KR101044421B1 - Gasification and slagging combustion system and method - Google Patents

Abstract

The gasification and slagging combustion system has a fluidized-bed gasification furnace 11 for vaporizing waste A and a slagging combustion furnace 31 for burning and melting by-products produced by the fluidized-bed gasification furnace 11. The gasification and slagging combustion system comprises the incombustibles discharging device 21 for delivering the incombustibles contained in the waste A from the gasification furnace 11 and the incombustibles to form a mixture gas of leaked combustible gas and air. The blower 1a which draws in combustible gas and air which leaks from the vaporization furnace 11 through the discharge apparatus 21 is included. The vaporization and slagging combustion system also includes blowers 41 and 42 that supply mixed gas and air to the vaporization furnace 11 and the slagging combustion furnace 31, respectively, and blowers 41 and 42 from the blower 1a. And a mixed gas delivery passage 65 for supplying the mixed gas to the furnace.

Description

GASIFICATION AND SLAGGING COMBUSTION SYSTEM AND METHOD}

The present invention provides a vaporization and slagging combustion system for treating waste such as municipal waste, waste processing fuel (RDF), waste plastic, waste glass fiber reinforced plastic (waste FRP), biomass waste, automobile waste and waste oil. It is about. More specifically, the present invention relates to a gas treatment apparatus and method for treating flammable gas leaking through a non-combustible discharge line provided at the bottom of a furnace of a fluidized-bed gasification furnace as a first stage of a vaporization and slagging combustion system.

1 shows a conventional fluidized-bed gasification furnace 11. As shown in FIG. 1, the fluidized-bed gasification furnace 11 has an air diffuser plate disposed at the furnace bottom 11a. Combustion air B for partial combustion is supplied from furnace bottom 11a to form a fluidized bed of flow medium P on the air diffuser plate. Waste A is supplied to the fluidized-bed gasification furnace 11 and flows into the fluidized bed. Waste (A) is brought into contact with flowing medium (P) and combustion air (B) heated to 450 to 750 ° C. and immediately pyrolyzed to produce combustible gases (including flammable components), tar and char.

The gas and gaseous tar produced by the pyrolysis are accompanied by fine particles of charcoal and discharged from the discharge duct 11b provided at the top of the fluidized-bed gasification furnace 11. The char with large diameter particles, produced by pyrolysis, is pulverized by active turbulent movement and partial combustion of the fluid medium in the fluidized bed and together with gas and tar from the discharge duct 11b. Discharged. Incombustibles contained in the waste, such as iron, aluminum, copper and debris, are discharged together with the flow medium P from the furnace bottom 11a through chutes 12 and into the incombustibles disposal facility. Delivered.

As shown in FIG. 1, a conventional non-combustible material treatment facility has a non-combustible discharge device 21, a vibrating screen 23, a sand lift 24, and a sand supply valve 25. The mixture of the incombustibles and the fluid medium discharged from the bottom 11a of the fluidized-bed gasification furnace 11 is transferred to the incombustibles discharging device 21 through the chute 12, and by the incombustibles discharging device 21. It is transmitted to the vibrating screen 23. The vibrating screen 23 separates the mixture into a non-combustible material having large diameter particles and a flow medium having small diameter particles. The separated flow medium is transferred in the vertical direction by the sand lifter 24 and is returned to the fluidized bed gasification furnace 11 through the sand supply valve 25. Large, separated, non-combustible materials, such as iron, aluminum, copper, and debris, exit the vibrating screen 23. Valuable materials such as metals are recovered from the discharged incombustibles and the remaining incombustibles are landfilled.

In general, the freeboard 11c of the fluidized-bed gasification furnace 11 is maintained under a negative pressure of approximately several tens of mm H ₂ O. The fluid medium P is fluidized in the fluidized bed, and pressure loss occurs in the vertical direction of the fluidized bed so that the pressure at the furnace bottom 11a becomes a positive pressure. Therefore, in order to prevent flammable gas from leaking out of the system, it is common to fill the chute 12 and the incombustibles discharging device 21 with a mixture of the fluid and the incombustibles to provide a material sealing effect. In addition, a mechanical sealing device such as a double damper may additionally be provided between the incombustibles discharging device 21 and the vibrating screen 23 to more reliably prevent the leakage of flammable gas.

However, it is substantially difficult for the chute 11 and the incombustibles discharging device 21 to achieve a perfect sealing effect by sealing the material with the mixture of the fluid medium and the incombustibles. In particular, air pressure is generated due to the pressure difference in the material seal, thereby leaking flammable gas. Even if a double damper is provided as a mechanical sealing device, the leakage of flammable gas is caused by the pressure difference generated between the upstream and downstream of the double damper during the switching operation of the double damper. In addition, under the operating conditions of the hot particles, it is technically difficult to obtain a complete sealing effect of the double damper. The sealing effect of the double damper may be incomplete by engagement or cause leakage of flammable gas. Such leaked flammable gases may contain trace amounts of toxic components. However, these leaked combustible gases have been discharged to the atmosphere without any treatment or only through dust removal. Thus, leaked flammable gas remaining around the incombustible treatment facility can significantly degrade the working environment.

The present invention has been made in view of the above disadvantages. Accordingly, an object of the present invention is to provide a vaporization and slagging combustion system and method capable of preventing the combustible gas discharged from the furnace bottom of a fluidized-bed gasification furnace through the incombustibles discharging device to be discharged to the atmosphere or to properly treat the combustible gas. To provide.

According to a first aspect of the present invention, there is provided a vaporization and slagging combustion system having a fluidized-bed gasification furnace for vaporizing waste and a slagging combustion furnace for burning and melting by-products generated in the fluidized-bed gasification furnace. The gasification and slagging combustion system is an incombustibles discharge device that delivers incombustibles contained in waste from a fluidized-bed gasification furnace together with a fluidized medium to form a mixed gas with air and combustible gases and air and incombustibles from the atmosphere. And a mixed gas drawing device for drawing flammable gas leaking out of the fluidized-bed gasification furnace through the discharge device. The gasification and slagging combustion system also provides a fluidized-bed gasification furnace and slag for the mixed air from a combustion air supply and a mixed gas extraction device to supply combustion air of waste to a fluidized-bed gasification furnace and a slagging combustion furnace. And a mixed gas delivery passage for supplying at least one of the ging furnaces.

Accordingly, the gasification and slagging combustion system includes a combustion air supply device for supplying a mixed gas including combustible gas to at least one of a fluidized-bed gasification furnace and a slagging combustion furnace, and a mixed gas delivery for supplying the mixed gas to the combustion air supply device. Have a passage Therefore, the amount of combustible gas to be discharged to the atmosphere can be minimized, so that the combustible gas can be properly disposed.

According to a second aspect of the present invention, there is provided a vaporization and slagging combustion system having a fluidized-bed gasification furnace for vaporizing waste and a slagging combustion furnace for burning and melting by-products produced by the fluidized-bed gasification furnace. The vaporization and slagging combustion system is a non-combustible discharge device that delivers a non-combustible material contained in waste from a fluidized-bed gasification furnace together with a fluidized medium to form a mixed gas with air and flammable gas, and air and non-combustibles from the atmosphere. And a mixed gas withdrawal device for withdrawing flammable gas leaking out of a fluidized-bed gasification furnace through a mass discharge device. The vaporization and slagging combustion system also includes a mixed gas supply passage for supplying the mixed gas from the mixed gas drawing device to at least one of the fluidized-bed gasification furnace and the slagging combustion furnace.

According to this arrangement, a mixed gas comprising combustible gas can be introduced into at least one of a fluidized-bed gasification furnace and a slagging combustion furnace. Therefore, the amount of combustible gas to be discharged to the atmosphere can be minimized, so that the combustible gas can be properly disposed.

The vaporization and slagging combustion system may have a dust collector for removing dust from the mixed gas. In this case, since dust can be removed from the mixed gas, the vaporization and slagging combustion system can operate stably for a long time. The dust collector is preferably located upstream of the mixed gas extraction device. In such a case, it is possible to prevent malfunction due to dust in the mixed gas drawing device such as the blower.

The mixed gas drawing device may include a blower. In such a case, a mixed gas comprising combustible gas can be stably treated in a vaporization and slagging combustion system. This arrangement is also appropriate when the combustible gas to be treated contains trace amounts of toxic components.

According to a third aspect of the present invention, a vaporization and slagging combustion method is provided. Waste is vaporized in a fluidized-bed gasification furnace. By-products produced in fluidized-bed gasification furnaces are burned and melted in slagging furnaces. Incombustibles contained in the waste are discharged from the fluidized-bed gasification furnace together with the fluidized medium. Combustible gas leaking out of a fluidized-bed gasification furnace is withdrawn from the atmosphere together with air to form a mixed gas of combustible gas and air. The mixed gas is supplied with the combustion air of the waste to at least one of the fluidized-bed gasification furnace and the slagging combustion furnace.

Thus, the mixed gas containing the treated combustible gas is supplied to at least one of the fluidized-bed gasification furnace and the slagging combustion furnace. Therefore, the amount of combustible gas to be discharged to the atmosphere can be minimized, so that the combustible gas can be properly disposed. This method is also suitable when the combustible gas to be treated contains trace amounts of toxic components.

According to a fourth aspect of the present invention, a vaporization and slagging combustion method is provided. Waste is vaporized in a fluidized-bed gasification furnace. By-products produced in fluidized-bed gasification furnaces are burned and melted in slagging furnaces. Incombustibles contained in the waste are discharged from the fluidized-bed gasification furnace together with the fluidized medium. Combustible gases leaking from the fluidized-bed gasification furnace are withdrawn from the atmosphere to form a mixed gas of combustible gas and air. The mixed gas is supplied to at least one of the fluidized-bed gasification furnace and the slagging combustion furnace.

Thus, the mixed gas containing the treated combustible gas is supplied to at least one of the fluidized-bed gasification furnace and the slagging combustion furnace. Therefore, the amount of combustible gas to be discharged to the atmosphere can be minimized, so that the combustible gas can be properly disposed. This method is also suitable when the combustible gas to be treated contains trace amounts of toxic components.

Dust can be removed from the mixed gas. In this case, since dust can be removed from the mixed gas by a dust collector or the like, it is possible to prevent failure due to dust in the mixed gas extractor such as a blower, and to stably perform vaporization and slagging combustion for a long time. have.

The above and other objects, features and advantages of the present invention will become more apparent from the preferred embodiments of the present invention described by way of example with reference to the accompanying drawings.

1 is a block diagram showing a conventional fluidized-bed gasification furnace having a incombustibles treatment facility;

2 is a block diagram showing a vaporization and slagging combustion system according to a first embodiment of the present invention;

3 is a block diagram illustrating a vaporization and slagging combustion system according to a second embodiment of the present invention.

A vaporization and slagging combustion system according to embodiments of the present invention is described below with reference to FIGS. 2 and 3. The same or corresponding parts in the drawings are denoted by the same reference numerals and will not be described repeatedly.

2 is a block diagram illustrating a vaporization and slagging combustion system according to a first embodiment of the present invention. As shown in FIG. 2, the gasification and slagging combustion system is a combustible gas produced by a fluidized-bed gasification furnace 11 and a fluidized-bed gasification furnace 11 which vaporize waste A to produce combustible gases, tars and charcoal. And a rotary slagging combustion furnace 31 for burning and melting tar. The fluidized-bed gasification furnace 11 is provided with an exhaust duct 11b at the top thereof, which is connected to the slagging combustion furnace 31. In the present embodiment, the slagging combustion furnace 31 has a first combustion chamber 31a, a second combustion chamber 31b and a third combustion chamber 31c. The vaporization and slagging combustion system also has an incombustibles discharging device 21, a vibrating screen 23, a sand lift 24, a sand supply valve 25 and an air supply passage 26 which draws air out of the atmosphere. .

Waste A to be treated is fed to the fluidized-bed gasification furnace 11 and pyrolyzed into combustible gas, tar and char in a fluidized bed maintained at 450 to 750 ° C. Most of the flammable gas and tar produced by the pyrolysis are discharged from the discharge duct 11b together with char in the form of fine particles and introduced into the rotary slagging combustion furnace 31. Bulk non-combustible materials such as iron, aluminum, copper and debris are withdrawn in the bottom portion 11a of the fluidized-bed gasification furnace 11 together with the fluidized medium and through the chute 12 to the incombustibles discharging device 21. Delivered. The mixture of the non-combustible material and the flow medium, which is delivered to the vibrating screen 23 by the non-combustible material discharging device 21, is separated into the non-combustible material having the large diameter particles and the flow medium having the small diameter particles. Expensive materials, such as iron and aluminum, are separated and recovered from incombustibles having large diameter particles by a recovery device. The remaining noncombustibles are landfilled. The fluid medium having the small diameter particles is conveyed upwards in the vertical direction by the sand lifter 24 and returned to the fluidized-bed gasification furnace 11 through the sand supply valve 25. Thus, the separated flow medium is reused as the flow medium.

In the vaporization and slagging combustion system according to the present embodiment, the free board 11c of the fluidized-bed gasification furnace 11 is generally maintained under a negative pressure of approximately several tens of mm H ₂ O. When the fluidized medium is fluidized in the fluidized-bed gasification furnace 11, pressure loss is generated in the vertical direction of the fluidized bed. Thus, the fluidized-bed gasification furnace 11 is operated to have a static pressure of 1500 mm H ₂ O at the furnace bottom 11a. In order to prevent the flammable gas in the vaporization furnace 11 from leaking out of the system, the chute 12 and / or the incombustibles discharging device 21 is filled with a mixture of the fluid medium and the incombustibles, so that the material sealing effect Can be provided. However, since a full sealing effect cannot be obtained by such a material sealing, a small amount of combustible gas may inevitably leak into the atmosphere.

In view of this, the gasification and slagging combustion system has a gas treatment apparatus 1 for the treatment of leaked flammable gas having a trace amount of toxic components mixed with a large amount of air withdrawn from the atmosphere. Specifically, the gas treatment device 1 is a gas mixture of the combustible gas and a large amount of air discharged from the bottom 11a of the fluidized-bed gasification furnace 11 through the chute 12 and the non-combustible material discharge device 21. Process. The vaporization and slagging combustion system also has a mixed gas delivery passage 65 for introducing a mixed gas containing the combustible gas treated by the gas treatment apparatus 1.

The gas treating device 1 is a dust collecting device for removing dust from a mixed gas, and a mixed gas extracting device which draws combustible gas from the bag filter 1 and the incombustible discharging device 21 and air from the atmosphere. As a blower 1a. The bag filter 1b is provided upstream of the blower 1a. In order to prevent the flammable gas discharged from the fluidized-bed gasification furnace 11 to leak out of the system, as shown in FIG. 2, a line 61 is connected to the top of the incombustibles discharging device 21, and the line 62 is connected to the chute upstream of the vibrating screen 23. The sand lift 24 has a suction port 24a provided on top thereof, and the suction port 24a is connected to the line 63. Lines 61, 62, 63 are connected to line 64 which is connected to the bag filter 1b of the gas treatment apparatus 1. By having such lines, a mixed gas of combustible gas and air discharged from the fluidized-bed gasification furnace 11 is introduced into the gas treatment apparatus 1.

According to this arrangement, the combustible gas can be concentrated without leaking out of the system. The points where the flammable gas is withdrawn are not limited to the above examples, and the flammable gas may be withdrawn at any point in the system as long as it can prevent the flammable gas from leaking out of the system. Since the concentration of flammable gas is high in the vicinity of the non-combustible substance discharge apparatus 21, it is effective and preferable to take out the combustible gas near the non-combustible substance discharge apparatus 21. FIG.

Air is introduced from the atmosphere into the line 62 through the air supply passage 26 and the vibrating screen 23 to dilute the withdrawn flammable gas. Thus, the withdrawn flammable gas is diluted by a large amount of air, so that the mixed gas is kept within the explosion limit. The mixed gas of diluted flammable gas and air is supplied to the bag filter 1b. After dust is removed by the bag filter 1b, the mixed gas is introduced into the blower 1a.

The amount of air to be supplied to line 62 is preferably at least two times the amount of leaked flammable gas, and more preferably at least five times. If the amount of air to be supplied is twice the amount of leaked flammable gas, it is possible to reliably prevent the flammable gas from leaking out of the system. If the amount of air to be supplied is excessively small, the temperature of the mixed gas rises. Thus, the temperature of the combustible gas can rise to the extent that the combustible gas explodes by the ignition source beyond the explosion limit. Therefore, a sufficient amount of low temperature air must be supplied to sufficiently dilute the combustible gas. If the amount of air to be supplied is at least five times the amount of leaked flammable gas, leakage of the flammable gas can be prevented more reliably.

The mixed gas of the combustible gas and the large amount of air drawn out by the blower 1a is supplied to the first suction line 51 and the second suction line 53 through the mixed air delivery passage (pipe), respectively. The first suction line 51 is connected to a flow blower 41 (combustion air supply device) for supplying air to the fluidized-bed gasification furnace 11. The second suction line 53 is connected to a second fan 42 (combustion air supply device) for supplying air to the slagging combustion furnace 31. Flow blower 41 and second fan 42 draw air from waste pits. Thus, unpleasant odorous air in the waste piles is prevented from leaking out of the system.

The mixed gas is mixed with air from the waste piles and introduced into the fluidized-bed gasification furnace 11 and the slagging combustion furnace 31 through the first suction line 51 and the second suction line 53, respectively. Thus, the combustible gas leaking out of the vaporization furnace 11 is burned at a high temperature in the fluidized-bed gasification furnace 11 and the slagging combustion furnace 31. Thus, even if the combustible gas contains the organic poisoning component, the organic poisoning component can be completely oxidized and decomposed in the fluidized-bed gasification furnace 11 and the slagging combustion furnace 31.

In FIG. 2, the mixed gas delivery passage 65 is connected to both the first suction line 51 for the flow blower 41 and the second suction line 53 for the second fan 42. However, the mixed gas delivery passage 65 may be connected to one of the first suction line 51 for the flow blower 41 and the second suction line 53 for the second fan 42. Alternatively, the mixed gas delivery passage 65 bypasses the blower 41 and the fan 42 to directly supply the mixed gas to the fluidized bed vaporization furnace 11 and / or the slagging combustion furnace 31. It may also be directly connected to the furnace 11 and / or the slagging combustion furnace 31. When the mixed gas is supplied to the slagging combustion furnace 31, any of the first combustion chamber 31a, the second combustion chamber 31b, and the third combustion chamber 31c in the slagging combustion furnace 31 to which the mixed gas is supplied is supplied. Any equivalent effect can be expected.

3 is a block diagram illustrating a vaporization and slagging combustion system according to a second embodiment of the present invention. As shown in FIG. 3, the vaporization and slagging combustion system has a double damper 22 as a mechanical seal located between the incombustibles discharging device 21 and the vibrating screen 23. Line 62 is connected downstream of double damper 22 and upstream of vibrating screen 23. Combustible gas and air are withdrawn to bag filter 1b via line 62. In this case, it is not necessary to take out from the incombustible substance discharging device 21. With a double damper 22 having a high sealing capacity, the suction line from the incombustibles discharging device 21, shown by line 61 in FIG. 2, reversely forces flammable gas from the fluidized-bed gasification furnace 11. To withdraw. The other structure is the same as shown in FIG.

If a mechanical sealing device such as a double damper is provided, the amount of leaked flammable gas can be reduced. When waste with high calorific value is treated, the combustible gas produced has a high concentration of flammable components. Therefore, such a mechanical sealing device is suitable when wastes having a high calorific value are processed. Instead of the double damper, a sealing device having a triple damper or a plurality of gate valves may be adopted as the mechanical sealing device.

As described above, according to embodiments of the present invention, a gasification and slagging combustion system is a gas for treating a mixed gas comprising a flammable gas leaking from a fluidized-bed gasification furnace through a non-combustible discharge device and air drawn from the atmosphere. Has a processing unit. The mixed gas withdrawn from the blower of the gas treatment apparatus is mixed with combustion air to be supplied to the fluidized-bed gasification furnace or with combustion air to be supplied to the slagging combustion furnace. Alternatively, the mixed gas is introduced directly into either the fluidized-bed gasification furnace or the slagging combustion furnace. Thus, the leaked flammable gas can be effectively treated in an appropriate manner. In addition, because the mixed gas is allowed to pass through the hot combustion zone in the slagging furnace, trace amounts of toxic components can be oxidized and decomposed.

Accordingly, according to the present invention, the vaporization and slagging combustion system includes a mixed gas in a combustion air supply device and a combustion air supply device for supplying a mixed gas including a combustible gas to at least one of a fluidized-bed gasification furnace and a slagging combustion furnace. It has a mixed gas delivery passage which supplies. Therefore, the amount of combustible gas to be discharged to the atmosphere can be minimized, so that the combustible gas can be properly disposed.

While the preferred embodiments of the invention have been shown and described in detail, those skilled in the art will understand that various changes and modifications can be made without departing from the scope of the appended claims.

The present invention can be suitably used in gasification and slagging combustion systems for treating municipal waste, waste processing fuel (RDF), waste plastics, waste glass fiber reinforced plastics (waste FRP), biomass wastes, automotive wastes and wastes. have.

Claims (12)

In a vaporization and slagging combustion system, Fluidized-bed gasification furnace for vaporizing waste; A slagging combustion furnace for burning and melting by-products produced by the fluidized-bed gasification furnace; An incombustibles discharging device for delivering incombustibles contained in the waste from the fluidized-bed gasification furnace together with a fluidized medium; A mixed gas extracting device which draws out the combustible gas before combustion and the air from the atmosphere leaking from the fluidized-bed gasification furnace through the incombustible discharging device to form a mixed gas with combustible gas and air before combustion; An air supply device for combustion for supplying air for combustion of the waste to the fluidized-bed gasification furnace and the slagging combustion furnace; And And a mixed gas delivery passage for supplying said mixed gas from said mixed gas drawing device to at least one of said fluidized-bed gasification furnace and said slagging combustion furnace through an air supply necessary for said combustion. The method of claim 1, Evaporating and slagging combustion system further comprises a dust collector for removing dust from the mixed gas. The method of claim 2, And the dust collecting device is disposed upstream of the mixed gas extracting device. The method of claim 1, And the mixed gas drawing device comprises a blower. In a vaporization and slagging combustion system, Fluidized-bed gasification furnace for vaporizing waste; A slagging combustion furnace for burning and melting by-products produced by the fluidized-bed gasification furnace; An incombustibles discharging device for delivering incombustibles contained in the waste from the fluidized-bed gasification furnace together with a fluidized medium; A mixed gas extracting device which draws out the combustible gas before combustion and the air from the atmosphere leaking from the fluidized-bed gasification furnace through the incombustible discharging device to form a mixed gas with combustible gas and air before combustion; And a mixed gas supply passage for supplying the mixed gas from the mixed gas drawing device to at least one of the fluidized-bed gasification furnace and the slagging combustion furnace. The method of claim 5, Evaporating and slagging combustion system further comprises a dust collector for removing dust from the mixed gas. The method of claim 6, And the dust collecting device is disposed upstream of the mixed gas extracting device. The method of claim 5, And the mixed gas drawing device comprises a blower. In the vaporization and slagging combustion method, Vaporizing the wastes in a fluidized-bed gasification furnace; Burning and melting byproducts produced by the vaporization in a slagging furnace; Draining incombustibles contained in the waste from the fluidized-bed gasification furnace together with a fluidized medium; Withdrawing the air from the combustible gas before combustion and the atmosphere leaking in the venting step to form a mixed gas of combustible gas and air before combustion; And And supplying air and the mixed gas necessary for combustion of the waste to at least one of the fluidized-bed gasification furnace and the slagging combustion furnace. 10. The method of claim 9, Vaporizing and slagging combustion method further comprising removing dust from the mixed gas. In the vaporization and slagging combustion method, Vaporizing the wastes in a fluidized-bed gasification furnace; Burning and melting byproducts produced by the vaporization in a slagging furnace; Draining incombustibles contained in the waste from the fluidized-bed gasification furnace together with a fluidized medium; Withdrawing the combustible gas before combustion and the air from the atmosphere leaking in the venting step to form a mixed gas of combustible gas and air before combustion; And Supplying the mixed gas to at least one of the fluidized-bed gasification furnace and the slagging combustion furnace. The method of claim 11, Vaporizing and slagging combustion method further comprising removing dust from the mixed gas.

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