KR101908242B1 - Pyrolysis gasifier - Google Patents

Abstract

The present invention relates to a pyrolysis gasification furnace with excellent damping performance. Specifically, according to embodiments of the present invention, the pyrolysis gasification furnace comprises: a vessel unit into which waste is supplied to be pyrolyzed; a gas discharge duct provided on an upper portion of the vessel unit, in which combustible gas created by pyrolysis of the waste flows to provide a passage to discharge the combustible gas from the vessel unit; and a damping unit which is provided on the gas discharge duct, and selectively blocks a gas flow passage in the gas discharge duct. The damping unit includes: a cylinder housing connected to the gas discharge duct, wherein a space communicating with the interior of the gas discharge duct is formed therein; a damping cylinder which is fixed on the cylinder housing, and includes a cylinder shaft provided to move towards the space in the cylinder housing; and a damping slide plate connected to the cylinder shaft, and selectively slid into the gas discharge duct from the cylinder housing by an operation of the cylinder shaft to seal the gas flow passage in the gas discharge duct.

Description

Pyrolysis gasification process {PYROLYSIS GASIFIER}

The present invention relates to a pyrolysis gasification furnace.

Disposal of various kinds of wastes such as municipal waste, industrial waste, etc. is problematic. One of the disposal methods of wastes is to classify combustible wastes such as wastes that can be used as biomass fuel including organic matter, waste synthetic resin of polypropylene series, thermally decompose them, drive the turbine by utilizing combustible gas generated through pyrolysis There is a method to utilize such as generating steam. If the combustible wastes are pyrolyzed in the gasification furnace, the emission of carbon dioxide gas can be reduced and the problem of global warming can be alleviated.

An example of such a conventional pyrolysis gasification furnace is shown in Patent Document 1. [ Hereinafter, a conventional pyrolysis gasifier will be described with reference to FIG. 9 is a view showing an internal structure of a conventional pyrolysis gasification furnace.

Referring to FIG. 13, the conventional pyrolysis gasification furnace includes a cylinder 530 for receiving flammable waste including waste synthetic resin, air injectors 535 and 536 for injecting air required for combustion of combustible waste into flammable waste, air An air supply portion 551 for supplying air to the jet portions 535 and 536, a fuel injection port 537 for supplying flammable waste, a lid 560 for sealing the fuel injection port 537, A gas discharge duct 570 that recovers gas at the side of the barrel 530 and a cooling means 510 installed so as not to come into direct contact with the combustible waste to cool the heat generated as the combustible waste is pyrolyzed.

According to the conventional pyrolysis and gasification furnace constructed as described above, combustible waste introduced through the fuel inlet 537 is ignited and pyrolyzed, combustible waste is pyrolyzed for a predetermined period of time, combustible gas is generated, And then discharged to the outside through the discharge duct 570 and can be secondarily combusted in facilities such as a gas combustion unit. At this time, an appropriate level of flammable gas can be generated by maintaining the proper temperature required for pyrolysis by the cooling means.

Meanwhile, the combustible gas generated by pyrolysis of the waste is supplied to the gas combustion unit for the secondary combustion through the gas discharge duct to perform the secondary combustion. When the pyrolysis gasification furnace is operated, the gas discharge duct is opened, It should be closed at the end. To this end, a damper capable of opening and closing is installed in the middle of the gas discharge duct. Conventionally, as a damper for opening and closing the gas discharge duct, a method of selectively opening and closing the gas discharge duct while advancing and retracting the slide plate in a direction perpendicular to the end surface of the duct by using a pneumatic cylinder is used.

However, due to the characteristics of the flammable gas, foreign matter such as tar adheres to a gap where the slide plate moves forward and backward after a predetermined time, thereby narrowing the gap or blocking the gap in the severe case so that the sliding movement of the slide plate is hindered and acts as a proper damper There is a problem in that the apparatus may be damaged.

Generally, in pyrolysis gasification, two or more individual units are connected to one gas combustion unit to perform alternating operation. When pyrolysis is completed in one gasification furnace, pyrolysis starts in another gasification furnace, The door is opened to clean the remaining material after pyrolysis. At this time, the foreign matter generated in the pyrolysis process is attached to the movement guide of the slide plate and the gap where the slide plate is advanced and retreated, so that even if the gas discharge duct is closed by the slide plate, There is a problem that external air introduced during the re-cleaning process flows into the cylinder of the gasification furnace undergoing pyrolysis through the gap, which hinders the pyrolysis process.

In addition, there is a problem that the slide plate is heated by the combustible gas at a high temperature of about 400 to 800 DEG C to cause thermal deformation, thereby deteriorating the damping performance.

Patent Registration No. 10-1218361 (December 27, 2012)

The present invention has been made in order to solve the problems of the prior art as described above, and it is an object of the present invention to provide a damping apparatus capable of performing a proper damping operation in spite of the influence of foreign matter such as tar, It is an object of the present invention to provide a pyrolysis gasifier furnished with a damping device for a gas discharge duct having a long durability and excellent damping performance.

According to an embodiment of the present invention, A gas exhaust duct provided at an upper portion of the cylinder and providing a passage through which a combustible gas generated by pyrolysis of the waste flows and is discharged from the cylinder; And a damping unit provided in the gas discharging duct and selectively blocking the gas flow passage in the gas discharging duct, wherein the damping unit is connected to the gas discharging duct, and the space communicating with the inside of the gas discharging duct A cylinder housing formed therein; A damping cylinder fixed to the cylinder housing and including a cylinder shaft provided so as to be able to advance and retreat toward an inner space of the cylinder housing; And a damping slide plate connected to the cylinder shaft and selectively slidably moved from the cylinder housing to the inside of the gas discharge duct by operation of the cylinder shaft to seal the gas flow passage in the gas discharge duct. A pyrolysis gasification furnace can be provided.

A cylinder fixing plate coupled to an upper end of the cylinder housing and to which the damping cylinder is fixed; And a cylinder fixing portion for fixing the damping cylinder to the cylinder fixing plate.

The damper connecting housing further includes a damper connecting housing installed in the middle of the gas discharging duct and connected to the cylinder housing to provide a path through which the damping slide plate can be slidably moved. A pyrolysis and gasification furnace in which a through hole corresponding to an inner flow path of the duct is formed can be provided.

The pyrolysis and gasification furnace may further include a reinforcing bar connected to the side wall of the damper connecting housing and fixed to the gas discharging duct to support the damper connecting housing.

And a foreign matter receiving hopper which is connected to a lower end of the damper connecting housing and is provided so that foreign matter accumulated in the damper connecting housing is received therein and which provides a discharge passage through which the foreign matter can be discharged to the outside A pyrolysis gasification furnace can be provided.

The pyrolysis and gasification furnace further includes a rotary valve provided at a lower portion of the foreign matter receiving hopper and discharging the foreign substances contained in the foreign matter receiving hopper to the outside while keeping the inside of the foreign matter receiving hopper closed. .

The rotary valve includes a plurality of rotating blades configured to continuously rotate, and an end of the rotating blades is brought into close contact with an inner wall surface of the rotary valve to seal the inside of the foreign material receiving hopper, A pyrolysis gasification furnace in which foreign matter is discharged to the outside by rotation of the wing can be provided

The damping slide plate may further include a cooling water pipe connected to the damping slide plate and provided to supply the cooling water to the inside of the damping slide plate. A pyrolysis gasification furnace can be provided.

Also, the cooling water pipe may be provided with a pyrolysis and gasification furnace, which is formed longer than the stroke length of the cylinder shaft and is installed through the cylinder housing.

The damping slide plate may further include a plate reinforcing plate inserted into the reinforcing plate mounting hole, wherein at least one reinforcing plate mounting hole is formed on both surfaces of the damping slide plate.

The plate reinforcing plate may be provided through the inner space of the damping slide plate and may be provided in the damping slide plate so as not to protrude from both surfaces of the damping slide plate. have.

According to the embodiments of the present invention, it is possible to minimize the influence of foreign matter such as tar, which may be generated in the pyrolysis process, on the damping process of the gas discharge duct, and to improve the damping performance and the life of the damping device of the gas discharge duct .

1 is a conceptual view showing a pyrolysis and gasification furnace according to an embodiment of the present invention.
Fig. 2 is a top view of the cross section of the barrel of Fig. 1. Fig.
3 is a front view showing a damping unit installed in a gas discharge duct of the pyrolysis gasification furnace of FIG.
4 is a plan view of the damping unit of Fig.
Fig. 5 is a cross-sectional view taken along line AA of Fig. 3, showing a state in which the gas flow path of the gas discharge duct is closed by the damping slide plate.
Fig. 6 is a cross-sectional view taken along line AA of Fig. 3, in which the damping slide plate is retracted from the gas discharge duct to open the gas flow path.
7 is an enlarged view of a portion B in Fig.
FIG. 8 is a diagram showing the duct unit of the gas discharge duct of FIG. 3 in a trigonometric manner.
Figure 9 is a front view of the duct connecting housing of Figure 3;
10 is a CC sectional view of Fig.
11 is a front view showing the damping slide plate of Fig.
12 is a DD sectional view of Fig.
13 is a view showing the internal structure of a conventional pyrolysis gasification furnace.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

1 and 2, a pyrolysis and gasification furnace 1 according to an embodiment of the present invention includes a cylinder 10 through which combustible waste is injected and pyrolyzed, a cylinder 10 disposed below the cylinder 10, A gas burning section 30 in which a gas generated by pyrolysis of flammable waste is burnt in a cylinder 10 and a cylinder 10 and a bottom door section 20 are supported As shown in FIG.

Examples of pyrolytic wastes include SRF molded fuels, Sobel forged solid fuels, Bio-SRF solid fuels, waste tires, TDF made from waste tires in chip form, other municipal waste or industrial waste Mechanical crushing, crushing, and combustible mixed waste produced for selective recycling.

The cylinder section 10 includes a waste combustion chamber 100 having a pyrolysis space 108 in which waste is thermally decomposed, a lid 110 for opening and closing an upper surface of the waste combustion chamber 100, A check door 120 that opens and closes the check hole 124 communicating with the outside of the space 108 and a check door 120 that is disposed inside the pyrolysis space 108 while being connected to the side cooling jacket 102 to supply a combustible gas to the waste combustion chamber 100 A gas induction refrigerant pipe 130 which is provided at a lower portion of the cylinder 10 to ignite the waste and an ignition unit 140 which is provided in the pyrolysis space 108, An air supply nozzle 150 for supplying air and a gas exhaust duct 160 provided at an upper portion of the cylinder 10 to discharge a combustible gas generated by thermal decomposition of the waste, A lower flange 170 may be provided.

The upper portion of the pyrolysis space 108 is opened / closed by the lid 110, and the lower portion is opened / closed by the bottom door portion 20, which will be described later. In addition, when the waste combustion chamber 100 is closed by the lid 110 and the bottom door portion 20, the sealed state with respect to the outside is maintained. Accordingly, the combustion flame, gas, and the like in the waste combustion chamber 100 may not be discharged to the outside while the waste is pyrolyzed.

In addition, the waste combustion chamber 100 may be constructed by laminating the side fireproof wall 104 - side cooling jacket 102 - outer wall 106 in this order from the inside to the outside. The side cooling jacket 102 is configured to receive the refrigerant from the outside to allow the refrigerant to flow therein, and the temperature of the refrigerant flowing through the inside cooling jacket 102 can be increased by heat exchange with the thermal decomposition space 108. The heat energy accumulated in the refrigerant can be discharged to the outside and recycled.

A side fire wall 104 is disposed between the side cooling jacket 102 and the pyrolysis space 108. The side fire wall 104 is made of a material having heat insulating performance and is provided with a side cooling jacket 102 and a pyrolysis space 108, thereby preventing the refrigerant in the side cooling jacket 102 from becoming excessively high or preventing the temperature inside the pyrolysis space 108 from becoming excessively low. The thickness t of the side fire wall 104 can be determined within the range of 50 to 60 mm and the thickness t of the side fire wall 104 is determined within this thickness range, There is no danger, and the problem that the pyrolysis temperature rises too much can be solved.

The lid 110 has an upper refractory wall 112 formed inside the waste combustion chamber 100 to prevent the heat inside the waste combustion chamber 100 from being discharged upward when the lid 110 is closed. Further, the lid 110 can be easily opened and closed as one end of the lid 110 is configured to be pivotable with respect to the waste combustion chamber 100. A hinge 116 is provided at one end of the lid 110 to connect the lid 110 to the waste combustion chamber 100 so as to be rotatable with the waste combustion chamber 100. When the lid 110 is closed, A sealing member 114 may be provided on a lower surface of the lid 110 in contact with the upper portion of the waste combustion chamber 100 at a portion contacting the waste combustion chamber 100. Such a sealing member 114 can prevent the gas inside the waste combustion chamber 100 from being discharged to the outside.

The inspection door 120 is provided on the side surface of the waste combustion chamber 100 and is provided to open and close the inspection hole 124 communicating with the outside of the pyrolysis space 108. The inspection hole 124 is formed in the waste combustion chamber 100, And may be provided for access to the interior. Further, a portion of the side cooling jacket 102 surrounding the check hole 124 may be provided with the door side fire wall 122. [ Thus, the cold air of the side cooling jacket 102 can prevent the combustible gas in the check hole 124 from being locally liquefied and causing the crank phenomenon to occur in the check hole 124.

Further, the door-side refractory wall 122 may be provided in a thickness of 200 to 300 mm and may be formed to be thicker than the side refractory wall 104. This is because the check hole 124 is a very narrow space as compared with the pyrolysis space 108 where combustible waste is accumulated and pyrolyzed and there is a risk of cranking due to cooling rather than a risk that the pyrolysis temperature of the pyrolysis waste will rise excessively It is necessary to further increase the cooling prevention effect of the internal space of the check hole 124 than the pyrolysis space 108.

The gas induction refrigerant pipe 130 is connected to both the upper and lower ends of the side cooling jacket 102 and is disposed inside the pyrolysis space 108 and is generated through pyrolysis and combustible wastes introduced into the pyrolysis space 108 So as to directly exchange heat with the combustible gas. The temperature inside the pyrolysis space 108 can be controlled more precisely by directly performing the heat exchange with the pyrolysis waste and the gas generated therefrom by the refrigerant flowing into the gas induction refrigerant pipe 130 in this way. To this end, a valve (not shown) is provided in the gas-guided refrigerant pipe 130 so that the flow rate of the refrigerant flowing in the pipe can be controlled according to the internal temperature of the waste combustion chamber 100.

2, a plurality of gas-driven refrigerant pipes 130 may be disposed along the circumference of the waste combustion chamber 100, and specifically, a plurality of pairs of two adjacent pairs of the gas- .

In addition, the pair of gas-guided refrigerant pipes 130 may have a bent portion at each of the upper and lower portions, and may have a vertically extending shape connecting the upper and lower bent portions. In this case, the up-and-down direction may be a direction perpendicular to the paper surface or a direction inclined at a predetermined angle with respect to the paper surface. Accordingly, a portion extending in the vertical direction of the gas-guided refrigerant pipe 130 is disposed so as to be spaced apart from the side-wall fire-proof wall 104, so that the gas rising space 132 can be formed.

When flammable waste is injected into the waste combustion chamber 100, pyrolysis occurs from the lower portion of the waste combustion chamber 100, thereby generating flammable gas from the lower portion of the combustible waste. At this time, the gas generated by pyrolysis rises to the upper part of the waste combustion chamber 100 and is discharged to the outside through the gas discharge duct 160. However, the gas which is raised due to the wastes accumulated in the waste combustion chamber 100 There is a problem that it is difficult to discharge the gas smoothly.

However, according to the present embodiment, the combustible waste can be prevented from permeating into the gas rising space 132 by the gas induction refrigerant pipe 130. Accordingly, a space in which the combustible gases generated in the lower portion of the waste combustion chamber 100 can smoothly ascend to the upper portion can be secured, thereby enabling smooth gas discharge.

The ignition unit 140 may be formed at the lower portion of the cylinder 10 to ignite flammable waste in the waste combustion chamber 100 to generate a flame and to start pyrolysis. The ignition unit 140 may be installed at a plurality of positions along the periphery of the waste combustion chamber 100, and may be disposed at four positions at regular intervals, for example. When a plurality of ignition units 140 are provided, they can be collectively controlled by a control unit (not shown).

The air supply nozzle 150 functions to supply the air supplied from an external blower (not shown) to the inside of the waste combustion chamber 100. The air supply nozzle 150 can be provided on an inclined surface formed at the lower portion of the cylinder 10 and pyrolyzed gradually from the lower part of the flammable waste accumulated in the waste combustion chamber 100 to the upper part, It is advantageous. However, the spirit of the present invention is not limited to this, and the air supply nozzle 150 may be formed at a central portion or an upper portion of the cylinder.

The gas discharge duct 160 is provided at an upper portion of the barrel 10 to provide a passage through which combustible gas generated by pyrolysis in the waste combustion chamber 100 is discharged. At this time, the gas exhaust duct 160 is composed of an outer wall made of a material such as concrete, duct refractory wall 164 made of a material having a heat insulating function such as castable, etc., and even if a high temperature flows the combustible gas, And the like can be avoided.

The gas exhaust duct 160 is connected to the gas combustion unit 30 and the combustible gas is delivered to the gas combustion unit 30 through the gas exhaust duct 160 to perform the secondary combustion. The gas combustion section 30 may include a gas combustion chamber 310 having a gas combustion space 312 and an air supply pipe 320 for supplying outside air to the gas combustion space 312. Further, the gas exhaust duct 160 is provided with a damping unit 200 for selectively blocking the flow path of the combustible gas. A specific configuration of the damping unit 200 will be described later.

The lower flange 170 may have a rectangular shape and may have a communication hole communicating with the pyrolysis space 108 therein. The lower flange 170 is a member attached to the lower surface of the waste combustion chamber 100. When the lower flange 170 is pressed by the seal ring of the bottom door portion 20, the gap between the waste combustion chamber 100 and the bottom door portion 20 And may include a packing member that is sealed. The packing member may be made of an elastic material for constituting a sealing environment and may be provided opposite to the bottom door portion 20 and may be provided in the shape of a rectangular ring depending on the shape of the lower flange 170.

The bottom door portion 20 is disposed below the tubular portion 10 to selectively seal the tubular portion 10 so that the bottom door portion 20 can be retracted in both directions along the guide rail 410 of the support portion 40 . Accordingly, the bottom door portion 20 can close the lower portion of the barrel portion 10 when it enters the lower side of the barrel portion 10.

Hereinafter, the specific structure of the damping unit 200 in which the flow of the combustible gas is selectively blocked by opening and closing the gas discharge duct 160 will be described with reference to Figs. 3 to 12. Fig.

3 to 12, the damping unit 200 includes a damping cylinder 210, a cylinder housing 220, a damper connecting housing 230, a foreign matter receiving hopper 240, a damping slide plate 250, (Not shown).

The damping unit 200 may be provided in the duct unit 162 constituting a part of the gas discharge duct 160. The duct unit 162 is separately formed from the remaining portion of the gas discharging duct 160 and is coupled to the remaining portion of the gas discharging duct 160 in a state where the damping unit 200 is installed to form one gas flow path , Which can provide convenience in manufacturing. However, the present invention is not limited thereto, and the damping unit 200 may be installed in the middle of the gas discharge duct 160 manufactured by a single duct. Hereinafter, a configuration in which the duct unit 162 is separately manufactured and the damping unit 200 is installed will be described as an example.

The duct unit 162, which is separately manufactured, is flanged at both ends, and the flange formed at both ends and the flange formed at the remaining portion of the gas discharge duct 160 are screwed together, so that the gas discharge duct 160 is formed . The duct unit 162 and the gas discharge duct 160 may be connected to each other through various methods that can be used for the duct fastening. ) Can be fastened.

The damping cylinder 210 and the cylinder fixing plate 212 may be connected to the cylinder housing 220 through the cylinder fixing plate 212 and the cylinder fixing plate 212 may be fixed by the cylinder fixing portion 216 Can be fixed. A cylinder shaft 214 is accommodated in the damping cylinder 210. The cylinder shaft 214 is drawn out of the damping cylinder 210 by hydraulic pressure to enter the cylinder housing 220, To the interior of the damping cylinder 210.

The cylinder housing 220 may be provided in the form of a rectangular parallelepiped shell having a receiving space therein. The upper end of the cylinder housing 220 is coupled to the cylinder fixing plate 212 to which the damping cylinder 210 is fixed, and the lower end thereof is connected to the damper connecting housing 230 . A fixing bracket 222a is fixed to a lower side surface of the cylinder housing 220 and a fixing bracket 222a is fixed to an upper connecting flange 232 formed at an upper end of the damper connecting housing 230 and a plurality of fixing bolts 222c and a fixing nut 222d.

The lower end of the cylinder housing 220 has a sliding gap 238 formed in the form of an upper end opening of the upper connecting flange 232 Lt; / RTI > At this time, the damper connecting housing 230 also has a hollow communicating with the sliding gap 238, and a through hole 236 formed at the center of the damper connecting housing 230. The damping slide plate 250 can communicate with the inner space of the cylinder housing 220 and the inner space of the damper connecting housing 230 and the inner flow path of the duct unit 162 through the communication space, Can enter the interior of the unit 162, or can be retracted from the duct unit 162.

The damper connecting housing 230 can be installed in the middle of the duct unit 162 and can be installed to divide the duct unit 162 into two. At this time, both sides of the damper connecting housing 230 can be connected and fixed to the respective divided portions of the duct unit 162 by welding or the like. Even if the damper connecting housing 230 is installed so as to divide the duct unit 162 midway through the through hole 236 formed in the damper connecting housing 230, the damper connecting housing 230 allows the duct unit 162 ) May not be blocked. The upper connection flange 232 formed at the upper end of the damper connection housing 230 is connected to the cylinder housing 220 and the lower connection flange 234 formed at the lower end of the damper connection housing 230 connects the foreign matter receiving hopper 240 ).

Also, a sliding gap 238 may be formed in the form of a lower end opening of the lower connection flange 234. The sliding gap 238 formed at the upper end of the upper connection flange 232 and the lower end of the lower connection flange 234 can guide the sliding movement of the damping slide plate 250. [

When foreign matter such as tar contained in the combustible gas flowing in the duct unit 162 of the gas discharge duct 160 is accumulated in the sliding gap 238 of the damper connecting housing 230, The damping slide plate 250 can be opened and closed to provide a space in which the foreign object can be temporarily lowered and accommodated, and the foreign object temporarily accommodated can be discharged to the outside. Specifically, the foreign matter receiving hopper 240 is connected to the lower connection flange 234 through the hopper fixing portion 244, and is sealingly connected to the inside of the duct unit 162 through the lower connection flange 234. At this time, the sliding gap 238 formed in the lower connection flange 234 can communicate with the inner space of the foreign material receiving hopper 240. A lower portion of the foreign substance receiving hopper 240 may be provided with a driving unit 246 connected to the rotary valve 242 and the rotary valve 242 to selectively rotate the rotary valve 242.

The rotary valve 242 is provided in the lower part of the foreign matter receiving hopper 240 communicating with the duct unit 162 through the lower connection flange 234. In addition, the rotary valve 242 can be maintained in a state where four to six rotating blades rotate at a low speed, and the foreign material scraped off while the damping slide plate 250 descends passes through the foreign material receiving hopper 240, Falls to the rotating blades of the rotating shaft 242, and then is discharged to the outside by the rotating blades rotating at low speed. At this time, since the end of the rotary vane of the rotary valve 242 is in close contact with the inner wall surface of the rotary valve 242, the inside of the gas discharge duct 160, which communicates with the foreign substance receiving hopper 240, Can be maintained.

The damping slide plate 250 is connected to the cylinder shaft 214 of the damping cylinder 210 by the cylinder shaft holder 252 and is advanced and retracted into the duct unit 162 by the reciprocating movement of the cylinder shaft 214 . When the cylinder shaft 214 is completely retracted into the damping cylinder 210 and positioned at the bottom dead center, the damping slide plate 250 is accommodated in the cylinder housing 220 and the cylinder shaft 214 is housed in the damping cylinder 210. [ The free end of the damping slide plate 250 is positioned at the lower end of the damper connecting housing 230 through the sliding gap 238 of the lower connecting flange 234 when the free end of the damping slide plate 250 is completely drawn out from the inside of the damper connecting housing 210 do.

Accordingly, when the cylinder shaft 214 is located at the bottom dead center, the internal gas flow path of the duct unit 162 is completely opened to allow the flow of the combustible gas. When the cylinder shaft 214 is located at the top dead center, The internal gas flow path of the unit 162 is completely closed so that the flow of the combustible gas can be shut off. As described above, the duct unit 162 can be opened and closed by the operation of the damping cylinder 210.

In addition, the damping slide plate 250 may have a space through which the cooling water can flow, and the damping slide plate 250 may be formed of a double jacket. A cooling water pipe 270 may be connected to the upper surface of the damping slide plate 250. Cooling water may be supplied from the cooling water supply unit (not shown) including the pump or the like through the cooling water pipe 270 to be forcedly flowed into the inner space of the damping slide plate 250. Accordingly, the cooling water forced to flow into the inner space of the damping slide plate 250 can cool the damping slide plate 250 to prevent thermal deformation of the damping slide plate.

A plurality of reinforcing plate mounting holes 253 may be formed on both sides of the damping slide plate 250. A plate reinforcing plate 254 may be inserted into the reinforcing plate mounting holes 253. At this time, the plate reinforcing plate 254 is installed through the inner space of the damping slide plate 250 and can be welded and fixed to the inside of the damping slide plate 250. The plate reinforcing plate 254 is provided to be inserted into the damping slide plate 250 so as not to protrude from both sides of the damping slide plate 250 in order to avoid interference when sliding the damping slide plate 250 Can be provided. Further, the plurality of reinforcing plate mounting holes 253 may be formed to be arranged in a predetermined pattern. Such plate reinforcing plate 254 can prevent thermal deformation such as twisting of the damping slide plate 250.

A reinforcing bar 239 may be welded to the side wall of the damper connecting housing 230 to suppress the thermal deformation of the damper connecting housing 230 so as to be formed in the duct fire wall 164 of the duct unit 162. For example, the reinforcement 239 may be provided in the form of a castable anchor within the duct fire wall 164 provided as a castellator. Accordingly, the reinforcing bar 239 is provided in a state of being embedded in the duct refractory wall 164 to strongly support the damper connecting housing 230 while suppressing thermal deformation.

An end portion of the damper connecting housing 230 facing the inside of the duct unit 162 may be formed with an inclined portion 237 formed by tapering. Even if the damper connecting housing 230 is partially deformed due to the inclined portion 237, interference with the sliding movement path of the damping slide plate 250 can be prevented.

The cooling water pipe 270 may be formed longer than the stroke length of the cylinder shaft 214 and may be installed through the cylinder housing 220. Accordingly, when the cylinder shaft 214 is positioned at the bottom dead center, it can be protruded to the upper portion of the cylinder housing 220. The cooling action of the cooling water supplied to the inside of the damping slide plate 250 through the cooling water pipe 270 causes the thermal deformation of the damping slide plate 250 despite the high temperature heat inside the gas exhaust duct 160 And the life of the damping unit 200 can be prolonged.

When the remaining material on the bottom door portion 20 is cleaned by pyrolysis in the cylinder 10 through the damping unit 200 having the above-described structure, residual heat does not flow backward, and the gas combustion portion The gas exhaust duct 160 can be closed so that outside air is not introduced into the gas combustion unit 30 even when another gasifier connected to the gas combustion unit 30 is operating.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, You will understand. For example, a person skilled in the art can change the material, size and the like of each constituent element depending on the application field or can combine or substitute the embodiments in a form not clearly disclosed in the embodiments of the present invention, Of the range. Therefore, it should be understood that the above-described embodiments are to be considered in all respects as illustrative and not restrictive, and that such modified embodiments are included in the technical idea described in the claims of the present invention.

1: pyrolysis gasification furnace 10: cylinder
100: waste combustion chamber 110: lid
120: Inspection door 130: Gas-induced refrigerant tube
140: ignition unit 150: air supply nozzle
160: gas discharge duct 162: duct unit
170: lower flange 200: damping unit
210: damping cylinder 212: cylinder fixing plate
214: cylinder shaft 216: cylinder fixing portion
220: cylinder housing 222: housing fixing portion
230: damper connection housing 232: upper connection flange
234: Lower connection flange 238: Sliding gap
239: Reinforcing bar 240: Foreign matter receiving hopper
242: Rotary valve 244: Hopper fixing section
250: Damping slide plate 252: Cylinder shaft holder
270: cooling water pipe 20: bottom door part
30: gas combustion unit 310: gas combustion chamber
312: gas combustion space 320: air supply pipe
40: Support part 400: Support frame
410: Guide rail 420: Combustion product removal unit

Claims (11)

A cylinder into which waste is injected and pyrolyzed;
A gas discharge duct provided at an upper portion of the cylinder and providing a passage through which a combustible gas generated by pyrolysis of the waste flows and is discharged from the cylinder;
And a damping unit provided in the gas discharge duct and selectively blocking the gas flow passage in the gas discharge duct,
Wherein the damping unit comprises:
A cylinder housing connected to the gas discharge duct and having a space communicating with the inside of the gas discharge duct;
A damping cylinder fixed to the cylinder housing and including a cylinder shaft provided so as to be able to advance and retreat toward an inner space of the cylinder housing;
A damping slide plate connected to the cylinder shaft and selectively slidable from the cylinder housing to the inside of the gas discharge duct by operation of the cylinder shaft to seal the gas flow passage in the gas discharge duct;
A damper connecting housing installed in the middle of the gas discharge duct and connected to the cylinder housing to provide a path through which the damping slide plate can slide;
A foreign matter receiving hopper which is connected to a lower end of the damper connection housing and is provided so that foreign substances accumulated in the damper connection housing can be received therein and which provides a discharge passage through which foreign matter can be discharged; And
And a rotary valve provided at a lower portion of the foreign matter receiving hopper and discharging the foreign matter contained in the foreign matter receiving hopper to the outside while keeping the inside of the foreign matter receiving hopper closed.
By pyrolysis gasification. The method according to claim 1,
A cylinder fixing plate coupled to an upper end of the cylinder housing and to which the damping cylinder is fixed; And
Further comprising a cylinder fastening portion for fastening the damping cylinder to the cylinder fastening plate.
By pyrolysis gasification. The method according to claim 1,
And a through hole corresponding to an inner flow path of the gas discharge duct is formed at a central portion of the damper connection housing.
By pyrolysis gasification. The method of claim 3,
Further comprising a reinforcing bar connected to a side wall of the damper connecting housing and fixed to the gas discharging duct to support the damper connecting housing,
By pyrolysis gasification. delete delete The method according to claim 1,
The rotary valve includes:
A plurality of rotating blades configured to rotate continuously,
The end of the rotary vane is brought into close contact with the inner wall surface of the rotary valve to seal the inside of the foreign matter receiving hopper,
Wherein a plurality of the rotating blades are rotated to discharge foreign substances to the outside,
By pyrolysis gasification. The method according to claim 1,
The inside of the damping slide plate is made of a double jacket into which cooling water can flow,
Further comprising a cooling water pipe connected to the damping slide plate and provided to supply the cooling water into the inside of the damping slide plate,
By pyrolysis gasification. 9. The method of claim 8,
The cooling water pipe
The cylinder housing being formed to be longer than the stroke length of the cylinder shaft,
By pyrolysis gasification. The method according to claim 1,
Wherein at least one reinforcing plate mounting hole is formed in both surfaces of the damping slide plate,
And a plate reinforcing plate inserted and installed in the reinforcing plate mounting hole,
By pyrolysis gasification. 11. The method of claim 10,
Wherein the plate reinforcing plate is installed through the inner space of the damping slide plate,
The damping slide plate being inserted into the damping slide plate so as not to protrude from both sides of the damping slide plate,
By pyrolysis gasification.

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