KR101126290B1 - Regenerative apparatus for activated carbon - Google Patents

Abstract

PURPOSE: An apparatus for regenerating activated carbon is provided to reduce the capacity and the size of combustion gas treating facilities by implementing a drying process in the process of supplying waste activated carbon into a regenerating furnace. CONSTITUTION: An apparatus for regenerating activated carbon includes a supplying conveyor(100), a multi-staged regenerating furnace(200), a plurality of burners(300), a gas treating part(400), a rotor(500), a combustion air pipe(600), a combustion gas pipe(700), and a combustion gas outlet(800). A heat collecting part is included in the combustion gas pipe, and combustion gas passes through the heat collecting part. The heat collecting part indirectly dries waste activated carbon based on air or steam of high temperatures. The rotary shaft of the rotor is vertically installed in the regenerating furnace. The rotor scrapes the waste activated carbon arranged at a lateral side based on horizontal rotation. The combustion air pipe transfers cooling air of raised temperatures to the burners. The combustion gas pipe transfers combustion gas generated from the inside of the regenerating furnace to the supplying conveyor. The combustion gas outlet transfers the combustion gas to the gas treating part.

Description

Activated carbon regeneration device {REGENERATIVE APPARATUS FOR ACTIVATED CARBON}

The present invention relates to an activated carbon regeneration apparatus, and more particularly, by recovering and reusing waste heat generated in a waste activated carbon regeneration process, raw materials required for evaporating and removing moisture contained in waste activated carbon can be reduced, and high thermal efficiency is achieved. The present invention relates to an activated carbon regeneration device that can be obtained.

In general, activated carbon is a porous carbon that activates char or charcoal.

The activated carbon has a surface area of more than 1,000 m2 per g, due to carbonization of about 500 ° C. and activation of about 900 ° C., and a micropore of 20 mm size is developed, and van der Waals attraction force. Through it has the property of removing various organic substances harmful to the human body.

In addition, the activated carbon is a substance composed of carbon (C), and unlike general carbon, its use is very diverse as a substance named as carbon living and active.

For example, the activated carbon is widely used in environmental fields such as gas masks, tobacco filters, air purification, tap water purification, water purifier filters, and wastewater treatment.

Such activated carbon has a very high ability to remove contaminants but loses its adsorption capacity after a period of use.

In order to solve this problem, an activated carbon adsorption tower for removing contaminants is used by passing waste activated carbon filled with gaseous or liquid contaminants into a reactor.

In the case of small-capacity activated carbon adsorption towers, waste activated carbon is periodically or completely replaced with new carbon (regenerated coal, etc.) in a fixed bed type, but in a large-scale water purification plant or wastewater treatment plant, a fixed amount of waste activated carbon is continuously installed. Is replacing with Shintan.

The regeneration process of waste activated carbon is largely divided into regeneration and reactivation.

Regeneration is a method of reversible treatment such as heat desorption to remove physically adsorbed substances using energy greater than adsorption energy, and chemical desorption and microbial fermentation to desorb organic substances through activated carbon adsorbed with organic substances. Say

Reactivation is a liquid adsorption with a large number of irreversible adsorption, or a gas phase adsorption where the adsorption performance is rapidly degraded through several regenerations, and thus reversible regeneration is not easy. How to activate.

The irreversible reactivation is activated in an atmosphere of steam and carbon monoxide at 700 to 950 ° C., and when reactivation is completed, activated carbon is supplied to the adsorption tower for reuse.

The combustion gas of the waste activated carbon contains a large amount of dust and is discharged to the atmosphere through a wet scrubber without a separate waste heat recovery device.

The waste activated carbon used for the liquid adsorption is mainly supplied to the activated carbon input conveyor by hydraulic transfer, and then removed from the end portion of the input conveyor and then transferred to the regeneration furnace.

However, since activated carbon has many micropores, a large amount of water present in the pores of activated carbon is not removed, and the weight ratio of activated carbon and water is maintained at 1: 1.

This wastes unnecessary energy (1,575 ㎉ / ㎏-AC) used for drying the moisture, and the amount of heat required for the evaporation / heating of the moisture contained in the activated carbon and the temperature of the combustion air additionally supplied therefor, and the capacity of the peripheral equipment is increased. Is increased.

In addition, the capacity of the rear end equipment of about 3.3 Nm 3 / kg-AC is increased due to the increase in the amount of combustion gas of vaporized steam and additionally consumed fuel in the drying process of activated carbon.

Therefore, it is urgent to develop energy-saving waste activated carbon input equipment.

An object of the present invention is to recover the waste heat of the combustion gas exhausted from the regeneration furnace to the outside when regenerating the waste activated carbon to supply to the conveyor or dryer for raw material supply, the energy required to recover the waste heat of the combustion gas to dry the waste activated carbon It is to provide an activated carbon regeneration device that can be reused.

In addition, the present invention provides an activated carbon regeneration apparatus capable of improving the regeneration performance of activated carbon by performing drying in advance in the process of supplying waste activated carbon into the regeneration furnace.

The present invention is a feed conveyor for drying and transporting the input waste activated carbon, and the multi-stage regeneration furnace in which the waste activated carbon conveyed from the supply conveyor is introduced through the upper, and the injected waste activated carbon sequentially descends along the downward, Spaced up and down spaced on the side of the regeneration furnace, a plurality of burner facilities for regenerating the waste activated carbon by radiating a flame into the regeneration furnace, and receiving the combustion gas from the regeneration furnace and cooling the combustion And a gas treatment unit which removes dust contained in gas and discharges it to the atmosphere, wherein a rotating shaft is installed vertically inside the regeneration furnace, and a rotating body scraping the waste activated carbon located laterally by horizontal rotation, Connecting the burner facilities with the upper end of the rotary shaft, and delivers the cooling air of the heated rotary shaft to the burner equipment Combustion gas piping connecting the small air pipe, the regeneration furnace and the supply conveyor, and delivering the combustion gas generated in the regeneration furnace to the supply conveyor, and the supply conveyor or the regeneration furnace and the gas processing unit. In connection, characterized in that it comprises a combustion gas discharge pipe for delivering the combustion gas to the gas processing unit.

Here, the supply conveyor may be provided with a jacket for drying the waste activated carbon using the waste heat supplied from the outside.

In addition, the supply conveyor is connected to the upper conveyor, the waste activated carbon is introduced into one side, the lower end of the upper conveyor, the dryer for receiving and drying the waste activated carbon, and is connected to the lower end of the dryer, the dried waste A lower conveyor for introducing activated carbon into the regeneration furnace may be provided.

In addition, both ends of the combustion gas pipe may be connected to the upper end of the regeneration furnace and the lower end of the dryer, respectively.

In addition, the dryer may be provided with a jacket for drying the waste activated carbon using waste heat supplied from the outside.

In addition, the rotating body is rotatably installed through the upper end and the lower end of the regeneration furnace, the upper end is rotatably connected to one end of the combustion air pipe, the through shaft is formed vertically therein, and It may be connected to the lower end of the rotary shaft, it may be provided with a drive motor for transmitting a rotational force horizontally to the rotary shaft.

In addition, a rotary shaft cooling blower for supplying cooling air through the through hole may be further installed at the lower end of the rotary shaft.

In addition, the rotating shaft may be formed with a plurality of grooves or protrusions along the vertical longitudinal direction for scraping the waste activated carbon during horizontal rotation.

On the other hand, the combustion gas pipe further comprises a heat recovery portion through which the combustion gas passes, the heat recovery portion may indirectly dry the waste activated carbon using hot air or steam (Steam).

Here, the heat recovery unit is provided with a heat exchanger for heat exchange between the combustion gas and the drying air supplied from the outside, both ends of the combustion gas discharge pipe may be connected to the heat exchanger and the gas treatment unit, respectively.

In addition, the heat exchanger may be further connected to a dry air blower for supplying air to the heat exchanger.

In addition, the heat recovery unit may be provided as a waste heat boiler for heating the fluid using the hot air or steam (Steam), both ends of the combustion gas discharge pipe may be connected to the waste heat boiler and the gas treatment unit, respectively.

In addition, the burner facility is provided with a plurality of burners spaced apart vertically on the side of the regeneration furnace, a combustion air supply pipe connected to the burners to use the heated rotary shaft cooling air as combustion air, and a lower end of the combustion air supply pipe It is connected to, and may be provided with a combustion air blower for supplying combustion air to the burner.

In addition, the gas processing unit is connected to one end of the combustion gas discharge pipe, the combustion gas cooler for cooling the combustion gas delivered, and connected to the combustion gas cooler, after removing the dust contained in the cooled combustion gas after the atmosphere It may be provided with a combustion gas scrubber to discharge the furnace.

In addition, the combustion gas scrubber may be further provided with a manned blower for discharging the combustion gas from which dust is removed.

The present invention is to recover the waste heat of the combustion gas generated during regeneration to be reused as the energy required to dry the waste activated carbon, it is possible to reduce the consumption of raw materials to save energy.

In addition, since regeneration is performed after drying in advance in the process of supplying the waste activated carbon into the regeneration furnace, the amount of combustion gas is reduced according to the removal of water contained in the waste activated carbon and the reduction of fuel consumption. It has the effect of reducing the capacity and size of the.

1 is a view showing an activated carbon recycling apparatus according to the present invention.
2 is a view showing a state in which a heat exchanger is installed in the activated carbon regeneration apparatus according to FIG. 1.
3 is a view for showing a state in which the waste heat boiler is installed in the activated carbon regeneration device according to FIG.
Figure 4 is a view for showing that the supply conveyor of the activated carbon regeneration apparatus according to the present invention comprises an upper conveyor, a dryer and a lower conveyor.
5 is a view showing a state in which a heat exchanger is installed in the activated carbon regeneration apparatus according to FIG. 4.
6 is a view for showing a state in which the waste heat boiler is installed in the activated carbon regeneration device according to FIG.

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

Advantages and features of the present invention, and a method of achieving the same will be apparent with reference to the embodiments described below in detail with reference to the accompanying drawings.

However, the present invention is not limited to the embodiments disclosed herein, but may be embodied in various different forms, and the present embodiments only make the disclosure of the present invention complete, and those of ordinary skill in the art to which the present invention belongs. It is provided to fully inform the person having the scope of the invention, which is defined only by the scope of the claims.

In addition, in the following description of the present invention, if it is determined that related related technologies and the like may obscure the gist of the present invention, detailed description thereof will be omitted.

1 is a view for showing an activated carbon regeneration device according to the present invention, Figure 2 is a view for showing a state in which a heat exchanger (heat exchanger) is installed in the activated carbon regeneration device according to FIG.

And, Figure 3 is a view for showing a state in which a waste heat boiler (boiler) is installed in the activated carbon regeneration device according to FIG.

In addition, Figure 4 is a view for showing that the supply conveyor of the activated carbon regeneration apparatus according to the present invention comprises an upper conveyor, a dryer and a lower conveyor.

In addition, FIG. 5 is a view showing a state in which a heat exchanger is installed in the activated carbon regeneration device according to FIG. 4, and FIG. 6 is a view showing a state in which a waste heat boiler is installed in the activated carbon regeneration device according to FIG. to be.

As shown in Figs. 1 to 6, the activated carbon regeneration apparatus according to the present invention includes a supply conveyor 100, a regeneration furnace 200, a burner facility 300, a gas processing unit 400, and a rotating body ( 500, a combustion air pipe 600, a combustion gas pipe 700, and a combustion gas discharge pipe 800.

Here, the supply conveyor 100 is a waste activated carbon (C) is introduced through the inlet 101 formed on one side.

Then, the waste activated carbon (C) introduced into the interior through the inlet 101 of the supply conveyor 100 is discharged downward through the outlet 102 of the other side while drying and transporting.

Here, a jacket (not shown) may be further installed inside or outside the supply conveyor 100 along a longitudinal direction.

The jacket is to dry the waste activated carbon (C) transported along the longitudinal direction of the supply conveyor 100 by the combustion gas or steam (Steam) supplied from the outside.

Of course, the jacket is described in the preferred embodiment it can be seen that other types of devices can be used.

Alternatively, the supply conveyor 100 may be composed of an upper conveyor 110, a dryer 120 and a lower conveyor 130.

Here, the activated carbon (C) is injected into the upper conveyor 110 through an inlet 111 formed at one side.

In addition, the upper conveyor 110 discharges downward through the outlet 112 of the other side while transferring the waste activated carbon (C) introduced into the inside.

Dryer 120, the upper end is connected to the outlet 112 of the upper conveyor 110 is supplied with the waste active stage (C).

In addition, the lower end of the dryer 120 may be connected to the inlet 131 of the lower conveyor 130 to be described below.

In addition, a valve 121 for discharging or blocking the dried waste activated carbon (C) to the inlet of the lower conveyor 130 to be described below may be further installed at the lower end of the dryer 120.

In addition, the dryer 120 may be further provided with a jacket (not shown) for drying the waste activated carbon (C) by the combustion gas or steam (Steam) supplied from the outside.

The jacket dries the waste activated carbon (C) introduced into the dryer 120 by combustion gas or steam supplied from the outside.

Of course, the jacket is described in the preferred embodiment it can be seen that other types of devices can be used.

The lower conveyor 130 is injected through the inlet 131 in which waste activated carbon C dried by the dryer 120 is formed at one side.

In addition, the lower conveyor 130 discharges the waste activated carbon (C) introduced into the bottom through the outlet 132 on the other side while transferring along the longitudinal direction.

The regeneration furnace 200 is supplied with waste activated carbon (C) in a state where the upper end is connected to the outlet 132 of the lower conveyor 130.

In addition, the regeneration furnace 200 may be formed in multiple stages such that the waste activated carbon (C) introduced into the regeneration furnace descends sequentially.

Preferably, a plurality of support members 210 may be provided in the regeneration furnace 200 to form a plurality of stages up and down.

The support members 210 may be installed in a disc shape or the like along the inner wall of the regeneration furnace 200 except for the center thereof.

That is, the activated activated carbon (C) may be loaded in multiple stages in the regeneration furnace 200 by the supporting members 210.

Then, the waste activated carbon (C) can be lowered through the central portion of the support member 210 formed into an empty space.

In addition, the central portion of the support member 210 is a space that is rotated horizontally in a state in which the rotating shaft 510 of the rotating body 500 to be described later is installed vertically.

The burner facility 300 is disposed vertically spaced apart from the side of the regeneration furnace 200, and radiates a flame (hot air) into the regeneration furnace 200 to regenerate waste activated carbon (C).

The burner facility 300 as described above includes a burner 310, a combustion air supply pipe 320, and a combustion air blower 330.

Here, the burner 310 may be disposed in plurality in the vertically spaced side of the regeneration furnace (200).

The burners 310 spray flames into the regeneration furnace 200 by air supplied from the outside.

The combustion air supply pipe 320 is composed of a main pipe and a branch pipe as shown in the drawing, and burners 310 are connected to branch pipes of the combustion air supply pipe 320, respectively.

That is, the combustion air supply pipe 320 collectively supplies the cooling air or external air of the rotary shaft 510 heated in the state connected to the burners 310 to the burners 310.

The combustion air blower 330 is connected to the lower end of the combustion air supply pipe 320 to supply air for combustion.

Here, the combustion air blower 330 may be fixedly installed on the ground or a structure.

The gas processor 400 cools the combustion gas discharged from the regeneration furnace 200 as described above, and removes dust that may be included in the combustion gas and discharges it to the atmosphere.

To this end, the gas processing unit 400 is composed of a combustion gas cooler 410, combustion gas scrubber 420 and the manned blower 430.

Here, one end of the combustion gas discharge pipe 800 is connected to the combustion gas cooler 410, and cools the combustion gas delivered from the regeneration furnace 200 through the combustion gas discharge pipe 800.

The combustion gas cooler 410 cools the combustion gas by spraying cooling water through a nozzle (not shown) installed at an upper portion thereof, and in this process, a part of the dust included in the combustion gas is removed.

Flue gas scrubber 420, the combustion gas cooler 410 and the side is interconnected by a separate connecting tube (not shown), after removing the dust contained in the combustion gas cooled in the combustion gas cooler 410 To the atmosphere.

To this end, a separate cleaning gas discharge tube (not shown) having a predetermined length vertically may be further formed on the upper portion of the combustion gas cleaner 420.

The combustion gas scrubber 420 removes most of the dust that may be included in the combustion gas by spraying the washing water through a nozzle (not shown) installed at an upper portion thereof.

The attracting blower 430 is fixedly installed on the ground or the structure, and the air inlet and the exhaust port may be connected to the upper end of the combustion gas scrubber 420, respectively.

That is, the attracting blower 430 discharges the combustion gas from which the dust is removed from the combustion gas cleaner 420 to the atmosphere.

The above-described rotating body 500 serves to scrape or mix down the waste activated carbon (C) located laterally by horizontal rotation.

To this end, the rotating body 500 is composed of a rotating shaft 510, the drive motor 520 and the rotating shaft cooling blower 530.

Here, the rotation shaft 510 is rotatably installed through the upper and lower ends of the regeneration furnace 200 described above, and the upper end thereof is rotatably connected to one end of the combustion air pipe 600 to be described later.

In addition, a through hole 511 is vertically formed in the rotary shaft 510 so as to communicate the combustion air pipe 600.

In addition, a bearing (not shown) may be coupled to an upper end of the rotation shaft 510 so that the upper end of the rotation shaft 510 may be easily rotated in a state of being coupled to one end of the combustion air pipe 600.

Of course, the lower end of the rotating shaft 510 may also be coupled to a bearing (not shown) so that it can be easily rotated in a state coupled with the lower end of the regeneration furnace (200).

In addition, the rotating shaft 510 may be formed in a plurality of grooves (not shown) or protrusions (not shown) for scraping the waste activated carbon (C) during horizontal rotation along the vertical longitudinal direction.

The driving motor 520 is organically connected to the lower end of the rotation shaft 510 and transmits rotational force so that the rotation shaft 510 can be rotated horizontally. Here, the drive motor 520 may be provided with a reducer (not shown).

In addition, the driving motor 520 is fixedly installed at the lower end, the ground or a separate structure of the above-described regeneration furnace 200, and transmits the rotational force in a state of being organically connected to the lower end of the rotation shaft 510.

For example, a gear 521 that is rotated may be coupled to a rotation shaft of the drive motor 520.

In addition, a gear groove 512 meshing with the gear 521 may also be formed at the outer diameter of the lower end of the rotation shaft 510.

The rotary shaft cooling blower 530 is coupled to the lower end of the rotary shaft 510 and supplies air for cooling through the through hole 511 of the rotary shaft 510.

That is, the rotary shaft 510 may be horizontally rotated by the rotational force of the driving motor 520 to scrape and shuffle waste activated carbon introduced into the regeneration furnace 200 and simultaneously move the waste activated carbon C downward. .

In this case, since cooling air is supplied from the rotary shaft cooling blower 530 to the through hole 511, the rotary shaft 510 may be maintained at a constant temperature even in a high temperature environment.

Combustion air pipe 600 connects the upper end of the rotary shaft 510 and the burner equipment 300, the combustion air supply pipe 320 to use the air heated in the cooling process of the rotary shaft to the combustion air of the burner equipment 300 To pass.

In addition, since the heat supplied to the combustion air supply pipe 320 is supplied to the burners 310, the burners 310 reduce the consumption of fuel by the heated combustion air supplied through the combustion air pipe 600. Can be reduced.

Therefore, since the heat transmitted from the regeneration furnace 200 and the flames of the burners 310 are mixed and sprayed into the regeneration furnace 200, the heating efficiency of the burner 310 is maximized and the flames are generated at the same time. Fuel consumption can also be reduced.

The combustion gas pipe 700 connects the upper end of the regeneration furnace 200 and the lower end of the supply conveyor 100, respectively.

That is, the combustion gas pipe 700 transmits the combustion gas generated at the time of combustion in the regeneration furnace 200 to the inside of the supply conveyor 100.

Alternatively, as shown in FIG. 4, when the supply conveyor 100 includes the upper conveyor 110, the dryer 120, and the lower conveyor 130, one end of the combustion gas pipe 700 may be connected to the dryer 120. Can be connected to one side.

The combustion gas discharge pipe 800 connects the regeneration furnace 200 and the supply conveyor 100 or the regeneration furnace 200 and the gas processing unit 400.

The combustion gas discharge pipe 800 as described above transfers the combustion gas exhausted from the inside of the regeneration furnace 200 to the combustion gas cooler 410 of the gas processing unit 400.

On the other hand, the combustion gas pipe 700 may further include a heat recovery portion through which the combustion gas passes.

The heat recovery unit may indirectly dry the waste activated carbon using hot air or steam.

The heat recovery unit may be installed as a heat exchanger 900 through which combustion gas and air supplied from the outside pass.

In addition, both ends of the above-described combustion gas discharge pipe 800 may be connected to an upper end of the heat exchanger 900 and an upper end of the above-described combustion gas cooler 410, respectively.

In addition, a dry air blower 910 for supplying external air may be further connected to one side of the heat exchanger 900.

Therefore, the drying air supplied through the drying air blower passes through the heat exchanger 900, and at this time, waste heat of the combustion gas is recovered to supply the dryer 100 of the supply conveyor 100 or the aforementioned supply conveyor 100. ) Can be used for the drying of waste activated carbon.

In addition, in the case of installing the heat exchanger 900 and drying the activated activated carbon, since the supply conveyor 100 or the dryer 120 does not come into direct contact with the dust of the combustion gas, the supply conveyor 100 or the dryer 120 The operating conditions are good.

In addition, the heat recovery unit may be installed as a waste heat boiler (boiler, 900 ') through which the combustion gas passes.

In addition, both ends of the combustion gas discharge pipe 800 may be connected to an upper end of the waste heat boiler 900 ′ and an upper end of the combustion gas cooler 410 described above.

Therefore, the waste steam of the combustion gas is recovered through the waste heat boiler 900 ′ and steam supplied to the supply conveyor 100 or the dryer 120 of the above-described supply conveyor 100 is disposed of waste activated carbon (C). Can be used for drying process.

In addition, in the case of installing the waste boiler 900 'to dry the activated carbon C, since the pipe diameter of the produced steam pipe is smaller than that of the gas pipe, the peripheral pipe of the supply conveyor 100 or the dryer 120 is more efficient. It may be configured as.

As a result, the present invention can recover the heat generated during combustion and waste heat generated from the combustion gas and reuse it as the energy required to dry the waste activated carbon (C), thereby reducing the consumption of raw materials and saving energy.

In addition, since the waste activated carbon (C) is regenerated after being dried in advance in the process of being supplied into the regeneration furnace 200, it is possible to reduce the capacity and size of the burner facility 300 and the combustion gas treatment facility. .

Although specific embodiments of the activated carbon regeneration apparatus of the present invention have been described so far, it is obvious that various modifications can be made without departing from the scope of the present invention.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined not only by the claims below but also by the equivalents of the claims.

In other words, the foregoing embodiments are to be understood in all respects as illustrative and not restrictive, the scope of the invention being indicated by the following claims rather than the detailed description, and the meaning and scope of the claims and All changes or modifications derived from the equivalent concept should be interpreted as being included in the scope of the present invention.

100: supply conveyor 110: upper conveyor
120: dryer 121: valve
130: lower conveyor 200: recycling furnace
210: support member 300: burner equipment
310: burner 320: combustion air supply pipe
330: combustion air blower 400: gas processing unit
410: combustion gas cooler 420: combustion gas scrubber
430: manned blower 500: rotating body
510: rotating shaft 511: through hole
512: gear groove 520: drive motor
521: gear 530: rotary shaft cooling blower
600: combustion air piping 700: combustion gas piping
800: combustion gas discharge pipe 900: heat exchanger
910: dry air blower 900 ': waste heat boiler
C: waste activated carbon

Claims (15)

A feed conveyor for drying and transporting the injected waste activated carbon; Spaced up and down on the side, a plurality of burner facilities for regenerating the waste activated carbon by radiating a flame into the regeneration furnace, and receiving and cooling the combustion gas from the regeneration furnace and included in the combustion gas Including a gas treatment unit for removing the dust to be discharged to the atmosphere,
The rotary shaft is installed vertically inside the regeneration furnace, and connects the rotary body scraping the waste activated carbon located laterally by horizontal rotation, and connects the upper end of the rotary shaft and the burner facilities, and the cooling air of the elevated rotary shaft. Combustion air pipes to deliver to the burner facilities, the combustion gas pipes connecting the regeneration furnace and the supply conveyor, and transfer the combustion gas generated in the regeneration furnace to the supply conveyor, and the supply conveyor or the A combustion gas discharge pipe connecting the regeneration furnace and the gas processing unit to transfer the combustion gas to the gas processing unit,
The combustion gas pipe further comprises a heat recovery portion through which the combustion gas passes, and the heat recovery portion indirectly dry the waste activated carbon using hot air or steam.
The method of claim 1,
The supply conveyor,
Activated carbon regeneration apparatus, characterized in that it comprises a jacket for drying the waste activated carbon using the waste heat supplied from the outside.
The method of claim 1,
The supply conveyor,
An upper conveyor into which the waste activated carbon is introduced to one side;
A dryer connected to a lower end of the upper conveyor and configured to receive and dry the waste activated carbon;
Connected to the bottom of the dryer, activated carbon regeneration apparatus characterized in that it comprises a lower conveyor for introducing the dried waste activated carbon into the regeneration furnace.
The method of claim 3,
Both ends of the combustion gas pipe,
Activated carbon regeneration apparatus characterized in that connected to the upper end of the regeneration furnace and the lower end of the dryer, respectively.
The method of claim 3,
The dryer,
Activated carbon regeneration apparatus, characterized in that it comprises a jacket for drying the waste activated carbon using the waste heat supplied from the outside.
The method of claim 1,
The rotating body,
The rotary shaft is rotatably installed through the upper and lower ends of the regeneration furnace, the upper end is rotatably connected to one end of the combustion air pipe, the through shaft is formed vertically therein;
Activated charcoal recycling apparatus characterized in that it is connected to the lower end of the rotating shaft, the drive motor for transmitting a rotational force horizontally to the rotating shaft.
The method of claim 6,
At the bottom of the rotation shaft,
Activated carbon regeneration device characterized in that the rotary shaft cooling blower for supplying cooling air through the through hole is further installed.
The method of claim 6,
The rotation axis is,
Activated carbon regeneration apparatus characterized in that a plurality of grooves or projections for scraping the waste activated carbon at the horizontal rotation is formed along the vertical longitudinal direction.
delete The method of claim 1,
The heat recovery unit,
The combustion gas and the drying air supplied from the outside is provided with a heat exchanger,
Both ends of the combustion gas discharge pipe,
Activated carbon regeneration apparatus, characterized in that connected to the heat exchanger and the gas treatment unit, respectively.
The method of claim 10,
The heat exchanger,
Activated carbon regeneration device characterized in that the air blower for supplying air to the heat exchanger is further connected.
The method of claim 1,
The heat recovery unit,
It is provided with a waste heat boiler for heating the fluid using the hot air or steam (Steam),
Both ends of the combustion gas discharge pipe,
Activated carbon regeneration device, characterized in that connected to each of the waste heat boiler and the gas treatment unit.
The method of claim 1,
The burner facility,
A plurality of burners spaced apart vertically on the side of the regeneration furnace,
Combustion air supply pipe connected to the burners for using the heated rotary shaft cooling air as combustion air,
And a combustion air blower connected to a lower end of the combustion air supply pipe and supplying combustion air to the burner.
The method of claim 1,
The gas processing unit,
A combustion gas cooler connected to one end of the combustion gas discharge pipe and cooling the combustion gas transmitted;
And a combustion gas scrubber connected to the combustion gas cooler and configured to remove dust contained in the cooled combustion gas and discharge the exhaust gas to the atmosphere.
The method of claim 14,
The combustion gas scrubber,
Activated carbon regeneration apparatus, characterized in that the attraction fan is further installed for discharging the combustion gas dust is removed.

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