KR20130134676A - Purification apparatus of synthesis gas for biomass gasification - Google Patents

Abstract

The present invention relates to a purification apparatus of synthetic gas for biomass gasification, which comprises a first cyclone connected to the rear end of a gasification furnace and mainly removing the dust produced in the gasification furnace; a condenser connected to the rear end of the first cyclone and cooling synthetic gas to collect pyroligneous liquor; a wet scrubber connected to the rear end of the condenser and firstly removing tar, dust and acidic gas in the synthetic gas; a second cyclone connected to the rear end of the wet scrubber and removing moisture and tar droplets in the synthetic gas; an adsorption tower removing the tar and moisture mist unremoved in the second cyclone; and a third cyclone connected to the rear end of the adsorption tower and removing the dust of the adsorption agent, in order to purify the synthetic gas generated in the gasification furnace to the level suitable for a gas engine. The purification apparatus of synthetic gas according to the present invention secures the stability of a gas engine by lowering tar, dust and moisture, which largely influence in the operation of a gas engine, to the concentration suitable for operation or less, so as to enable a high efficient power generation; prevents shutdown of the gasification system due to the blocking of pipes due to tar, dust and moisture, and the increase of the pressure loss; and secures the stable working condition to have an effect capable of continuous working.

Description

Biomass gasification syngas purification device {PURIFICATION APPARATUS OF SYNTHESIS GAS FOR BIOMASS GASIFICATION}

The present invention relates to a syngas purification apparatus for removing tar, dust, water, and acid gases generated in a biomass gasifier.

In general, the apparatus mainly used for the purification of biomass syngas is a condenser, a wet scrubber is mainly used. The condenser cools the synthesis gas to recover wood vinegar, and the wet scrubber removes impurities such as tar, dust, and acid gas.

Conventional refining apparatus has a low removal efficiency for impurities in the synthesis gas, tar and dust in the synthesis gas flows into the gas engine causing a failure. In addition, the moisture including the tar cleaning liquid is not removed, causing a lot of problems in the utilization of the synthesis gas.

As prior art as the background of the invention, Patent Documents 1 and 2 disclose a purification system for a synthesis gas, and a method and installation for purification of a gas, respectively.

However, although both Patent Literatures 1 and 2 are related in that they are wet purifiers for refining the syngas obtained through gasification, the substance to be purified in the syngas is limited to acid gas, and the structure and structure of the refining apparatus are There is a difference between the difference and the substance to be purified in the synthesis gas for ammonia and hydrogen sulfide, and there are differences in the structure and structure of the purification apparatus.

In addition, Patent Literature 3 discloses an acidic gas separation and recovery apparatus, except that it is related to the configuration for removing moisture at the outlet of the absorption tower, there is a difference in the manner and structure of the water remover installed at the outlet of the absorption tower.

In addition, Patent Documents 4 and 5 disclose a cogeneration method by biomass gasification and an eco-friendly low carbon green rice flour processing plant using a power generation system through pyrolysis gasification in a vertical continuous rice husk carbonation manufacturing apparatus, but the process configuration of syngas There is only a similar relationship, and there is a difference in that the structure of the refinery is differentiated to refine the refining process and remove tar, dust, and water, and the refinement of the refining apparatus and propose a differentiated internal structure.

(Patent Document 1) Korean Registered Patent No. 10-0786574 (August 21, 2007.)

(Patent Document 2) Korean Unexamined Patent Publication No. 10-2009-0021246

(Patent Document 3) Korean Patent Publication No. 10-2012-0002004 (published on June 1, 2012)

(Patent Document 4) Korean Patent Registration No. 10-0742159 (Nov. 18, 2010)

(Patent Document 5) Korean Patent Publication No. 10-2010-0120580 (published Nov. 16, 2010)

Accordingly, an object of the present invention is to provide a syngas purification apparatus for removing tar, dust, water, and acid gases generated in a biomass gasifier.

In order to achieve the above object, a biomass gasification syngas purification apparatus according to an aspect of the present invention is a purification apparatus for refining a synthesis gas generated in a gasifier to a level suitable for use in a gas engine, the rear end of the gasifier A primary cyclone connected to mainly remove dust generated in the gasifier, a condenser connected to a rear end of the primary cyclone to recover wood vinegar by cooling the syngas, and connected to a rear end of the condenser. A wet scrubber to remove tar, dust, and acid gas in the syngas first, a secondary cyclone connected to a rear end of the wet scrubber to remove water and tar droplets in the syngas, and the second cyclone Adsorption tower to remove the removed tar and water mist, and tertiary to be connected to the rear end of the adsorption tower to remove dust of the adsorbent Including the cycle theory.

The wet scrubber may be an integral wet scrubber in which a pair of venturi scrubbers and a pair of primary and secondary spray scrubbers are sequentially combined.

The venturi scrubber may include a spray nozzle attached to spray the cleaning chemical, and the inlet of the primary spray scrubber may include a tangential inflow cyclone-type gas-liquid separator installed to separate the cleaning liquid and the gas sprayed from the venturi scrubber.

The column of the primary spray scrubber includes a plurality of cramped baffles installed so that droplets collide with each other so that large droplets of particles fall downward, and the column of the secondary spray scrubber is disposed above and below to separate water and tar mist from the gas. It may include a perforated plate spaced apart from a predetermined interval.

The slot portion and each porous plate of the venturi scrubber may include a chemical spray nozzle installed to clean the attached tar particles.

The tar concentrated in the bath of the wet scrubber is continuously removed by the tar separator, and the tar separated washing liquid can be supplied back to the bath as circulating water.

The adsorption tower may be filled with an adsorbent to completely remove the water mist generated in the wet scrubber and the unremoved tar and dust.

The adsorbent may be composed of chaff, sand, activated carbon, activated alumina, clays, metals or combinations thereof.

The adsorption tower may further include a syngas sealing device and a screw discharge device.

The screw discharge device may be inserted into the discharge portion of the lower portion of the adsorption column in a tangential direction to penetrate the absorption tower discharge port.

The syngas sealing device may include a rotary valve and a slide knife valve to block and seal the syngas outflow at the upper and lower portions thereof.

The adsorption tower can be manufactured in a cylinder and square shape or a combination thereof.

Adsorbent input and discharge in the adsorption tower is automatically filled from the upper hopper when it is lower than the input height by using the sensor to detect the height of the linked adsorbent when the screw discharge device is operated, and the slide knife valve is connected to the discharge port attached as a double valve. Can be discharged in a lock hopper manner.

The adsorbents used in the adsorption tower are supplied to the gasifier and used as gasification fuel, and the inorganic and metal adsorbents can be regenerated and reused.

Biomass gasification syngas purification method according to another aspect of the present invention is a purification method for purifying the synthesis gas generated in the gasifier to a level suitable for use in a gas engine, gasification through a primary cyclone connected to the rear end of the gasifier A process of mainly removing dust generated in a furnace, a process of recovering wood vinegar by cooling the syngas through a condenser connected to a rear end of the primary cyclone, and syngas through a wet scrubber connected to a rear end of the condenser A process for removing tar, dust and acid gas in the inside, a process for removing water and tar droplets in the syngas through a secondary cyclone connected to the rear end of the wet scrubber, and an adsorption column in the secondary cyclone. Removing the tar and water mist removed, and through a third cyclone connected to the rear end of the adsorption column. And a step of removing dust of the adsorbent.

According to the present invention, it is possible to reduce the tar and dust, which greatly affects the operation of the gas engine, to a concentration suitable for operation to ensure the stability of the gas engine, thereby enabling high efficiency power generation, and to close the pipes by tar and dust and increase the pressure loss. It prevents the operation stop of the gasification system and secures stable operation condition. It has the effect of continuous operation.

1 is a block diagram of a biomass gasification syngas purification apparatus according to an embodiment of the present invention,
2 is a schematic configuration diagram showing a venturi and a spray integrated scrubber,
3 is a plan view of a tangentially introduced cyclone type gas-liquid separator,
4 is a front view, a plan view, and a side view of the baffle inside the primary scrubber,
5 is another embodiment of a baffle inside the primary scrubber,
6 is a front view of the screw forced discharge adsorption tower,
7 is a plan view of FIG. 6,
8 is another embodiment of the adsorption tower.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying 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. The terms used below are defined in consideration of the functions of the present invention, which may vary depending on the user, the intention or custom of the operator, and the like. Therefore, the definition should be based on the contents throughout this specification.

1 shows a configuration of a biomass gasification syngas purification apparatus according to an embodiment of the present invention.

As shown in FIG. 1, the biomass gasification syngas refining apparatus of the present invention is a refining apparatus for purifying syngas generated in the gasifier 10 to a level suitable for use in the gas engine 90. 10) the first cyclone 20, the condenser 30, the wet scrubber 40, the secondary cyclone 22, the adsorption tower 70, the tertiary cyclone 24, , The inlet blower 26 and the gas engine 90 are sequentially connected.

The primary cyclone 20 mainly removes the dust generated in the gasifier 10.

The condenser 30 is a two-stage condenser, which cools the synthetic gas from which dust is removed through the primary cyclone 20 to recover wood vinegar used for soil improvement, pest prevention, and the like.

The wet scrubber 40 removes tar, dust, and acid gases such as H ₂ S and HCI in the syngas from which wood vinegar is recovered.

In the secondary cyclone 22, water and tar droplets in the syngas passing through the wet scrubber 40 are removed.

The adsorption tower 70 removes the tar and the water mist that has not been removed from the secondary cyclone 22, and may use a dry adsorption tower.

Finally, the tertiary cyclone 24 removes the dust of the adsorbent passing through the adsorption tower 70.

As shown in FIG. 2, the wet scrubber 40 is an integral type in which a pair of venturi scrubbers 42 and a pair of primary and secondary spray scrubbers 50 and 60 are sequentially combined to increase the removal efficiency of tar, dust, and acid gas. It consists of a wet scrubber, the venturi scrubber 42 includes a spray nozzle 44 attached to spray the cleaning chemicals, and the venturi scrubber 42 at the inlet of the primary and secondary spray scrubbers 50 and 60. A tangential inflow cyclone type gas-liquid separator 52 as shown in FIG.

In addition, a plurality of cramped baffles 56 are installed inside the column 54 of the primary spray scrubber 50, and inside the column 64 of the secondary spray scrubber 60. As the pair of porous plates 66 are spaced apart vertically, water and tar are suppressed from being discharged out of the scrubber. The baffle 56 provided inside the column 54 of the primary spray scrubber 50 may employ a corrugated baffle as shown in FIG. 5.

The droplets separated by the gas-liquid separator 52 collide with the baffle 56 of the primary spray scrubber 50 to form large droplets of water and fall downward, and the synthesis gas is installed in the secondary spray scrubber 60. The porous plate 66 separates water and tar mist from the syngas.

On the other hand, the chemical spray nozzles 48 and 68 are adjacent to the slot 43 of the venturi scrubber 42 and the respective porous plates 66 in the secondary spray scrubber 60 to wash the attached tar particles. Can be installed.

The wet scrubber 40 is provided with a water tank 46 at the lower part of the primary and secondary spray scrubbers 50 and 60, and is continuous by a tar separator (not shown) concentrated in the water tank 46. The tar and the tar separated washing liquid can be supplied back to the water tank 46 as circulating water.

Adsorption tower 70 is a dry adsorption tower, it can be used by filling the adsorbent to completely remove the water mist and the tar and dust removed in the wet scrubber (40). The adsorbent may be composed of chaff, sand, activated carbon, activated alumina, clays, metals or combinations thereof. The shape of the adsorption tower may be a cylindrical as well as a suction tower having a rectangular structure as shown in FIG. 8 to reduce pressure loss, and may be manufactured in other cylinders or combinations thereof.

However, when these adsorbents adsorb moisture and tar, they are not discharged to the lower portion of the adsorption tower 70, so that continuous operation is not performed. Thus, in the present invention, as shown in FIGS. 6 and 7, the adsorption tower 70 may further include a screw discharge device 80 and a syngas sealing device 90.

At this time, the screw discharge device is inserted into the discharge portion 72 in the lower portion of the adsorption tower 70 in the tangential direction to penetrate the adsorption tower discharge port 74 to enable continuous discharge and input, thereby preventing operation stop of the gasification system, Stable operating conditions can be secured to enable continuous operation.

In addition, the adsorbent used in the adsorption tower 70 may be supplied to the gasifier 10 to be used as a gasification fuel, and inorganic and metal based adsorbents may be regenerated and reused.

Synthesis gas sealing device 90 is installed in the upper and lower portions of the adsorption tower 70, as shown in Figure 6, a rotary valve 92 and a slide for blocking and sealing the outflow of the synthesis gas Knife valve 94 or gate valve.

The adsorbent input and discharge in the adsorption tower 70 is automatically filled from the upper hopper when the screw discharge device 80 is lower than the input height by using a level sensor 76 that detects the interlocking adsorbent height when the screw discharge device 80 operates. The slide knife valve 94 can be discharged in a lock hopper manner through an outlet 96 attached as a double valve.

According to the biomass gasification synthesis gas purification apparatus of the present invention as described above, by reducing the tar and dust having a great influence on the operation of the gas engine to a concentration suitable for the operation to ensure the stability of the gas engine, high efficiency power generation is possible, Continuous operation is possible by preventing the shutdown of the gasification system due to tar, dust, water pipe closure, and increased pressure loss and securing stable operating conditions.

As described above is only one preferred embodiment of the biomass gasification syngas purification apparatus and method according to the present invention, the present invention is not limited to the above-described embodiment, as claimed in the following claims Without departing from the gist of the present invention, anyone of ordinary skill in the art will have the technical spirit of the present invention to the extent that various modifications can be made.

10: gasification furnace 20, 22, 24: cyclone
30: condenser 40: wet scrubber
42: Venturi Scrubber 43: Slot
44: spray nozzle 46: water tank
48, 68: chemical injection nozzle 50, 60: spray scrubber
52: gas-liquid separator 54, 64: column
56: baffle 70: adsorption tower
76 sensor 80 screw discharge device
90: syngas sealing device 92: rotary valve
94: Slide Night Valve

Claims (15)

As a refining device for refining the synthesis gas generated in the gasifier to a level suitable for use in a gas engine,
A primary cyclone connected to a rear end of the gasifier to mainly remove dust generated in the gasifier;
A condenser connected to a rear end of the primary cyclone and cooling the syngas to recover wood vinegar;
A wet scrubber connected to a rear end of the condenser to first remove tar, dust, and acid gas in the syngas;
A secondary cyclone connected to a rear end of the wet scrubber to remove water and tar droplets in the syngas;
An adsorption tower for removing tar and moisture mist which have not been removed from the secondary cyclone;
A tertiary cyclone connected to a rear end of the adsorption tower to remove dust of the adsorbent;
Biomass gasification syngas purification device.
The method of claim 1,
The wet scrubber is an integral wet scrubber in which a pair of venturi scrubbers and a pair of primary and secondary spray scrubbers are sequentially combined.
Biomass gasification syngas purification device.
3. The method of claim 2,
The venturi scrubber includes a spray nozzle attached to spray the cleaning chemicals,
The inlet of the primary spray scrubber includes a tangential flow cyclone type gas-liquid separator installed to separate the cleaning liquid and the gas sprayed from the venturi scrubber.
Biomass gasification syngas purification device.
3. The method of claim 2,
Inside the column of the primary spray scrubber includes a plurality of cramped baffles are installed so that the droplets collide with each other to fall large droplets downwards,
Inside the column of the secondary spray scrubber includes a perforated plate spaced apart a predetermined interval up and down to separate water and tar mist from the gas
Biomass gasification syngas purification device.
The method according to claim 3 or 4,
The slot portion of the venturi scrubber and each of the perforated plate includes a chemical spray nozzle installed to wash the attached tar particles
Biomass gasification syngas purification device.
The method of claim 1,
Tar concentrated in the water tank of the wet scrubber is continuously removed by a tar separator, and the tar separated washing liquid is supplied back to the water tank as circulating water.
Biomass gasification syngas purification device.
The method of claim 1,
The adsorption tower is used by filling the adsorbent to completely remove the water mist and unremoved tar and dust generated in the wet scrubber.
Biomass gasification syngas purification device.
The method of claim 7, wherein
The adsorbent is composed of chaff, sand, activated carbon, activated alumina, clays, metals or combinations thereof
Biomass gasification syngas purification device.
The method of claim 1,
The adsorption tower further includes a syngas sealing device and a screw discharge device
Biomass gasification syngas purification device.
The method of claim 9,
The screw discharge device is inserted into the discharge portion of the lower portion of the adsorption column in a tangential direction to penetrate the adsorption tower discharge port.
Biomass gasification syngas purification device.
The method of claim 9,
The syngas sealing device includes a rotary valve and a slide knife valve for blocking and enclosing the syngas external outflow at the upper and lower sides thereof.
Biomass gasification syngas purification device.
The method of claim 9,
The adsorption tower can be manufactured in a cylinder and square shape or a combination thereof
Biomass gasification syngas purification device.
The method of claim 9,
The adsorbent input and discharge in the adsorption tower is automatically filled from the upper hopper when the screw discharge device is operated, when the screw discharge device is lower than the input height by using a sensor that detects the interlocking adsorbent height, and the slide knife valve is attached as a double valve. To the lock hopper through the outlet
Biomass gasification syngas purification device.
The method of claim 7, wherein
The adsorbent used in the adsorption tower is supplied to the gasifier and used as gasification fuel, and the inorganic and metal adsorbents are regenerated and reused.
Biomass gasification syngas purification device.
As a purification method for purifying syngas generated in a gasifier to a level suitable for use in a gas engine,
A primary cyclone connected to a rear end of the gasifier to mainly remove dust generated in the gasifier;
A condenser connected to a rear end of the primary cyclone and cooling the syngas to recover wood vinegar;
A wet scrubber connected to a rear end of the condenser to first remove tar, dust, and acid gas in the syngas;
A secondary cyclone connected to a rear end of the wet scrubber to remove water and tar droplets in the syngas;
An adsorption tower for removing tar and moisture mist which have not been removed from the secondary cyclone;
A tertiary cyclone connected to a rear end of the adsorption tower to remove dust of the adsorbent;
Biomass gasification syngas purification method.

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