KR101223910B1 - Regeneration apparatus for wasted activated carbon - Google Patents

Abstract

The present invention relates to a waste activated carbon recycling apparatus, comprising: a low temperature rotary stirring drying furnace for drying moisture contained in waste activated carbon in a refractory thermal insulation kiln, and a high temperature activated carbon recycling apparatus.
The rotary stirring drying furnace is separated into first and second rotary stirring drying furnaces which are formed to cross in an X-shape on an inner upper side of the fireproof insulation kiln,
The first rotary agitation drying furnace has an inlet formed so as to be exposed to an upper portion of one side of the inner and insulated kilns so that the waste activated carbon can be introduced into the interior of the lower end, and a rotating power from a motor installed outside the refractory insulated kiln. It is provided with a first rotating shaft to receive and rotate the first rotating shaft, and the first stirring blade for transporting the waste activated carbon introduced into the lower end through the inlet to the high end while stirring the first opening; And
The high end of the first rotary stirring drying furnace and the low end of the second rotary stirring drying furnace are connected by a connecting passage,
The second rotary agitator drying furnace includes a second rotary shaft that receives rotational power from a motor installed outside the fireproof insulation kiln, and is rotated at a predetermined interval on the second rotary shaft to form a first rotary agitating drying furnace through the connection passage. The second stirring blade which transfers the waste activated carbon falling from the high end of a to a high end while stirring is provided,
At a high end of the second rotary agitation drying furnace, a transport passage for supplying the dried waste activated carbon to the activated carbon regeneration furnace protrudes to one side of the fireproof insulation kiln,
In the input portion formed at one end of the activated carbon regeneration furnace exposed to one side of the refractory insulation kiln, an input hopper into which dried waste activated carbon falling through the transfer passage is introduced, and waste activated carbon introduced into the input hopper is inside the activated carbon regeneration furnace. A waste activated carbon input device is installed in which a feeding screw for feeding and feeding is rotatably installed.
Spiral cooling tubes are connected to the other end of the activated carbon regeneration furnace exposed to the other side of the refractory thermal insulation kiln to spirally cool and discharge the regenerated activated carbon regenerated in the activated carbon regeneration furnace,
The discharge end of the spiral cooling tube is a invention characterized in that it is provided with a plurality of discharge passage to separate and discharge the regeneration activated carbon from small to large particle size.

Description

Regeneration apparatus for wasted activated carbon

The present invention relates to a waste activated carbon regeneration apparatus, and more particularly, to a waste activated carbon regeneration apparatus for reusing the waste activated carbon used to adsorb organic pollutants to be reused.

In order to prevent water pollution and air pollution, which are serious with the development of the heavy chemical industry, granular activated carbon having excellent adsorption capacity of organic pollutants is most used.

In the point of pursuing qualitative rather than quantitative in the treatment of tap water, the establishment of a safe and sanitary infrastructure called advanced water treatment has been established. Accordingly, the tap water purification plant has been established to improve the water quality of tap water. It is actively introducing a high-purity water treatment process using carbon, the above-mentioned granular activated carbon is deteriorated adsorption capacity after a certain period of use.

Conventionally, after using granular activated carbon for a certain period of time, when the adsorption capacity decreases, it must be replaced with a new granular activated carbon. However, when the waste activated carbon whose adsorption capacity has been degraded is disposed of, it may cause secondary pollution. In addition, there has been an economic problem, such as waste management problems and a high cost of disposing of the waste activated carbon, and the improvement of this situation is urgently required.

The present invention has been proposed to solve the conventional problems as described above, the purpose of providing a facility that can be recycled in a state that can reuse the waste activated carbon in the state that the adsorption capacity of organic contaminants in the reusable state by using for a period of time. Invented.

The present invention, as a means for pursuing the above object,

A waste activated carbon regeneration apparatus comprising a low temperature rotary stirring drying furnace and a high temperature activated carbon regeneration furnace for drying moisture contained in waste activated carbon in a fireproof thermal insulation kiln,

The rotary stirring drying furnace is separated into first and second rotary stirring drying furnaces which are formed to cross in an X-shape on an inner upper side of the fireproof insulation kiln,

The first rotary agitation drying furnace is formed to be exposed to the upper portion of the one side of the refractory thermal insulation kiln so that the waste activated carbon can be introduced into the interior of the lower end, and the rotational power from the motor installed outside the refractory thermal insulation kiln. It is provided with a first rotating shaft that is received and rotated, and the first stirring blade which is formed at a predetermined interval on the first rotating shaft to transfer the waste activated carbon introduced into the lower end through the inlet to the high end while stirring. ,

The high end of the first rotary stirring drying furnace and the low end of the second rotary stirring drying furnace are connected by a connecting passage,

The second rotary agitator drying furnace includes a second rotary shaft that receives rotational power from a motor installed outside the fireproof insulation kiln, and is rotated at a predetermined interval on the second rotary shaft to form a first rotary agitating drying furnace through the connection passage. The second stirring blade which transfers the waste activated carbon falling from the high end of a to a high end while stirring is provided,

At a high end of the second rotary agitation drying furnace, a transport passage for supplying the dried waste activated carbon to the activated carbon regeneration furnace protrudes to one side of the fireproof insulation kiln,

In the input portion formed at one end of the activated carbon regeneration furnace exposed to one side of the refractory insulation kiln, an input hopper into which dried waste activated carbon falling through the transfer passage is introduced, and waste activated carbon introduced into the input hopper is inside the activated carbon regeneration furnace. A waste activated carbon input device is installed in which a feeding screw for feeding and feeding is rotatably installed.

Spiral cooling tubes are connected to the other end of the activated carbon regeneration furnace exposed to the other side of the refractory thermal insulation kiln to spirally cool and discharge the regenerated activated carbon regenerated in the activated carbon regeneration furnace,

The discharge end of the spiral cooling tube is characterized in that it is provided with a plurality of discharge passage to separate and discharge the regeneration activated carbon from small to large particle size.

In addition, each of the plurality of discharge passages formed in the discharge end of the spiral cooling tube is divided by 4 to 8 mesh network and 12 to 30 mesh network formed between the inner diameter and the outer diameter of the spiral cooling tube, based on the size of the particle size. The first to third outlets, which are separated into medium and small sizes, are separately formed.

According to the present invention, the waste activated carbon can be recycled without recycling the waste activated carbon, which is introduced into the high-purity water treatment process of the tap water, so that the organic pollutants are adsorbed, and the ability to adsorb organic pollutants is no longer disposed. It can provide economic effects while solving the waste management problems that occur during the recycling process.In particular, in the regeneration of waste activated carbon, the waste water contained in the waste activated carbon is dried and then heated to a high temperature to burn off organic pollutants. By doing so, there is an advantage to efficiently recycle the waste activated carbon.

1 is an overall configuration diagram of the waste activated carbon recycling apparatus of the present invention,
2 is a sectional view taken along the line AA in Fig. 1,
3 is a cross-sectional view taken along line BB of FIG. 1 showing a plurality of discharge passages formed in the discharge end of the spiral cooling tube connected to the regeneration activated carbon discharge port of the activated carbon regeneration furnace of the present invention to discharge the regenerated activated carbon.

Detailed embodiments of the waste activated carbon recycling apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

Reference numeral 1 denotes a refractory insulating kiln, and first and second rotary stirring drying furnaces 2a and 2b for drying the waste activated carbon at a low temperature are formed on an upper portion of the refractory insulating kiln. An activated carbon regeneration furnace 3 for regenerating by heating the dried waste activated carbon to a high temperature is formed in the lower portion of the refractory thermal insulation kiln 1.

The first and second rotary agitation drying furnaces 2a and 2b are provided in a structure in which both ends thereof are supported by the fire-resistant insulating kiln 1 while being separated from each other and intersecting in a X shape.

Each of the first and second rotary stirring drying furnaces 2a and 2b receives rotational power from the first and second motors 4a and 4b installed outside the fireproof insulation kiln 1 to rotate. The first and second rotary shafts 21a and 21b are rotatably installed, and the first and second rotary shafts 21a and 21b are formed at predetermined intervals, respectively, and have a low end 23a (while stirring the waste activated carbon). First and second stirring blades 22a and 22b are formed to transfer from the 23b side to the higher end portions 24a and 24b, and one side of each of the first and second rotary shafts 21a and 21b. That is, at one end positioned at the high end 24a, 24b of each of the first and second rotary agitation drying furnaces 2a, 2b, stirring is performed from the first and second stirring vanes 22a, 22b. And a conveying screw (not shown) for conveying the waste activated carbon to be conveyed toward the higher ends 24a and 24b.

In the lower end 23a of the first rotary agitation drying furnace 2a, an inlet 25 through which waste activated carbon is introduced from the outside of the refractory thermal insulation kiln 1 is formed, and the first rotary agitating drying furnace ( The high end 24a of 2a and the low end 23b of the second rotary agitation drying furnace 2b are connected by a connecting passage 26. Accordingly, waste activated carbons transferred from the lower end 23a of the first rotary agitator 2a to the high end 24a are transferred to the lower end (2b) of the second rotary agitated dryer 2b through the connecting passage 26. 23b).

In addition, at a high end 24b of the second rotary agitation drying furnace 2b, a conveying passage 27 for supplying the activated activated carbon to the activated carbon regeneration furnace 3 is formed, and the conveying passage ( 27 is configured to protrude outward from one side of the fire-resistant insulation kiln 1 and to supply it to the activated carbon regeneration furnace 3.

The activated carbon regeneration furnace (3) is rolled below the refractory insulation kiln (1), both ends are installed in a structure exposed from both sides of the refractory insulation kiln (1), and also the middle portion of the activated carbon regeneration furnace (3) Is installed in a state exposed from the fire-resistant insulation kiln (see Fig. 1).

The activated carbon regeneration furnace (3) is rotatably installed in the refractory insulation kiln (1). For this purpose, the rotary gear (31) in which the activated carbon regeneration furnace (3) is mounted in the middle portion of the driving motor (5) It is connected to the drive gear 51 by a chain and is configured to rotate the activated carbon regeneration furnace 3 by receiving rotational power from the drive motor 5, and also to facilitate the smooth rotation operation of the activated carbon regeneration furnace 3. To each end and the middle portion exposed to the outside from the fire-resistant insulation kiln (1) is provided with a plurality of rotary disks 33 are rotated while being supported by a plurality of support rollers 32 as shown in FIG. .

A waste activated carbon input device 6 is connected to an input unit 34 formed on one side of the activated carbon regeneration furnace 3, and the waste activated carbon input device 6 has a high degree of a second rotary stir drying furnace 2b. Input of the activated hopper 61 to receive the dried waste activated carbon dropped through the transfer passage 27 connected to the end 24b and the activated activated carbon regeneration furnace 3 to the waste activated carbon introduced into the input hopper 61. The supply screw 61 for supplying through the part 34 is rotatably installed.

In addition, the supply screw 62 of the waste activated carbon input device 6 is configured to supply the activated activated carbon regeneration furnace 3 to the waste activated carbon introduced into the input hopper 61 while rotating by receiving rotational power from the motor 63. have.

In addition, the inner surface of the activated carbon regeneration furnace 3 is formed while stirring the stirring blades (36) for transferring the activated activated carbon supplied through the inlet (34) toward the plurality of outlets 35 at a predetermined interval toward the spiral direction It is.

On the other side of the activated carbon regeneration furnace 3, a combustion gas discharge passage 37 is formed to extend and a spiral cooling tube 7 formed to spirally surround the combustion gas discharge passage 37 is installed. The spiral cooling tube 7 receives a plurality of collection boxes collected by size while being cooled by air cooling by receiving the activated activated carbon discharged through the plurality of outlets 35 in the state where the regeneration process is completed in the activated carbon regeneration furnace 3 ( 7a) (7b) (7c) is discharged, one end (right side in the drawing) of the spiral cooling tube (7) is connected to a plurality of outlets 35, the spiral cooling tube (7) of The other end, that is, the discharge end 71 is divided into a plurality of mesh nets 74 and 75 between the inner diameter 72 and the outer diameter 73 of the spiral cooling tube 7 to discharge the regenerated activated carbon by size. Discharge passages 76, 77 and 78 are formed.

One mesh network 74 adjacent to the inner diameter 72 of the plurality of mesh networks 74 and 75 is formed of 4 to 8 meshes to be formed between the inner diameter 72 and the mesh network 74. Through the discharge passage 76, the regenerated activated carbon having a larger size than the hole of 4 to 8 mesh is discharged, and another mesh network 75 is formed of 12 to 30 mesh so that the plurality of mesh network ( The discharge passage 77 formed between 74 and 75 allows the regenerated activated carbon of medium size smaller than the holes of 4 to 8 mesh and larger than the holes of 12 to 30 mesh to be discharged. The discharge passage 78 formed between the outer diameters 73 allows the regenerated activated carbon having a size smaller than that of the 12 to 30 mesh holes to be discharged.

In addition, inside the discharge end 71 of the spiral cooling tube 7, the activated activated carbon discharged to the discharge end 71 is adjacent to the inner diameter 72 of the plurality of discharge passages 76, 77, 78. A blocking plate 79 is formed to block the other two discharge passages 77 and 78 so as to be discharged only through one discharge passage 76. The plurality of discharge passages 76 and 77 are also formed. The outlets 76a, 77a and 78a of the outlets 76a and 78a are formed at a position farthest from the outlet 76a of the outlet passage 76, based on the blocking plate 79. The discharge port 78a of the discharge passage 78 is formed at the nearest position, and the discharge hole 77a of the discharge passage 77 is formed at the intermediate position (see FIG. 3).

Therefore, since the spiral cooling tube 7 is formed in a spiral shape, the discharge holes 76a, 77a, 78a of the plurality of discharge passages 76, 77, 78 formed inside the discharge end 71 are The activated carbon is discharged at different locations, and thus, the activated carbon discharged from the outlets 76a, 77a, and 78a is collected and stored separately in a plurality of collection boxes 7a, 7b, and 7c. Will be.

On the other hand, the combustion gas discharged to the combustion gas discharge passage 37 formed at the other end of the activated carbon regeneration furnace 3 is configured to be discharged to the outside through the dust collecting chamber (8).

In addition, the activated carbon regeneration furnace 3 is heated to a high temperature in the lower portion of the refractory insulation kiln 1 so as to burn off the organic contaminants adsorbed on the dried waste activated carbon that is stirred and transported inside the activated carbon regeneration furnace 3. There are two or more buzzers 9 that can be heated.

In addition, at the high ends 24a and 24b of each of the first and second rotary stirring drying furnaces 2a and 2b, steam outlets 28a and 28b for discharging water vapor generated when the waste activated carbon is dried are provided. Is formed, the gas discharge port 11 for discharging the combustion gas and steam, etc. are formed at the upper end of the refractory insulation kiln (1).

The operation of regenerating waste activated carbon with the present invention configured as described above will be described.

When the refractory insulation kiln 1 ignites the burner 9 to heat the activated carbon regeneration furnace 3, the ignition heater of the burner 9 directly heats the activated carbon regeneration furnace 3 and at the same time the fireproof insulation kiln. The first and second rotary agitation drying furnaces 2a and 2b provided so as to intersect in a x shape on the upper part of (1) are indirectly heated.

When the activated activated carbon is introduced into the inlet 25 installed to expose one side of the refractory insulation kiln 1 while the burner 9 is ignited as described above, the activated activated carbon introduced into the inlet 25 is rotated first. High end 24a while continuously being stirred by the first stirring blade 22a which is formed at a predetermined interval on the first rotating shaft 21a which is rotated while being introduced into the lower end 23a of the stirring drying furnace 2a. The first and second rotary stir drying furnaces 2a and 2b are indirectly heated by the ignition heater of the burner 9 which directly heats the activated carbon regeneration furnace 3. Therefore, the water contained in the waste activated carbon that is introduced into the lower end 23a of the first rotary agitation drying furnace 2a and is stirred and conveyed by the first stirring blade 22a is transferred toward the high end 23a. The waste activated carbon transferred to the high end 24a of the first rotary agitation drying furnace 2a through the connecting passage 26. The water is completely dried while being dropped into the lower end 23b and transferred to the high end 24b while being stirred by the second stirring blade 22b.

The waste activated carbon completely dried while being transferred to the high end 24 b of the second rotary stirring drying furnace 2b as described above is introduced into the waste activated carbon input device 6 through the transfer passage 27. The waste activated carbon supplied into the activated carbon regeneration furnace 3 through the injection unit 34 is supplied to the inside of the input unit 34 of the activated carbon regeneration furnace 3 by the feeding screw 62. Is transferred to the outlet 35 while being agitated by the stirring feed vanes 36 formed in a spiral shape, wherein the activated carbon regeneration furnace 3 directly heated to the ignition heat of the burner 9 is organically adsorbed to the waste activated carbon. Heated at high temperatures to burn contaminants.

Therefore, the organic contaminants adsorbed on the waste activated carbon introduced and supplied through the inlet 34 of the activated carbon regeneration furnace 3 are completely calcined while being stirred and transported toward the outlet 35 and are regenerated into activated carbon. The regenerated activated carbon regenerated in the activated carbon regeneration furnace 3 is discharged to the spiral cooling tube 7 through the plurality of outlets 35, and the spiral cooling tube 7 itself rotates together with the activated carbon regeneration furnace 3. Since the regenerated activated carbon discharged through the plurality of discharge ports 35 is moved to the discharge end 71 by the rotational operation of the spiral cooling tube 7, the plurality of discharges formed in the discharge end 71 at this time. Of the passages 76, 77, 78, only the discharge passage 76 formed between the inner diameter 72 and the mesh net 76 is opened, and the remaining two discharge passages 77, 78 are blocked plate ( 79) the regeneration bow being moved to the discharge stage 71 because it is blocked by Burnt is discharged only through the above-described one of the discharge passage (76).

However, since the mesh nets 74 forming the discharge path 76 are mesh nets having large holes of 4 to 8 mesh, the activated activated carbon discharged through the discharge path 76 is 4 to 8 mesh big. Only the regenerated activated carbons having a large particle size passing through the holes are discharged through the discharge holes 76a and are stored and collected by the collection boxes 7a, and the mesh net 74 forming the discharge passages 76 is also included. A medium particle size that does not fall into the medium sized holes of the 12 to 30 mesh formed in the mesh network 75 among the regenerated activated carbons moving through the large holes of the 4-8 mesh formed in the discharge passage 77. Only the regenerated activated carbon having the discharged through the discharge port (77a) of the discharge passage 77 is to be stored and collected in the collection box (7b), and finally 12 to 12 formed in the mesh network 75 to form the discharge passage 76 30 bucks Small size activated carbon regeneration of passing through the holes of a small size are discharged through the discharge port (78a) of the discharge passage 78 formed by the outer diameter 73 will be stored and collected in a collection box (7c).

As described above, the regenerated activated carbon stored in each of the plurality of collection boxes 7a, 7b, and 7c is automatically stored separately by size, thereby providing an advantage of allowing collection by size.

1: fireproof insulation kiln 11: gas outlet
2a, 2b: first and second rotary stirring drying furnace
21a, 21b: first and second rotary shafts 22a, 22b: first and second stirring blades
23a, 23b: low end 24a, 24b: high end
25: inlet 26: connecting passage
27: transfer passage 28a, 28b: steam outlet
3: activated carbon regeneration furnace 31: rotating gear
32: support roller 33: rotating disc
34: inlet 35: outlet
36: stirring feed wing 4a, 4b: motor
5: drive motor 51: drive gear
6: waste activated carbon input device 61: input hopper
62: supply screw 63: motor
7: spiral cooling tube 71: discharge stage
72: inner diameter 73: outer diameter
74,75: mesh network 76,77,78: discharge passage
76a, 77a, 78a: outlet 79: blocking plate
8: dust collection room 9: burner

Claims (2)

A waste activated carbon regeneration apparatus comprising a low temperature rotary stirring drying furnace and a high temperature activated carbon regeneration furnace for drying moisture contained in waste activated carbon in a fireproof thermal insulation kiln,
The rotary stirring drying furnace is separated into first and second rotary stirring drying furnaces which are formed to cross in an X-shape on an inner upper side of the fireproof insulation kiln,
The first rotary agitation drying furnace is formed to be exposed to the upper portion of the one side of the refractory thermal insulation kiln so that the waste activated carbon can be introduced into the interior of the lower end, and the rotational power from the motor installed outside the refractory thermal insulation kiln. It is provided with a first rotating shaft that is received and rotated, and the first stirring blade which is formed at a predetermined interval on the first rotating shaft to transfer the waste activated carbon introduced into the lower end through the inlet to the high end while stirring. ,
The high end of the first rotary stirring drying furnace and the low end of the second rotary stirring drying furnace are connected by a connecting passage,
The second rotary agitator drying furnace includes a second rotary shaft that receives rotational power from a motor installed outside the fireproof insulation kiln, and is rotated at a predetermined interval on the second rotary shaft to form a first rotary agitating drying furnace through the connection passage. The second stirring blade which transfers the waste activated carbon falling from the high end of a to a high end while stirring is provided,
At a high end of the second rotary agitation drying furnace, a transport passage for supplying the dried waste activated carbon to the activated carbon regeneration furnace protrudes to one side of the fireproof insulation kiln,
In the input portion formed at one end of the activated carbon regeneration furnace exposed to one side of the refractory insulation kiln, an input hopper into which dried waste activated carbon falling through the transfer passage is introduced, and waste activated carbon introduced into the input hopper is inside the activated carbon regeneration furnace. A waste activated carbon input device is installed in which a feeding screw for feeding and feeding is rotatably installed.
Spiral cooling tubes are connected to the other end of the activated carbon regeneration furnace exposed to the other side of the refractory thermal insulation kiln to spirally cool and discharge the regenerated activated carbon regenerated in the activated carbon regeneration furnace,
And a plurality of discharge passages are provided at the discharge end of the spiral cooling tube so as to separate and discharge the regenerated activated carbon from the larger ones to the smaller ones.
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