 is 2,5 cm and the diameter of the perforations 18 is 10 mm.

When the heating element 10 according to the present invention is installed in the combustion chamber 5 and the flame is ignited by the torch 8, the heating element 10 becomes red to heat up the internal temperature of the combustion chamber 5 in a few minutes at 800 to 950 ° C. It is possible to raise the range of, and by keeping this temperature constant, the first combustion gas can be completely secondary burned. Since the heat generating body 10 is maintained at a high temperature, it is possible to maintain a constant high temperature and complete combustion is possible because the primary combustion gas passes through the heat generating body.

In the present invention, a burner device 1 for generating sparks in the combustion chamber 5 is provided. The burner device 1 is combusted as air is injected through the pipe 22 and fuel is injected and injected through the fuel hose 20. This burner device 1 can be easily implemented by those skilled in the art. In the present invention, a turbo air fan should be used to inject air.

In the present invention, when the temperature of the combustion chamber 5 is sensed and the temperature reaches a certain temperature, the fuel supply motor (not shown) is stopped, and only the air fan is operated to supply only air. In addition, when the temperature inside the combustion chamber 5 falls below a predetermined temperature, an automatic control and an ignition / fire extinguishing device for automatically igniting the torch 8 of the burner by automatically operating a fuel supply motor are provided.

Means are provided for supplying air to the combustion chamber 5 inside the burner device 1 and the secondary combustion furnace 3. This means consists of an air fan 2, pipes 21, 22, 23, and 24, valves 26, 27, and 28, and a plurality of pipes 25. The air fan 2 should be turbo type.

The air is injected together with the fuel in the burner device 1 through the pipe 22 by the air fan 2 and enters the combustion chamber 5. A plurality of pipes 25 are formed such that air is distributed longitudinally through the pipe 23 toward the top of the combustion furnace 3 for complete combustion in the combustion chamber 5. That is, the plurality of pipes 25 allow air to be evenly introduced into the combustion furnace 3 through the heat insulating layer. A plurality of pipes 25 are formed such that air is longitudinally dispersed through the pipe 24 toward the lower side of the combustion furnace 3. Here too, the plurality of pipes 25 penetrates the heat insulating layer so that air is evenly introduced.

In the secondary combustion device according to the present invention, an endoscope 30 may be attached to know the inside of the combustion chamber 5. A thermometer (not shown) for measuring the temperature inside the combustion chamber 5 may be installed, and an automatic ignition for igniting and extinguishing the torch 8 according to a sensor (not shown) attached to the thermometer. Although / fire extinguishing switches (not shown) may be installed, they can be easily understood by those skilled in the art.

In FIG. 1, the inlet 4 into which the primary combustion gas is injected is shown as being injected from the bottom direction, but this is shown for convenience and can be injected from the side direction as well as the downward direction.

The heating element 10 of the present invention is installed in a horizontal type, as shown in FIG. 1, but is not necessarily limited thereto, and may be preferably installed in a vertical type.

The secondary combustion device according to the present invention can completely burn the primary combustion gas by injecting air into the combustion chamber appropriately and keeping the temperature of the combustion chamber of the secondary combustion furnace constant at 800 to 950 ° C. Effectively reducing pollutants. In addition, since a conventional fuel burner device can be used, it is economical in terms of operating cost.

Simple modifications and variations of the present invention can be readily used by those skilled in the art, and all such variations or modifications can be considered to be included within the scope of the present invention.

Claims (14)

A second combustion furnace 3 having an outer case made of steel and having an insulation layer formed therein; A heating element (10) installed in the internal combustion chamber (5) of the secondary combustion furnace to completely burn the primary combustion gas; A burner device having a torch extending into the combustion chamber 5 and injecting fuel and air to generate a flame; And Means for supplying air into the burner device (1) and the secondary combustion furnace (3); Secondary combustion device for receiving the first combustion gas from the incinerator primary combustion device to complete combustion in the combustion chamber (5) of the secondary combustion furnace (3) characterized in that consisting of. The secondary combustion device according to claim 1, wherein the heating element (10) is provided with a plurality of isolation support (16) for fixing the heat insulation layer (7). The secondary combustion device of claim 2, wherein the plurality of perforated cylinders comprise three to six cylinders. 3. Secondary combustion device according to claim 2, characterized in that the plurality of perforated cylinders comprises first to fourth perforated cylinders (11, 12, 13, and 14). The method of claim 1, wherein the air supply means comprises an air fan (2), pipes (21, 22, 23, and 24), valves (26, 27, and 28), and a plurality of pipes (25). Secondary combustion device characterized in that. The secondary combustion device according to claim 5, wherein the air fan (2) is turbo type. According to claim 5, The plurality of pipes 25 are installed in the upper portion in the longitudinal direction of the secondary combustion furnace along the pipe 23, and installed in the lower portion in the longitudinal direction of the secondary combustion furnace along the pipe (24). Secondary combustion device, characterized in that. 2. The burner device according to claim 1, wherein the burner device stops the fuel supply motor when the temperature of the combustion chamber 5 reaches a predetermined temperature, and automatically operates the fuel supply motor when the temperature of the combustion chamber 5 falls below a predetermined temperature. And a ignition / fire extinguishing device for automatically igniting the torch (8) of the burner. 2. Combustion apparatus according to claim 1, characterized in that an endoscope for visually viewing the interior of the combustion chamber (5) is provided. A plurality of perforated cylinders of different diameters are arranged concentrically, and the torch end is installed to be opened by a support member, and the opposite end is provided with a blocking plate 15, and the outer cylinder surface has a heating element 10 ) Is provided with a plurality of isolation support (16) for fixing to the heat insulating layer (7), the first from the incinerator primary combustion device mounted in the combustion chamber of the secondary combustion furnace (3) of the incinerator Heating element for supplying car combustion gas and burning it completely. 11. The heating element according to claim 10, wherein said plurality of perforated cylinders comprise three to six cylinders. The heating element according to claim 10, wherein said plurality of perforated cylinders comprise first to fourth perforated cylinders (11, 12, 13, and 14). Igniting the burner device 1, preheats the heating element provided in the combustion chamber 5 in the secondary combustion furnace 3 to maintain the temperature in the combustion chamber at a temperature of 800 to 950 ° C; Introducing a first combustion gas generated from the first combustion of the incinerator through an inlet into the preheated combustion chamber (5); Completely burning the introduced primary combustion gas through the heating element (10) in the preheated combustion chamber (5); And The completely burned gas is discharged to the outlet through the circumferential outer passage (19); A method for completely combusting the first combustion gas of the incinerator, characterized in that it comprises a step in a secondary combustion device equipped with a heating element. 15. The fuel supply motor of claim 13, wherein the fuel supply motor is stopped by the automatic controller when the temperature of the combustion chamber 5 reaches a predetermined temperature in the step of combusting the first combustion gas, and the temperature of the combustion chamber is lowered below a predetermined temperature. And automatically igniting the torch (8) by automatically operating the fuel supply motor.