KR101359087B1 - Complex combustioin chamber of vibrating type - Google Patents

Abstract

The present invention relates to a composite combustion chamber for combusting gas matters of solid fuel and unburned matters passing through a thermal decomposition path and more specifically, a combustion chamber including a vibration combustion chamber combusting the unburned matters which cannot be gasified while being vibrated by a vibrator. The composite combustion chamber (100) includes a main combustion chamber (100) combusting the gas matters and the vibration combustion chamber (120) combusting the unburned matters generated in the thermal decomposition path (30).

Description

Complex combustion chamber of vibration system {COMPLEX COMBUSTIOIN CHAMBER OF VIBRATING TYPE}

The present invention is a combustion chamber for burning gaseous substances and unburned materials of a solid fuel passed through a pyrolysis furnace, and particularly includes a vibrating combustion chamber for conveying and burning unburned materials while being vibrated by a vibrator.

In general, a pyrolysis apparatus gasifies solid fuel such as waste plastic and sludge, and supplies a relatively high-calorie synthesis gas to a combustion chamber or the like as is widely known.

In the pyrolysis apparatus, as described above, not only the gaseous substance that is the target of combustion is discharged, but also unburned powder, tar, or char (hereinafter, referred to as unburned substance).

In the case of such unburned material, it is conventionally put in a combustion chamber and combusted like the gaseous material.

However, in the conventional combustion chamber as described above, the unburned material naturally falls to the bottom of the combustion chamber by gravity and thus does not sufficiently burn.

On the other hand, the technique of the pyrolysis device or the combustion chamber is well known and is described in detail in the following prior art document, and thus redundant description and illustration are omitted.

U.S. Registered Patent # 6112677 Japanese Laid-Open Patent No. 2001-521056 Korea Patent Registration No.1161867 Korean Registered Patent No.1024291 Korean Registered Patent No. 0628290 Korean Unexamined Patent No. 2013-0084913 Korean Unexamined Patent No. 2007-0034543 Korean Patent Publication No. 2005-0119968

The present invention is to solve the above-mentioned problems, including the vibration combustion chamber vibrated by the vibrator, the unburned material is lowered to the floor and is not stagnant, the stagnant prevention and movement of the unburned material by the vibrator, and also to stay in the movement to the outlet An object of the present invention is to provide a vibrating complex combustion chamber capable of completely burning unburned material by increasing time.

The present invention for achieving the above object is a composite combustion chamber 100 for burning the gaseous material and unburned material of the solid fuel passing through the pyrolysis furnace 30, the composite combustion chamber 100 is the main combustion chamber for burning the gaseous material And a vibrating combustion chamber 120 for burning unburned material, wherein the vibrating combustion chamber 120 is installed at one side of the main combustion chamber 110 and communicates with the main combustion chamber 110. There is one feature of the composite combustion chamber of the vibration system including a main body 121 and the vibrator (V) provided on one side of the vibration combustion chamber main body 121.

At this time, the vibration combustion chamber main body 121 includes a hollow combustion chamber inner cylinder 121b and a vibration combustion chamber outer cylinder 121a, and is installed on one side of the vibration combustion chamber main body 121, and thus, the vibration combustion chamber inner cylinder 121b. Cooling water supply unit 125 for injecting coolant into the water jacket 129 which is a space between the outer combustion chamber outer cylinder 121a and the coolant discharge unit installed at the other side of the vibrating combustion chamber body 121 to discharge the cooling water ( It is also possible to include 127).

In addition, the vibration combustion chamber body 121 is installed on one side of the main combustion chamber 110 and the coil spring 123 is elastically connected between the vibration combustion chamber body 121 and the main combustion chamber 110 is installed and vibrated. It is also possible to include a heat-resistant flexible 122 that absorbs.

In addition, the vibration combustion chamber main body 121 is provided on one side and includes an air supply unit 124 for injecting air into the vibration combustion chamber inner cylinder 121b, the air supply 124 is the vibration combustion chamber inner cylinder 121b It is also possible to include a pipe-shaped air supply unit main body 124a which is installed inside the air supply, and a plurality of discharge holes 124b which are formed on the outer periphery of the air supply unit main body 124a to discharge air.

In addition, the main combustion chamber 110 is installed on one side of the main combustion chamber main body 111 including the main combustion chamber inner cylinder (111b) and the main combustion chamber outer cylinder (111a) of the hollow shape, and the main combustion chamber main body 111 is the thermal decomposition Combustion chamber injection unit 113 through which the gaseous material and unburned material of the solid fuel passing through the furnace 30 are injected, and a combustion gas discharge unit formed on the other side of the main combustion chamber main body 111 to discharge the burned material. 114, the castable 112 installed inside or outside the main combustion chamber inner cylinder 111b, and the main combustion chamber outer cylinder 111a and the castable provided on one side of the main combustion chamber main body 111. It is also possible to include a coolant water supply unit 117a for injecting coolant into the water jacket 115, which is a space between 112, and a coolant discharge unit 117b for discharging the coolant.

In addition, the main combustion chamber body 111 is provided on one side includes an air injection unit 116 for injecting air into the inner combustion chamber inner cylinder (111b), the air injection unit 116 is the main combustion chamber outer cylinder (111a) The air supply duct 116a installed at one side, the air chamber 116b including the space between the main combustion chamber outer cylinder 111a and the castable 116e, and the castable 116e are installed to penetrate the air. It is also possible to include an air nozzle 116c injected into the main combustion chamber inner cylinder 111b.

In addition, further comprising a combustion material discharge device 200 communicated to one side of the vibration combustion chamber 120, the combustion material discharge device 200 and the chamber (C) communicated to one side of the vibration combustion chamber 120 It is also possible to include a gate (G) installed on one side of the chamber (C) to open and close the inside of the chamber (C).

In addition, the gate G includes a first gate G1 and a second gate G2 disposed in the vertical direction of the chamber C, and the chamber C is located above the first gate G1. It is also possible to include a first chamber C1 disposed on the side, and a second chamber C2 disposed between the first gate G1 and the second gate G2.

In addition, a connection chute 210 communicating with the first chamber C1 and the vibration combustion chamber 120, a heat-resistant flexible 220 installed between the connection chute 210 and the first chamber C1, Including the inner duct 230, which is installed inside the heat-resistant flexible 220, installed on the connection chute 210 side and the outer duct 240 installed on the first chamber (C1) side, the inside Duct 230 may be inserted into the outer duct 240.

It is also possible to include a first air cylinder 250 and a second air cylinder 260 operating the first gate G1 and the second gate G2.

In addition, the pyrolysis furnace 30 and the main combustion chamber 110 further comprises a combustion promoting unit 300, the combustion promotion unit 300, one side is in communication with the pyrolysis furnace 30 and the other side Induction duct 330 in communication with the combustion chamber injection unit 113 of the main combustion chamber 110, and the air supply unit 310 is in communication with one side of the induction duct 330, the induction duct 330 Including the inner and outer duct 331 and the outer duct 332 is installed, the air supply unit 310 may be in communication with the space between the inner duct 331 and the outer duct 332.

The features and advantages of the present invention will become more apparent from the following detailed description based on the accompanying drawings.

Prior to that, terms and words used in the present specification and claims should not be construed in a conventional and dictionary sense, and the inventor may properly define the concept of the term in order to best explain its invention It should be construed as meaning and concept consistent with the technical idea of the present invention.

In accordance with the present invention as described above to prevent the unburned material falling on the floor to accumulate, by using a vibrating body to move the unburned material little by little to complete combustion in the combustion chamber and then to discharge the combustion material to the outside, the combustion chamber By increasing the residence time of the unburned dust in the interior there is an effect that can completely burn the unburned material.

1 is a front view of a composite combustion chamber according to an embodiment of the present invention,
2A and 2B are conceptual views illustrating a side view and a supply nozzle of an air injection unit viewed from a side in which fuel is injected as a complex combustion chamber according to an embodiment of the present invention;
3 is a side view as viewed from the side of the combustion gas is discharged as a complex combustion chamber according to an embodiment of the present invention,
4A and 4B are perspective views illustrating a combustion accelerator according to an embodiment of the present invention;
5 is a conceptual diagram illustrating a coupling relationship between a combustion accelerator and a pyrolysis furnace and a main combustion chamber according to an embodiment of the present invention;
6 is a conceptual diagram showing a combustion material discharge device according to an embodiment of the present invention,
7 is a conceptual diagram illustrating an air supply unit according to an embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The objectives, specific advantages, and novel features of the present invention will become more apparent from the following detailed description taken in conjunction with the accompanying drawings, in which: FIG. It should be noted that, in the present specification, reference numerals are added to the constituent elements of the drawings, and the same constituent elements have the same number as far as possible even if they are shown in different drawings. In addition, terms such as “first”, “second”, “one side”, and “other side” are used to distinguish one component from another component, and the component is limited by the terms. no. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

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

1 is a front view of a composite combustion chamber according to an embodiment of the present invention, Figures 2a and 2b is a side view and the air supply nozzle of the air injection portion as viewed from the side of the fuel injection as a composite combustion chamber according to an embodiment of the present invention 3 is a side view of the combustion gas discharged as a complex combustion chamber according to an embodiment of the present invention, Figure 4a and 4b is a perspective view showing a combustion accelerator according to an embodiment of the present invention 5 is a conceptual diagram illustrating a coupling relationship between a combustion accelerator and a pyrolysis furnace and a main combustion chamber according to an embodiment of the present invention, and FIG. 6 is a conceptual diagram illustrating a combustion material discharge device according to an embodiment of the present invention. 7 is a conceptual diagram illustrating an air supply unit according to an embodiment of the present invention.

The present invention is a composite combustion chamber 100 for burning the gaseous material and unburned material of the solid fuel passed through the pyrolysis furnace 30, as shown in Figures 1 to 3, the composite combustion chamber 100 is a gaseous material And a main combustion chamber 110 for burning and a vibrating combustion chamber 120 for burning unburned material.

At this time, the vibration combustion chamber 120 is installed on one side of the main combustion chamber 110, the hollow vibration combustion chamber body 121 and in communication with the main combustion chamber 110 and the vibration combustion chamber body 121 on one side It includes a vibrator (V) installed.

That is, the main combustion chamber 110 burns the gaseous material of the solid fuel passing through the pyrolysis furnace 30.

At this time, the unburned material is issued in the pyrolysis furnace 30, and includes unburned powder, tar, or char, and the like unburned material is lowered in the ground direction in the main combustion chamber 110. As a result, they do not burn completely.

The unburned material is introduced into the vibration combustion chamber main body 121 of the vibration combustion chamber 120, and the vibration combustion chamber main body 121 is vibrated by the vibrator V as described above.

Therefore, when the unburned material introduced into the vibrating body main body 121 descends to the bottom, the unburned material is moved little by little using the vibrating body, so that the time for staying in the space increases, thereby increasing the combustion time. Finally, complete combustion is possible.

Meanwhile, the vibrator V may be used as long as it is attached to one side of the vibrating combustion body 121 to transmit vibration to the vibrating combustion body 121, and for example, an eccentric motor that generates vibration, or A cylinder or the like installed on the vibrating combustion body 121 to generate vibration may be used, and a plurality of cylinders may be used.

As described above, the vibrating combustion chamber body 121 may include the vibrating combustion chamber body 121 and a vibrating combustion chamber outer cylinder 121a having a hollow shape.

That is, the vibration combustion chamber outer cylinder 121a is disposed outside the vibration combustion chamber inner cylinder 121b, and a space is formed between the vibration combustion chamber outer cylinder 121a and the vibration combustion chamber inner cylinder 121b.

In this case, the space is used as a water jacket 129 for circulating coolant, and a coolant water supply unit 125 for injecting coolant into the water jacket 129 is installed at one side of the vibrating combustion chamber body 121. The coolant discharge part 127 through which the coolant is discharged is installed at the other side of the vibrating combustion chamber body 121.

That is, as shown in FIG. 1, the coolant water supply part 125 is installed at the left side of the vibrating combustion chamber main body 121 in the drawing, wherein the coolant water supply part 125 vibrates with the vibration combustion chamber inner cylinder 121b. It may be installed between the combustion chamber outer cylinder 121a to allow the coolant to be introduced into the water jacket 129.

In addition, the coolant discharge part 127 may be installed at the upper right side of the drawing of the vibrating combustion chamber body 121, and the coolant discharge part 127 may also be disposed between the vibrating combustion chamber inner cylinder 121b and the vibrating combustion chamber outer cylinder 121a. Can be installed in the cooling water discharged.

Meanwhile, the vibrating combustion chamber body 121 may be disposed below the main combustion chamber 110 as shown in the figure, and may have a U-shaped cross section, which is an example for describing the present invention. Is a device capable of increasing the residence time of the unburned material and thereby completely burning the unburned material. Even if the vibrating combustion chamber body 121 has a different shape, all of them belong to the scope of the present invention. Of course.

In addition, the vibration combustion chamber body 121 is a vibration is transmitted by the vibrator (V), which is installed on one side of the main combustion chamber 110 in order to prevent the vibration is transmitted to the main combustion chamber 110 side. It is also possible to include a coil spring 123 on which the vibration combustion chamber body 121 is supported.

In addition, the vibration combustion chamber body 121 and the main combustion chamber 110 may be provided between the heat-resistant flexible 122 to absorb the vibration.

That is, the heat-resistant flexible 122 refers to a flexible material that can absorb vibrations and has heat resistance without burning even at a high temperature. The heat-resistant flexible 122 made of such a material is combined with the vibration combustion chamber body 121. Installed between the main combustion chamber 110 to block the vibration is transmitted to the main combustion chamber (110).

In addition, the vibrating combustion chamber body 121 is elastically connected to the main combustion chamber 110 by the coil spring 123 to prevent the vibration of the vibrating combustion chamber body 121 from being transmitted to the main combustion chamber 110. do.

On the other hand, as described above in the vibrating combustion chamber body 121, the unburned material is burned, and air must be supplied for the combustion. It may include an air supply unit 124 for injecting air to (121b).

That is, as shown in FIG. 1 and FIG. 7, the air supply part 124 is the air supply part 124 is installed inside the vibration combustion chamber inner cylinder 121b, and a pipe-shaped air supply part main body injecting air ( 124a and a plurality of discharge holes 124b formed on the outer periphery of the air supply unit body 124a to discharge air.

That is, after the air supply unit body 124a is inserted into the vibration combustion chamber inner cylinder 121b, air may be discharged through the discharge hole 124b to inject air into the vibration combustion chamber inner cylinder 121b.

Meanwhile, as illustrated in FIG. 2, the air supply unit 124 may include a pair spaced apart at a predetermined interval on the left side of the vibrating combustion chamber body 121, which is one of the air supply units 124. As described above, only the shape, position, and number of the air supply units 124 are all within the scope of the present invention as long as air can be injected into the vibrating combustion chamber inner cylinder 121b as described above. Of course.

The main combustion chamber 110 is installed in the upper side of the vibration combustion chamber 120 as described above.

The main combustion chamber 110 includes a main combustion chamber body 111 including a main combustion chamber inner cylinder 111b and a main combustion chamber outer cylinder 111a having a hollow shape as shown.

That is, the main combustion chamber main body 111 is provided with a main combustion chamber outer cylinder 111a outside the main combustion chamber inner cylinder 111b similarly to the vibration combustion chamber main body 121.

On the other hand, the main combustion chamber 110 is to burn the gaseous material passing through the pyrolysis furnace as described above, for this purpose is installed on one side of the main combustion chamber body 111 as shown in Figure 2 the pyrolysis furnace ( The combustion chamber injection unit 113 through which the gaseous material and the unburned material of the solid fuel passing through 30 are injected into the interior, and the material burned by being formed on the other side of the main combustion chamber body 111 as shown in FIG. 3 is discharged. Combustion gas discharge portion 114 is included.

At this time, the castable 112 is installed inside or outside the main combustion chamber inner cylinder 111b.

The castable 112 is a kind of refractory material that can withstand high temperatures as it is well known, and blocks the heat of the combustion heat from the inside of the combustion chamber to the outside, and the heat source partially radiated heat generated inside the main combustion chamber inner cylinder 111b. It will be delivered to the cooling water to be described later.

2 and 3, the main combustion chamber inner cylinder 111b may be installed inside the castable 122, but the present invention is not limited thereto, and the main combustion chamber inner cylinder 111b is castable. (122) It goes without saying that all of them belong to the scope of the present invention even if they are installed outside.

Meanwhile, a space between the main combustion chamber outer cylinder 111a and the castable 112 may function as a water jacket 115 through which coolant is circulated.

In this case, the coolant may include a coolant water supply part 117a installed at one side of the main combustion chamber main body 111 to inject the coolant and a coolant discharge part 117b through which the coolant is discharged.

That is, as shown in FIG. 1, the coolant water supply unit 117a may be installed at the left side of the drawing, and the coolant water supply unit 117b may be installed at the upper right side of the drawing.

Meanwhile, since air is required to burn unburned material and gaseous material in the main combustion chamber main body 111, it is installed at one side of the main combustion chamber main body 111 to inject air into the main combustion chamber inner cylinder 111 b. It may include an air injection unit 116.

In this case, the air inlet 116 is provided between the air supply duct 116a installed on one side of the main combustion chamber outer cylinder 111a, and the main combustion chamber outer cylinder 111a and the castable 116e as shown in FIG. 2A. It is also possible to include an air chamber 116b formed of a space, and an air nozzle 116c installed to penetrate the castable 116e and into which air is injected into the main combustion chamber inner cylinder 111b.

That is, the air may be injected through the air supply duct 116a and then temporarily stored in the air chamber 116b and finally injected into the main combustion chamber inner cylinder 111b through the air nozzle 116c.

As described above, a plurality of air nozzles 116c may be provided to penetrate the castable 116e. (See FIG. 2B).

In addition, the air supply duct 116a may be installed as two left and right sides as shown, which is just an example for explaining the present invention, and the air supply duct as long as air can be injected as described above. Even if the shape or number of 116a is changed, it is a matter of course that all belong to the scope of the present invention.

In addition, the air supply duct 116a may be installed in an inclined portion of the main combustion chamber outer cylinder 111a as shown, and another air supply duct (not shown) may be installed in the main combustion chamber outer cylinder 111a for additional air supply. It is also possible to install on the side.

Meanwhile, in the main combustion chamber 110 of the present invention, the gaseous material introduced from the pyrolysis furnace 30 is discharged from the pyrolysis facility 30 to meet with the outside air to ignite itself, and the unburned material is lowered down to be recomposed at the bottom. In some cases, the ignition part 118 may be separately installed in the vicinity of the injection part 113 of the main combustion chamber 110, as shown in FIG. 2.

At this time, the ignition unit 118 may be used as long as it can enter the main combustion chamber inner cylinder 111b to ignite.

In addition, it is also possible to include a monitoring window (W1) installed in the main combustion chamber 110 to monitor the interior and the manholes (M1, M2) for the inspection of the internal equipment, as shown in Figure 1 and 2, It is also possible to install the monitoring window (W2) on one side of the vibration combustion chamber (120).

Also, as shown in FIGS. 2A and 3, a wheel 130 installed at one side of the main combustion chamber 110 and a wheel installed at the bracket 130 to facilitate movement of the main combustion chamber 110 ( (Not shown).

As described above, the main combustion chamber 110 of the present invention combusts the gaseous material and the unburned material from the pyrolysis furnace 30, and to promote combustion in the main combustion chamber 110, FIGS. 4A, 4B and FIG. As shown in FIG. 5, it is also possible to further include a combustion accelerator 300 installed between the pyrolysis furnace 30 and the main combustion chamber 110.

In this case, the combustion promotion unit 300 is one side is in communication with the pyrolysis furnace 30 and the other side is induction duct 330 is in communication with the combustion chamber injection unit 113 of the main combustion chamber 110, the induction duct ( 330 may include an air supply unit 310 communicated with one side.

That is, air is injected through the air supply unit 310 and air is injected into the main combustion chamber 110 through the induction duct 330.

In this case, the induction duct 330 includes an inner duct 331 and an outer duct 332 installed inside and outside, and the air supply unit 310 is a space between the inner duct 331 and the outer duct 332. The air injected through the air supply unit 310 to communicate with the air may be injected into the main combustion chamber 110 through a space between the inner duct 331 and the outer duct 332.

According to the present invention, the gas generated in the pyrolysis facility 30 is discharged to meet the air, and the combustion is made. The gas combustion is made in the form of a nozzle so as to burn efficiently, and the combustion efficiency inside the main combustion chamber 110 is improved. You can.

On the other hand, the air supply unit 310 may be bent in the form of the letter L as shown, which is just an example for explaining the present invention, a shape capable of injecting air toward the induction duct 330 as described above Therefore, even if the shape of the air supply unit 310 is changed, it is natural that all belong to the scope of the present invention.

Meanwhile, as described above, the unburned material remaining in the vibrating combustion chamber 120 is combusted. At this time, as shown in FIG. 6, the vibrating combustion chamber 120 is discharged to discharge the remaining residue. It is also possible to further include a combustion material discharge device 200 communicated to the side.

At this time, the combustion material discharge device 200 is a chamber (C) which is in communication with one side of the vibration combustion chamber 120, the gate (G) is installed on one side of the chamber (C) to open and close the interior of the chamber (C) It is also possible to include).

That is, the combustion material discharge apparatus 200 includes a combustion material discharge device 200 for discharging the remaining residue after combustion of unburned material in the vibration combustion chamber 120, and when the residue is discharged, the residue flows back to the vibration combustion chamber 120. In order to prevent the residue, the gate G blocks the chamber C after the residue is discharged.

To this end, the gate G includes a first gate G1 and a second gate G2 disposed in the vertical direction of the chamber C, and the chamber C is located above the first gate G1. The first chamber C1 may be disposed at a side thereof, and the second chamber C2 may be disposed between the first gate G1 and the second gate G2.

That is, the two chambers C1 and C2 are interrupted by the two gates G1 and G2 to prevent backflow of residual material and backflow of external air.

In detail, first, when the completely burned residue falls, the residue is collected into the first chamber C1 with the first gate G1 closed.

Thereafter, when the first gate G1 is opened while the second gate G2 is closed after a predetermined time, the residue falls into the second chamber C2 to prevent the residue and the external air from flowing back.

On the other hand, the gate (G) is to control the inside of the chamber (C) as described above, even if other valves are used as long as this object is achieved, it is natural that the scope of the present invention.

In addition, the first gate G1 and the second gate G2 of the gate G are operated by the first air cylinder 250 and the second air cylinder 260, and the first air cylinder 250 and The second air cylinder 260 may be operated by receiving a signal from a control unit (not shown), for example, a panel having a separate timer device.

Meanwhile, the residue collected in the second chamber C2 is discharged to the outside by opening the second gate G2 after a predetermined time.

In this case, before the second gate G2 is opened, the primary gate G1 is closed and operated.

In addition, the second gate G2 may be installed at an end of the second chamber C2 as shown.

In addition, the chamber (C) may also serve to help complete combustion before the final discharge because the residues stay there for a certain time.

On the other hand, since the upper portion of the combustion material discharge device 200 is connected to the vibration combustion chamber 120 is vibrated by the vibrator (V) it is necessary to prevent the transmission of vibration to the combustion material discharge device 200 side.

To this end, as illustrated, a connection chute 210 communicating with the first chamber C1 and the vibration combustion chamber 120, and a heat-resistant flexible plate installed between the connection chute 210 and the first chamber C1 ( 220 and an inner duct 230 installed inside the heat-resistant flexible 220 and installed on the connection chute 210 and an outer duct 240 installed on the first chamber C1 side. can do.

That is, the heat resistant flexible 220 may serve to absorb vibration as described above and may be installed between neighboring flanges F2 as shown.

In addition, the heat-resistant flexible 220 may include an inner duct 230 and the outer duct 240 as described above to facilitate the protection and discharge of the residue.

At this time, the inner duct 230 may be inserted into the outer duct 240 as shown to allow the residue to be smoothly discharged to the second chamber (C2) side.

In addition, the connection chute 210 and the discharge chute 128 may also be interconnected by the flange (F1).

Although the present invention has been described in detail through specific examples, this is for explaining the present invention in detail, and the present invention is not limited thereto, and a person having ordinary skill in the art within the technical idea of the present invention. It is obvious that modifications and improvements are possible.

It is intended that the present invention cover the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.

110: main combustion chamber 111: main combustion chamber body
112: castable 113: combustion chamber injection portion
114: combustion gas discharge unit 115: water jacket
117a: cooling water supply section 117b: cooling water discharge section
118: ignition unit 120: vibration combustion chamber
121: vibration combustion chamber body 122: heat resistant flexible
124: air supply unit 125: coolant water supply unit
126: drain 127: cooling water discharge portion
128: drain chute 129: water jacket
130: bracket 200: combustion material discharge device
210: connection chute 230: internal duct
240: outer duct C: chamber
300: combustion promotion unit 310: air supply unit
330: induction duct 331: internal duct
332: outer duct G: gate

Claims (11)

As the composite combustion chamber 100 for burning the gaseous material and unburned material of the solid fuel passed through the pyrolysis furnace 30,
The complex combustion chamber 100 includes a main combustion chamber 110 for burning the gaseous material and a vibration combustion chamber 120 for burning unburned material generated in the pyrolysis furnace 30.
The vibrating combustion chamber 120 is installed on one side of the main combustion chamber 110, but the hollow vibrating combustion chamber body 121 in communication with the main combustion chamber 110 and the vibrating combustion chamber body 121 is installed on one side of the main combustion chamber 110. Including a vibrator (V),
Coil spring 123 which is installed on one side of the main combustion chamber 110, the vibration combustion chamber body 121 is elastically connected,
And a heat-resistant flexible member (122) installed between the vibration combustion chamber body (121) and the main combustion chamber (110) to absorb vibration.
The method of claim 1,
The vibration combustion chamber body 121 includes a hollow combustion chamber inner cylinder 121b and a vibration combustion chamber outer cylinder 121a.
A coolant water supply unit 125 installed at one side of the vibration combustion chamber main body 121 to inject cooling water into the water jacket 129 which is a space between the vibration combustion chamber inner cylinder 121b and the vibration combustion chamber outer cylinder 121a; Vibration combustion chamber main body 121 is installed on the other side of the vibration combustion complex combustion chamber characterized in that it comprises a cooling water discharge portion 127 for discharging the cooling water.
delete 3. The method of claim 2,
Is installed on one side of the vibration combustion chamber body 121 includes an air supply unit 124 for injecting air into the inner cylinder 121b,
The air supply unit 124 is installed in the inner cylinder 121b of the vibrating combustion chamber, and a pipe-shaped air supply unit body 124a into which air is injected, and
Vibration-type complex combustion chamber characterized in that it comprises a plurality of discharge holes (124b) is formed on the outer periphery of the air supply unit main body (124a) is discharged air.
delete The method of claim 1,
The main combustion chamber 110 mounts the main combustion chamber main body 111 including a hollow main combustion chamber inner cylinder 11b and a main combustion chamber outer cylinder 111a.
Is installed on one side of the main combustion chamber body 111 includes an air injection unit 116 for injecting air into the inner combustion chamber inner cylinder (111b),
The air injection unit 116 and the air supply duct 116a which is installed on one side of the outer cylinder 111a of the main combustion chamber,
An air nozzle 116b formed of a space between the main combustion chamber outer cylinder 111a and the castable 116e, and an air nozzle in which air is injected into the main combustion chamber inner cylinder 111b; And 116c).
The method of claim 1,
Further comprising a combustion material discharge device 200 in communication with one side of the vibration combustion chamber 120,
The combustion material discharge device 200 and the chamber (C) is in communication with one side of the vibration combustion chamber 120,
And a gate (G) installed at one side of the chamber (C) to open and close the inside of the chamber (C).
The method of claim 7, wherein
The gate G includes a first gate G1 and a second gate G2 disposed in the vertical direction of the chamber C.
The chamber C includes a first chamber C1 disposed above the first gate G1, and a second chamber C2 disposed between the first gate G1 and the second gate G2. Complex combustion chamber of the vibration system comprising a.
9. The method of claim 8,
A connection chute 210 communicating with the first chamber C1 and the vibration combustion chamber 120;
The heat-resistant flexible 220 is installed between the connection chute 210 and the first chamber (C1),
Including the inner duct 230 and the outer duct 240 is installed on the connection chute 210 side as being installed inside the heat-resistant flexible 220,
The inner duct 230 is a vibrating complex combustion chamber, characterized in that inserted into the outer duct (240).
9. The method of claim 8,
And a first air cylinder (250) and a second air cylinder (260) for operating the first gate (G1) and the second gate (G2).
The method of claim 1,
Further comprising a combustion promoting unit 300 is installed between the pyrolysis furnace 30 and the main combustion chamber 110,
The combustion promotion unit 300 is one side is in communication with the pyrolysis furnace 30 and the other side is induction duct 330 is in communication with the combustion chamber injection portion 113 of the main combustion chamber 110, the induction duct 330 It includes an air supply unit 310 is communicated to one side,
The induction duct 330 includes an inner duct 331 and an outer duct 332 installed inside and outside, and the air supply unit 310 communicates with a space between the inner duct 331 and the outer duct 332. Complex combustion chamber of the vibration system characterized in that the.

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