KR102376461B1 - Pyrolysis device with air cooling system - Google Patents

Abstract

The present invention relates to an air-cooled waste pyrolysis furnace capable of rapidly lowering the temperature of a pyrolysis space part filled with combustible waste fuel, which is provided to stand vertically, a fuel inlet opening and closing with a lid at the upper part, and a floor door at the lower part The ash discharge port for opening and closing the unit is provided, and the periphery is provided with a cylindrical steel plate; a perimeter fire wall provided to be spaced apart from the inner periphery of the perimeter steel plate and provided with a pyrolysis space therein; a cooling chamber formed so that upper and lower portions are closed between the peripheral fire wall and the peripheral steel plate; a gas discharge pipe provided in the upper portion of the pyrolysis space to pass through the cooling chamber and to be drawn out of the cylinder; an ignition unit and an air supply unit provided in a lower portion of the pyrolysis space through a cooling chamber; One end is connected to the cooling gas supply means and the other end is connected to the lower part of the cooling chamber to supply cooling gas such as cooling air or cooling nitrogen to the lower part of the cooling chamber, and a pump for supplying the cooling gas at a high pressure is provided in the middle a first cooling gas supply pipe; A first cooling gas recovery pipe having one end connected to the cooling gas supply means and the other end connected to the upper part of the cooling chamber to recover and re-cool the cooling gas transferred by heat exchange to the upper part of the cooling chamber by the cooling gas supply means. It is characterized in that it contains;

Description

Pyrolysis device with air cooling system

The present invention relates to a pyrolysis device having an air-cooled cooling structure, and more particularly, to a pyrolysis device having an air-cooled cooling structure that allows the temperature of a pyrolysis space filled with fuel, which is combustible waste, to be quickly lowered.

In general, various methods are known as a method of treating various types of waste such as household waste, industrial waste, and pathogenic waste. And conventionally, the thermal decomposition method is widely used as a method of treating household waste, industrial waste, pathogenic waste, and the like.

The conventional pyrolysis method classifies and pyrolyzes combustible waste such as waste that can be used as biomass fuel, including organic matter, polypropylene-based waste synthetic resin, and pathogenic waste, and completely burns the combustible gas generated through pyrolysis through a combustor. It is a method of using the combustion heat generated during combustion to operate a boiler to recover steam, and to use the steam to drive a turbine or generate steam.

And, as the conventional pyrolysis method utilizes gas generated by thermally decomposing combustible wastes in a gasifier, there is an advantage in reducing the emission of carbon dioxide and alleviating the problem of global warming.

Therefore, first, as an example of a pyrolysis gasifier used in a conventional waste pyrolysis method, Korean Patent Publication No. 1218361 "Pyrolysis gas generating system using combustible waste" (hereinafter referred to as "conventional pyrolysis gas generating system") is is known

As shown in FIG. 4, the conventional pyrolysis gas generating system forms a space in which combustible waste is pyrolyzed (hereinafter referred to as "pyrolysis space") and withstands the heat of combustion of combustible waste 320 and It includes a cooling water jacket 310 filled with cooling water 305 and a cylinder portion 330 made of a rolled steel sheet 333 surrounding the cooling water jacket 310 .

The cooling water jacket 310 is provided on the inner periphery of the cylindrical tube 330 , and the fire resistant material 320 is installed inside the cooling water jacket 310 to prevent direct contact with combustible waste.

The fire resistant material 320 is installed so that the cooling water jacket 310 does not come into direct contact with the combustible waste, and serves to appropriately lower the temperature of the combustible waste to the range of the pyrolysis temperature.

If the refractory material 320 is not installed between the combustible waste and the cooling water jacket 310, the temperature of the combustible waste in contact with the cooling water jacket 310 or near the cooling water jacket 310 is lower than the thermal decomposition temperature, so that the combustible waste This is not carbonized, and the waste synthetic resin is maintained in a liquid or solid state. Therefore, if the refractory material 320 is not installed between the combustible waste and the cooling water jacket 310, the thermal decomposition efficiency of the combustible waste becomes very low, and the liquid or solid waste synthetic resin is not easily pyrolyzed even if it is heated again later. will become

The cooling water jacket 310 constantly maintains the temperature of the combustible waste fuel in the barrel 330 within the pyrolysis temperature range. By doing so, it serves to bring the temperature of the fuel in the cylinder part 330 into the range of the thermal decomposition temperature.

Therefore, in the prior art, it is important to lower the temperature of the refractory material in the process of thermally decomposing combustible waste to lower the internal temperature of the pyrolysis space to the most appropriate temperature range for thermal decomposition of combustible waste fuel.

However, in the conventional pyrolysis gas generating system, when the temperature of the pyrolysis fuel of the fuel exceeds the pyrolysis temperature, cooling water is injected into the cooling water jacket in the process of lowering the temperature of the fuel to a temperature range suitable for pyrolysis to lower the temperature of the refractory material in the pyrolysis space As the negative temperature is lowered, the circulation of the cooling water is delayed, and it takes a long time to lower the temperature of the refractory material, so there is a problem that the efficiency of pyrolysis by burning combustible waste is reduced.

In addition, in the conventional pyrolysis gas generating system, as a temperature difference occurs in the upper and lower portions of the refractory material due to the temperature deviation of the coolant filled in the coolant jacket, the upper and lower portions of the fuel filled in the pyrolysis space in the process of lowering the temperature of the fuel There was also a problem in that the thermal decomposition efficiency of the fuel was lowered due to the occurrence of a temperature deviation in the

Korean Patent Publication No. 1218361 "Pyrolysis gas generation system using combustible waste"

Accordingly, the present invention has been devised to solve the various problems of the prior art, and an object of the present invention is to reduce the temperature of the fuel to a temperature suitable for pyrolysis because the temperature of the fuel exceeds the pyrolysis temperature during pyrolysis. An object of the present invention is to provide an air-cooled waste pyrolysis furnace capable of rapidly lowering the temperature of a fuel-filled pyrolysis space by rapidly lowering the temperature of the peripheral fire wall by introducing a cooling gas that moves rapidly at high pressure.

Another object of the present invention is to reduce the temperature difference between the upper and lower parts of the cooling chamber in which the high-pressure cooling gas is circulated to a minimum so that the temperature of the entire perimeter fire wall provided around the pyrolysis space can be uniformly lowered by pyrolysis of air-cooled waste. To provide a fireplace.

In order to achieve the above object, the pyrolysis device having an air-cooling cooling structure according to the present invention is provided to stand vertically, a fuel inlet opening and closing with a lid is provided at the upper part, and an ash outlet port opening and closing the floor door unit at the lower part and a cylindrical portion provided with a peripheral steel plate; a perimeter fire wall provided to be spaced apart from the inner periphery of the perimeter steel plate and provided with a pyrolysis space therein; a cooling chamber formed so that upper and lower portions are blocked between the peripheral fire wall and the peripheral steel plate; a gas discharge pipe provided in the upper portion of the pyrolysis space to pass through the cooling chamber to be drawn out of the cylinder; an ignition unit and an air supply unit provided in a lower portion of the pyrolysis space through a cooling chamber; One end is connected to the cooling gas supply means and the other end is connected to the lower part of the cooling chamber to supply cooling gas such as cooling air or cooling nitrogen to the lower part of the cooling chamber, and a pump for supplying the cooling gas at a high pressure is provided in the middle a first cooling gas supply pipe; A first cooling gas recovery pipe having one end connected to the cooling gas supply means and the other end connected to the upper part of the cooling chamber to recover and re-cool the cooling gas transferred by heat exchange to the upper part of the cooling chamber by the cooling gas supply means. It is characterized in that it contains;

In addition, it is characterized in that a helical protrusion is further formed on the outer side of the perimeter fire wall of the pyrolysis device having an air-cooling cooling structure according to the present invention by rotating the cooling gas supplied from the lower part in a helical manner.

In addition, a spiral cooling tube is further provided in the spiral valley formed around the spiral protrusion of the pyrolysis device having an air cooling structure according to the present invention, and the lower end of the spiral cooling tube is connected to the first cooling gas recovery tube. A second cooling gas recovery pipe is further connected, and a second cooling gas supply pipe connected to the discharge side of the pump of the first cooling gas supply pipe is further connected to the upper end of the spiral cooling pipe.

In the present invention configured as described above, as the temperature of the fuel exceeds the pyrolysis temperature during pyrolysis and a cooling gas that moves rapidly at high pressure is introduced into the cooling chamber in the process of lowering the temperature of the fuel to a temperature suitable for pyrolysis, the peripheral fire wall There is an effect of improving the pyrolysis efficiency by rapidly lowering the temperature of the pyrolysis space to a temperature range suitable for pyrolysis of fuel.

In addition, the present invention minimizes the temperature difference between the upper and lower parts of the cooling chamber in which the high-pressure cooling gas is circulated to uniformly lower the temperature of the entire perimeter fire wall provided around the pyrolysis space, so that the temperature rises during pyrolysis. There is also an effect that the efficiency of pyrolysis can be further improved by lowering the temperature of the entire fuel to the optimum pyrolysis temperature range suitable for pyrolysis.

1 is a front cross-sectional view showing a pyrolysis device having an air-cooled cooling structure of a first embodiment of the present invention.
Figure 2 is a front cross-sectional view showing a pyrolysis device having an air-cooled cooling structure of the second embodiment according to the present invention.
Figure 3 shows a pyrolysis device having an air-cooled cooling structure of a third embodiment according to the present invention,
3A is a front cross-sectional view,
3B is a partial cut-away front cross-sectional view.
4 is a front cross-sectional view showing a conventional pyrolysis gas generating system.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings. However, it should be understood that the present invention may be embodied in many different forms and is not limited to the described embodiments.

1 is a cross-sectional front view showing a pyrolysis device having an air-cooled cooling structure according to a first embodiment of the present invention.

As shown in the figure, the pyrolysis device having an air-cooled cooling structure according to the present invention (hereinafter referred to as "pyrolysis device") is capable of improving the pyrolysis efficiency at the initial stage of pyrolysis by burning combustible waste fuel, It includes the cylinder part 1, the peripheral fire wall 2, the cooling chamber 3, the gas discharge pipe 4, the ignition part 5, the 1st cooling gas supply pipe S1, and the 1st cooling recovery pipe R1. .

The cylinder part 1 is provided to stand upright, and it is preferable to have a cylindrical shape so that fuel, which is a combustible waste, can be burned inside to facilitate thermal decomposition, and a peripheral steel plate 1a is preferably provided on the periphery. Do.

A fuel inlet 11 into which fuel, which is a combustible waste, which is opened and closed by a lid 12 is put in the upper portion of the barrel 1, and an ash outlet opened and closed by the floor door 14 at the lower portion of the barrel 1 ( 13) is provided. And the bottom door 14 is a well-known thing configured to be able to lift, or to be moved up and down and left and right to discharge the ash, and the accompanying drawings show a state configured to be lifted and opened.

It is preferable that the lower part of the cylindrical part 1 is configured in a cone shape with a wide upper part and a narrow lower part so that the ash generated during combustion of combustible waste can be smoothly discharged.

In addition, the peripheral fire wall 2 is provided to be spaced apart from the inner surface of the peripheral steel plate 1a on the inner periphery of the peripheral steel plate 1a, and a pyrolysis space 21 in which fuel, which is a combustible waste, is filled and burned. ) will be provided.

The cooling chamber 3 is provided such that the upper and lower portions are blocked between the peripheral fire wall 2 and the peripheral steel plate 1a, and inside is moved from the lower part to the upper part through a first cooling gas supply pipe S1 to be described later. Cooling gas is supplied.

The gas discharge pipe 4 passes through the cooling chamber 3 in the upper portion of the pyrolysis space 21 and is withdrawn to the outside of the barrel 1, and the gas discharge pipe 4 recycles the gas discharged through pyrolysis. It is connected to recycling means (not shown) such as boilers.

The ignition unit 5 penetrates the cooling chamber 3 at the lower portion of the pyrolysis space 21 to be connected to the outside of the cylinder 1, and injects a flame into the fuel, which is combustible waste, to ignite the fuel. To do this, the ignition unit 5 is already known.

The air supply part 6 is provided to be connected to the outside of the cylinder part 1 through the cooling chamber 3 at the lower part of the pyrolysis space 21 , and the combustion of combustible waste into the lower part of the pyrolysis space 21 . It serves to supply the necessary air. And the air supply unit 6 includes an air chamber 61 to which air is supplied through an air supply pipe 611, and a cooling chamber 3 under the pyrolysis space 21 to pass through the air chamber 61. It may be composed of a plurality of air inlet pipes 62 for supplying air to the lower portion of the pyrolysis space 21 .

In addition, the first cooling gas supply pipe S1 has one end connected to the cooling gas supply means 7 for supplying the cooling gas and the other end connected to the lower part of the cooling chamber 3 to lower the cooling chamber 3 . It supplies a cooling gas composed of furnace cooling air or cooling nitrogen, and a pump (P) for supplying the cooling gas at a high pressure is provided in the middle.

The first cooling gas recovery pipe (R1) has one end connected to the cooling gas supply means (7) and the other end connected to the upper part of the cooling chamber (3), so that the first cooling gas recovery pipe (R1) is heat-exchanged and moved to the upper part of the cooling chamber (3). It serves to recover the gas to the cooling gas supply means (7) and re-cool it.

The cooling gas supply means 7 is connected to the first cooling gas supply pipe S1 and the first cooling gas recovery pipe R1 and serves to circulately supply the cooling gas to the cooling chamber 3 , A tank 71 to which a first cooling gas recovery pipe R1 is connected and replenishable with air or nitrogen is provided, and a tank 71 provided on the discharge side of the tank 71 and connected to the first cooling gas supply pipe S1 The cooling discharge pipe 72 and the cooling discharge pipe 72 surround the outside and are connected to a known refrigeration system (not shown) so that a cooling refrigerant (Freon gas, etc.) passes inside and passes through the inside of the cooling discharge pipe 72 It may be configured to include a cooling refrigerant pipe 73 for cooling the gas.

Hereinafter, a process of thermally decomposing combustible waste through a pyrolysis device having an air-cooled cooling structure in the first embodiment according to the present invention configured as described above is as follows.

1, in the case of pyrolysis of combustible waste through the pyrolysis device having the air-cooled cooling structure of the first embodiment according to the present invention, first, the lid 12 is opened to open the pyrolysis space part ( 21) is filled with fuel, which is a combustible waste, and then the lid 12 is closed.

Next, the air supply unit 6 is operated to supply air to the lower portion of the pyrolysis space 21 , and the ignition unit 5 is operated to ignite the fuel filled in the pyrolysis space 21 and burn it.

Next, when the temperature of the fuel exceeds the pyrolysis temperature in the process of pyrolysis by burning the fuel as described above, a known temperature sensor (not shown) installed in the pyrolysis space unit 21 is controlled by a known controller (not shown) or an operator. is detected and the control unit or the operator operates the refrigeration system and the pump P of the cooling gas supply means 7 to cool the high pressure from the lower part of the cooling chamber 3 to the upper part through the first cooling gas supply pipe S1. Through the process of continuously supplying gas and continuously discharging the gas whose temperature has risen through heat exchange in the first cooling gas recovery pipe R1, the temperature of the surrounding fire wall 2 is rapidly lowered to form the pyrolysis space 21 ) to quickly lower the temperature to a suitable temperature range for pyrolysis of fuel and maintain a suitable temperature range for pyrolysis of fuel.

And, if the temperature range suitable for thermal decomposition of fuel is maintained, pyrolysis continues in a state in which the control unit or the operator turns off the refrigeration system and the pump P of the cooling gas supply means 7 .

That is, the present invention is to quickly lower the fuel temperature by operating the refrigeration system and the pump P of the cooling gas supply means 7 when the fuel temperature exceeds the optimum thermal decomposition temperature.

Therefore, in the pyrolysis device having the air-cooled cooling structure of the first embodiment according to the present invention, the temperature of the fuel exceeds the pyrolysis temperature during pyrolysis as described above, and in the process of lowering the temperature of the fuel to a temperature suitable for pyrolysis, in the cooling chamber 3 As the cooling gas that moves rapidly at high pressure is introduced, the temperature of the peripheral fire wall 2 is rapidly lowered to rapidly lower the temperature of the pyrolysis space 21 to a temperature range suitable for pyrolysis of fuel, thereby improving the pyrolysis efficiency. useful invention.

2 is a front cross-sectional view showing a pyrolysis device having an air-cooled cooling structure of a second embodiment according to the present invention.

As shown in FIG. 2, it is premised that the pyrolysis apparatus having the air-cooled cooling structure of the second embodiment according to the present invention includes all of the configurations of the waste pyrolysis furnace of the first embodiment described above. Therefore, in the pyrolysis device having an air-cooled cooling structure of the second embodiment according to the present invention, the cooling effect of the peripheral fire wall 2 through the cooling gas supplied from the lower side to the outside of the peripheral fire wall 2 can be improved. A helical protrusion 8 may be further formed by turning the cooling gas supplied from the helically to rise.

In addition, it is preferable that the cross-sectional shape of the spiral protrusion 8 is formed in a long plate shape in the left and right direction so that the cooling gas can be raised while turning more smoothly.

Therefore, the pyrolysis device having the air-cooled cooling structure of the second embodiment according to the present invention controls the temperature sensor installed in the pyrolysis space 21 when the temperature of the fuel exceeds the pyrolysis temperature during pyrolysis by burning fuel. A high-pressure cooling gas in the lower portion of the cooling chamber 3 through the first cooling gas supply pipe S1 by operating the refrigeration system and the pump P of the cooling gas supply means 7 and the pump P by the operator or the operator. to be supplied rapidly and continuously.

Next, when the high-pressure cooling gas is rapidly and continuously supplied to the lower part of the cooling chamber 3 through the first cooling gas supply pipe S1 as described above, the cooling gas is supplied to the outer side of the peripheral fire wall 2 by a spiral protrusion 8 By moving upward while turning along the spiral valleys 81 formed around the Heat exchange with the peripheral fire wall (2) is made.

Therefore, in the pyrolysis device having the air-cooled cooling structure of the second embodiment according to the present invention, the cooling gas moving along the helical valley 81 around the periphery of the helical protrusion 8 is in contact with the perimeter fire wall 2 in a large area to form a perimeter. As heat exchange with the fire wall 2 is made, the temperature of the peripheral fire wall 2 is rapidly lowered to quickly lower the temperature of the pyrolysis space 21 to a temperature range suitable for thermal decomposition of fuel, thereby improving the pyrolysis efficiency. It is a useful invention.

3 is a view showing a pyrolysis device having an air-cooled cooling structure of a third embodiment according to the present invention.

As shown in FIG. 3, it is premised that the pyrolysis apparatus having the air-cooled cooling structure of the third embodiment according to the present invention includes all of the configurations of the waste pyrolysis furnace of the second embodiment described above.

Therefore, in the pyrolysis device having the air-cooling cooling structure of the third embodiment according to the present invention, the spiral cooling tube 9 is further provided in the spiral valley 81 formed around the spiral protrusion 8 .

A second cooling gas recovery pipe (R2) connected to the first cooling gas recovery pipe (R1) is further provided at the lower end of the spiral cooling pipe (9), and at the upper end of the spiral cooling pipe (9) A second cooling gas supply pipe S2 connected to a discharge side from which the cooling gas of the pump P of the first cooling gas supply pipe S1 is discharged is further provided to be connected.

In addition, in the spiral cooling pipe 9, heat exchange between the cooling gas moving from the bottom to the top along the outside of the spiral cooling pipe 9 and the cooling gas moving from the top to the bottom inside the spiral cooling pipe 9 is performed. To be able to, the inner periphery may be provided in close contact with the outer surface of the perimeter fire wall 2 and the outer periphery may be provided in close contact with the inner surface of the peripheral steel plate 1a.

Therefore, in the waste pyrolysis furnace of the third embodiment according to the present invention, when the temperature of the fuel exceeds the pyrolysis temperature in the process of pyrolysis by burning fuel, the control unit or the operator detects the temperature sensor installed in the pyrolysis space 21 . Thus, the control unit or the operator operates the refrigeration system and the pump (P) of the cooling gas supply means (7).

Then, the cooling gas is rapidly and continuously supplied from the lower part of the cooling chamber 3 through the first cooling gas supply pipe S1 so that the cooling gas is formed around the spiral protrusion 8 on the outside of the peripheral fire wall 2 The cooling gas is supplied upward while turning spirally along the spiral trough 81 and continuously discharged to the first cooling gas recovery pipe R1, and then to the upper part of the spiral cooling pipe 9 through the second cooling gas supply pipe S2. is rapidly and continuously supplied, and the cooling gas is supplied downward while spirally rotating at the upper part of the inside of the spiral cooling pipe 9, and is continuously discharged to the second cooling gas recovery pipe R2.

And the cooling gas moving upward along the helical valley 81 around the helical protrusion 8 exchanges heat with the peripheral fire wall 2, and the cooling gas moves downward from the top inside the helical cooling pipe 9. is heat-exchanged with the perimeter fire wall (2).

In addition, the cooling gas moving upward along the spiral valley 81 is heat-exchanged with the peripheral fire wall 2 to rise, and as heat exchange is made with the cooling gas moving downward along the inside of the spiral cooling pipe 9, the upper It is discharged to the first cooling gas recovery pipe (R1) without abruptly increasing the temperature in the process of rising in the .

Conversely, the cooling gas moving downward along the spiral cooling pipe 9 undergoes heat exchange with the peripheral fire wall 2 to descend, and as heat exchange is made with the cooling gas moving upward along the spiral valley 81, it descends from the bottom. It is discharged to the second cooling gas recovery pipe (R2) without abruptly increasing the temperature in the process.

Therefore, the temperature of the upper and lower portions of the cooling gas moving upward along the spiral valley 81 and the cooling gas moving downward along the spiral cooling pipe 9 hardly occurs, so that there is little variation in the internal temperature of the cooling chamber. do.

Therefore, the waste pyrolysis furnace of the third embodiment according to the present invention minimizes the temperature difference between the upper and lower parts of the cooling chamber 3 through the cooling gas moving downward from the top inside the spiral cooling pipe 9 . By reducing it, the temperature of the perimeter fire wall 2 provided on the periphery of the thermal decomposition space part 21 can be made uniform.

Therefore, the waste pyrolysis furnace of the third embodiment according to the present invention minimizes the temperature difference between the upper and lower portions of the cooling chamber 3 through which the high-pressure cooling gas is circulated, and the perimeter fire wall provided around the pyrolysis space 21 . (2) This is a useful invention that can further improve the efficiency of thermal decomposition by lowering the entire temperature of the fuel, whose temperature has risen during pyrolysis, to the optimum pyrolysis temperature range suitable for pyrolysis by uniformly lowering the overall temperature.

Although preferred embodiments of the present invention have been described above, various changes, modifications and equivalents may be used in the present invention. It is clear that the present invention can be equally applied by appropriately modifying the above embodiments. Accordingly, the above description is not intended to limit the scope of the invention defined by the limits of the following claims.

On the other hand, although specific embodiments have been described in the detailed description of the present invention, it will be apparent to those of ordinary skill in the art that various modifications are possible without departing from the scope of the present invention.

1: barrel
11: fuel inlet
12 : Lid
13: Ash outlet
14: floor door part
2: perimeter fire wall
21: pyrolysis space part
3: cooling chamber
4: gas exhaust pipe
5: ignition part
6: air supply
7: cooling gas supply means
71 : tank
72: cooling discharge pipe
73: cooling refrigerant pipe
8: spiral protrusion
81: spiral bone
9: spiral cooling tube
S1: first cooling gas supply pipe
S2: second cooling gas supply pipe
R1: first cooling gas recovery pipe
R2: second cooling gas recovery pipe
P: pump

Claims (5)

a cylinder part provided to stand vertically, a fuel inlet opening and closing with a lid on the upper part, an ash discharge port opening and closing a bottom door part on the lower part, and a circumferential steel plate provided;
a perimeter fire wall provided to be spaced apart from the inner periphery of the perimeter steel plate and provided with a pyrolysis space therein;
a cooling chamber formed so that upper and lower portions are closed between the peripheral fire wall and the peripheral steel plate;
a gas discharge pipe provided in the upper portion of the pyrolysis space to pass through the cooling chamber and to be drawn out of the cylinder;
an ignition unit and an air supply unit provided in a lower portion of the pyrolysis space through a cooling chamber;
One end is connected to the cooling gas supply means and the other end is connected to the lower part of the cooling chamber to supply cooling gas such as cooling air or cooling nitrogen to the lower part of the cooling chamber, and a pump for supplying the cooling gas at a high pressure is provided in the middle a first cooling gas supply pipe;
A first cooling gas recovery pipe having one end connected to the cooling gas supply means and the other end connected to the upper part of the cooling chamber to recover and re-cool the cooling gas transferred by heat exchange to the upper part of the cooling chamber by the cooling gas supply means. ; will include,
On the outside of the perimeter fire wall
A helical protrusion is further formed to raise the cooling gas supplied from the lower part by turning it helically, and a helical cooling tube is further provided in the helical valley formed around the helical protrusion,
A second cooling gas recovery pipe connected to the first cooling gas recovery pipe is further connected to a lower end of the spiral cooling pipe,
A second cooling gas supply pipe connected to the discharge side of the pump of the first cooling gas supply pipe is further connected to an upper end of the spiral cooling pipe.
According to claim 1,
The cooling gas supply means
a tank to which the first cooling gas recovery pipe is connected and to which air or nitrogen is replenishable;
a cooling discharge pipe provided on the discharge side of the tank and connected to the first cooling gas supply pipe;
and a cooling refrigerant pipe that surrounds the outside of the cooling discharge pipe and is connected to a refrigeration system so that the cooling refrigerant passes therein to cool the gas passing through the cooling discharge pipe.
delete delete According to claim 1,
The spiral cooling tube is
A pyrolysis device having an air-cooling cooling structure, characterized in that the inner periphery is provided in close contact with the outer surface of the perimeter fire wall, and the outer periphery is provided in close contact with the inner surface of the perimeter steel plate.

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