CN114940497B - Activation equipment and activation process for activated carbon production - Google Patents

Abstract

The invention belongs to the technical field of activated carbon, and in particular relates to activating equipment and an activating process for producing activated carbon, wherein the activating equipment comprises an activating furnace; the activation oven includes a housing; the shell is divided into a preheating zone, a supplementary carbonization zone, an activation zone and a cooling zone from top to bottom; a regenerator is arranged on one side of the shell; the heat accumulation chamber is communicated with a supplementary carbonization zone inside the shell; the upper end of the shell is provided with a feeding groove; the lower end of the shell is provided with a discharge opening; according to the invention, through the arrangement of the blanking pipe, the blanking pipe can rotate under the drive of the rotating mechanism, so that the position of the vent hole where water vapor enters is changed, the excessive water content of the carbonized material at the position caused by the fact that the water vapor enters only from a single vent hole facing the water vapor is avoided, the aggregation of carbon ash on the surface of the carbonized material is reduced, the carbon ash at the position of the vent hole caused by the excessive combustion of the carbon powder is avoided, the water vapor inlet amount of the vent hole is improved, and the activation effect and activation efficiency of the carbonized material in a product channel are improved.

Description

Activation equipment and activation process for activated carbon production

Technical Field

The invention belongs to the technical field of activated carbon, and particularly relates to activating equipment and an activating process for activated carbon production.

Background

The activated carbon is a carbon-based adsorption material with excellent texture and increasingly widely applied, the Style-Pu activation furnace is a main activation furnace type used in the activated carbon industry of China, and is mainly used for activating activated carbon for producing coal quality, in the traditional Style-Pu activation furnace, a furnace core comprises a preheating section, a supplementary carbonization section, an activation section and a cooling section from top to bottom, and the furnace type is often blocked in a production path due to ash content, moisture and the like of production raw materials in daily production, so that the yield of the activation furnace, the quality of the activated carbon and the recorded service life are influenced.

The product channel of the existing SiP activation furnace is communicated with the vertical direction of the activation air channel, so that water vapor in the activation air channel enters the product channel through the air vent, the water vapor activates carbonized materials in the product channel, so that the carbonized materials close to the air vent towards the water vapor are overhigh in water content, more carbon powder is adhered to the surface of the carbonized materials, along with the aggregation of the carbon powder, the carbonized materials close to the air vent towards the water vapor are directly contacted with the water vapor, the carbon powder on the surface of the carbonized materials is overfired to generate carbon ash, and a large amount of carbon ash is generated to easily cause a nodulation phenomenon, so that the air vent of the product channel is easily blocked, and the activation effect and activation efficiency of the carbonized materials in the product channel are reduced.

In view of the above, the present invention provides an activation device and an activation process for activated carbon production, which solve the above technical problems.

Disclosure of Invention

In order to make up the defects of the prior art, the invention provides the activating equipment and the activating process for producing the activated carbon, and the activating equipment used in the invention enables the blanking pipe to rotate under the drive of the rotating mechanism through the arrangement of the blanking pipe, so that the position of the vent hole for entering the water vapor is changed, the condition that the water content of the carbonized material is too high due to the fact that the water vapor enters the vent hole which faces the water vapor only from a single direction is avoided, the aggregation of the carbon ash on the surface of the carbonized material is reduced, the carbon ash nodulation at the position of the vent hole caused by the overfiring of the carbon powder is avoided, the water vapor inlet amount of the vent hole is improved, and the activating effect and the activating efficiency of the carbonized material in a product channel are improved.

The technical scheme adopted for solving the technical problems is as follows: the invention relates to an activating device for producing active carbon, which comprises an activating furnace; the activation furnace includes:

a housing; the shell is divided into a preheating zone, a supplementary carbonization zone, an activation zone and a cooling zone from top to bottom; a regenerator is arranged on one side of the shell; the heat accumulation chamber is communicated with a supplementary carbonization zone inside the shell; the upper end of the shell is provided with a feeding groove; the lower end of the shell is provided with a discharge opening;

Product channel; the middle part of the product channel is rotationally connected with a blanking pipe; the blanking pipe is positioned in the activation zone area of the shell; the outer wall of the blanking pipe is provided with a vent hole; the product channel is vertically arranged in the shell; one end of the product channel is communicated with the feeding groove, and the other end of the product channel is communicated with the discharging opening; grid grooves are formed in the blanking pipe;

a rotating mechanism; the rotating mechanism is arranged on the outer wall of the blanking pipe; the rotating mechanism drives the discharging pipe to rotate under the pushing of the water vapor;

a controller; the controller is used for controlling the operation of the whole activation furnace.

Preferably, the rotating mechanism comprises a blade; the blade plate is fixed on the surface of the blanking pipe; the blade plates are obliquely arranged; a baffle is arranged in the shell.

Preferably, the cross section of the blade plate is arc-shaped; the concave surface of the arc-shaped blade plate faces the blanking pipe.

Preferably, the middle part of the blade plate is provided with an arc hole; the inner wall of the blanking pipe is connected with a pushing module in a sliding manner; the pushing module comprises a push rod and a push plate; the outer wall of the blanking pipe is provided with a mounting groove communicated to the inside; the push rod is rotationally connected in the mounting groove through a torsion spring; the pushing plate is connected to the inner wall of the blanking pipe in a sliding manner; one end of the push rod is hinged with the push plate, and the other end of the push rod is fixedly connected with the wind shield; the wind shield is opposite to the arc-shaped hole; arc plates are arranged on two sides of the blanking pipe; the two adjacent arc plates are positioned between the shell and the baffle, and one surface of the two adjacent arc plates, which is far away from each other, is fixedly connected with the shell and the baffle respectively.

Preferably, a square groove is formed in one surface, close to the arc-shaped hole, of the wind shield.

Preferably, a semicircular groove is formed in one surface, close to the arc-shaped hole, of the wind shield.

Preferably, the number of the blanking pipes is at least 4; the two adjacent blanking pipes are connected through threads; the inclined directions of the blades of two adjacent blanking pipes are opposite; the screw thread rotation directions of the two adjacent screw thread joints are opposite; the outer wall of the blanking pipe is connected with a sleeve in a sliding manner; the sleeve is positioned at the threaded connection position of two adjacent blanking pipes.

Preferably, an annular pipe is arranged in the blanking pipe; the grid grooves are formed in the inner wall of the annular tube; a T-shaped groove is formed in the inner wall of the blanking pipe; the T-shaped groove is connected with a connecting rod in a sliding way; one end of the connecting rod penetrates into the annular tube, and the other end of the connecting rod is fixedly connected with a sliding block; a spring is fixedly connected to one surface of the sliding block, which is far away from the connecting rod; one end of the spring far away from the sliding block is in sliding contact with the bottom of the T-shaped groove; the inner wall of the T-shaped groove is provided with a clamping groove.

The invention discloses an activation process for producing active carbon, which is suitable for an activation device provided with a pushing module and comprises the following steps:

S1: the worker closes the discharge opening first and then adds the carbonized material from the feed tank, so that the carbonized material fills the product channel and the blanking pipe at the cooling belt; the controller controls the opening of the regenerator, so that the superheated steam in the regenerator enters the supplementary carbonization zone and flows to the activation zone from the supplementary carbonization zone, and the steam flows in a zigzag manner in the activation zone as an activation medium;

s2: when the steam flows through the blanking pipe, the steam which is positively flushed into the blanking pipe can enter the blanking pipe through the vent holes of the blanking pipe, so that the steam which enters the blanking pipe continuously flows into the blanking pipe, the steam activates carbonized materials in the blanking pipe, the steam which is blown to the blade plate on the outer wall of the blanking pipe pushes the blade plate and drives the blanking pipe to rotate, the rotation directions of two adjacent blanking pipes are opposite, the two blanking pipes in the middle are fixedly connected through rotation threads, and the uppermost blanking pipe is lowered under the action of gravity after the rotation of the uppermost blanking pipe is lifted to the thread separation; the uppermost blanking pipe and the two blanking pipes which are in threaded connection with the middle part are always in a shaking state;

s3: the water vapor blocked by the blade plate can flow along the surface of the blade plate, which is close to the outer wall of the blanking pipe, towards the direction of the arc-shaped hole, so that the water vapor is sprayed from the arc-shaped hole to the wind shield; the wind shield drives the push rod to overcome the torsion of the torsion spring under the blowing of the water vapor, so that the push rod rotates along the hinging point between the push rod and the torsion spring, the push rod pushes the push plate to swing along the inner wall of the blanking pipe, and the push plate can push the carbonized material to swing in the blanking pipe;

S4: after the carbonization material is activated, opening a discharge opening to enable the carbonization material in the cooling belt to be taken out, at the moment, enabling the carbonization material in the activation belt to fall into the cooling belt, closing the discharge opening, at the moment, enabling the carbonization material in the supplementary carbonization belt to fall into an activation belt area, enabling the carbonization material in the preheating belt to fall into a supplementary carbonization belt area, adding the carbonization material into a feeding tank by a worker, and accordingly supplementing the carbonization material in the preheating belt, after the activation of the carbonization material in the activation belt is completed, cooling the carbonization material after the activation in the cooling belt is completed, and taking out the carbonization material in the cooling belt by the worker to obtain the carbonization material;

s5: when the activated carbonized material is taken out, firstly removing dust in activated pores of the carbonized material by a negative pressure adsorption box, and then drying the carbonized material with the dust removed, thereby finally obtaining the required activated carbon.

The invention discloses an activation process for producing active carbon, which is suitable for an activation device provided with an annular pipe and comprises the following steps:

s1: the worker closes the discharge opening first and then adds the carbonized material from the feed tank, so that the carbonized material fills the product channel and the blanking pipe at the cooling belt; the controller controls the opening of the regenerator, so that the superheated steam in the regenerator enters the supplementary carbonization zone and flows to the activation zone from the supplementary carbonization zone, and the steam flows in a zigzag manner in the activation zone as an activation medium;

S2: when the steam flows through the blanking pipe, the steam which is positively flushed into the blanking pipe can enter the blanking pipe through the vent holes of the blanking pipe, so that the steam which enters the blanking pipe continuously flows into the blanking pipe, the steam activates carbonized materials in the blanking pipe, the steam which is blown to the blade plate on the outer wall of the blanking pipe pushes the blade plate and drives the blanking pipe to rotate, the rotation directions of two adjacent blanking pipes are opposite, the two blanking pipes in the middle are fixedly connected through rotation threads, and the uppermost blanking pipe is lowered under the action of gravity after the rotation of the uppermost blanking pipe is lifted to the thread separation; the uppermost blanking pipe and the two blanking pipes which are in threaded connection with the middle part are always in a shaking state;

s3: in the process that the blade plate drives the blanking pipe to rotate, the blanking pipe drives the annular pipe to synchronously rotate through the sliding block and the connecting rod which are clamped with the clamping groove, when carbonized materials in the blanking pipe are excessive, the carbonized materials can squeeze the connecting rod, so that the connecting rod pushes the sliding block to squeeze the spring, the sliding block extends out of the clamping groove, and the sliding block is ensured to slide in the T-shaped groove;

s4: after the carbonization material is activated, opening a discharge opening to enable the carbonization material in the cooling belt to be taken out, at the moment, enabling the carbonization material in the activation belt to fall into the cooling belt, closing the discharge opening, at the moment, enabling the carbonization material in the supplementary carbonization belt to fall into an activation belt area, enabling the carbonization material in the preheating belt to fall into a supplementary carbonization belt area, adding the carbonization material into a feeding tank by a worker, and accordingly supplementing the carbonization material in the preheating belt, after the activation of the carbonization material in the activation belt is completed, cooling the carbonization material after the activation in the cooling belt is completed, and taking out the carbonization material in the cooling belt by the worker to obtain the carbonization material;

S5: when the activated carbonized material is taken out, firstly removing dust in activated pores of the carbonized material by a negative pressure adsorption box, and then drying the carbonized material with the dust removed, thereby finally obtaining the required activated carbon.

The beneficial effects of the invention are as follows:

1. according to the invention, the activating equipment is arranged through the blanking pipe, so that the blanking pipe can rotate under the drive of the rotating mechanism, the position of the vent hole for entering water vapor is changed, the condition that the water content of the carbonized material is too high due to the fact that the water vapor enters the vent hole from a single direction, and the aggregation of carbon ash on the surface of the carbonized material is reduced, the carbon ash at the position of the vent hole caused by the overfire of the carbon powder is avoided, the water vapor inlet amount of the vent hole is improved, and the activating effect and activating efficiency of the carbonized material in a product channel are improved.

2. According to the activation equipment used in the invention, the square groove is formed in one surface of the wind deflector, which is close to the arc hole, so that the amount of water vapor blown out by the arc hole is increased by the square groove, the blocking effect of the wind deflector on the water vapor blown out by the arc hole is improved, the pushing force of the water vapor on the wind deflector is improved, the pushing plate can quickly push the carbonized material to move, the dropping of the carbon ash is accelerated, and the practical application effect of the activation equipment is improved.

Drawings

The invention will be further described with reference to the drawings and embodiments.

FIG. 1 is a flow chart of the present invention with a push module installed;

FIG. 2 is a flow chart of the present invention with an annular tube installed;

FIG. 3 is a perspective view of the present invention;

FIG. 4 is a schematic view of a push module of the present invention;

FIG. 5 is a cross-sectional view at A-A in FIG. 4;

FIG. 6 is an enlarged view at B in FIG. 4;

FIG. 7 is an enlarged view at C in FIG. 5;

FIG. 8 is a schematic view of the structure of the blanking pipe with the annular pipe installed in the present invention;

FIG. 9 is a cross-sectional view taken at D-D of FIG. 8;

in the figure: 1. a housing; 11. a discharge port; 111. a preheating zone; 112. supplementing a carbonization belt; 113. an activation belt; 114. a cooling belt; 115. a regenerator; 116. product channel; 12. a blade; 13. an arc-shaped hole; 14. a sleeve; 15. an annular tube; 16. a T-shaped groove; 161. a connecting rod; 162. a slide block; 163. a spring; 164. a clamping groove; 2. discharging pipes; 21. a vent hole; 22. grid grooves; 3. a push rod; 31. a push plate; 32. a mounting groove; 33. a wind deflector; 34. a groove; 4. a baffle; 5. an arc-shaped plate.

Detailed Description

The invention is further described in connection with the following detailed description in order to make the technical means, the creation characteristics, the achievement of the purpose and the effect of the invention easy to understand.

As shown in fig. 1 to 9, an activation apparatus for activated carbon production according to the present invention includes an activation furnace; the activation furnace includes:

a housing 1; the shell 1 is divided into a preheating zone 111, a supplementary carbonization zone 112, an activation zone 113 and a cooling zone 114 from top to bottom; a regenerator 115 is arranged on one side of the shell 1; the regenerator 115 is communicated with a complementary carbonization zone 112 inside the shell 1; the upper end of the shell 1 is provided with a feeding groove; the lower end of the shell 1 is provided with a discharge opening 11;

a product lane 116; the middle part of the product channel 116 is rotatably connected with a blanking pipe 2; the blanking pipe 2 is positioned in the area of the activation belt 113 of the shell 1; the outer wall of the blanking pipe 2 is provided with a vent hole 21; the product channel 116 is vertically installed inside the housing 1; one end of the product channel 116 is communicated with the feeding groove, and the other end is communicated with the discharge opening 11; a grid groove 22 is formed in the blanking pipe 2;

a rotating mechanism; the rotating mechanism is arranged on the outer wall of the blanking pipe 2; the rotating mechanism drives the blanking pipe 2 to rotate under the pushing of water vapor;

a controller; the controller is used for controlling the operation of the whole activation furnace;

in the prior art, the product channel 116 in the activation furnace is communicated with the activation air channel in the vertical direction, so that water vapor in the activation air channel enters the product channel 116 through the air vent 21, the water vapor activates carbonized materials in the product channel 116, so that the moisture of the carbonized materials close to the air vent 21 facing the water vapor is overhigh, more carbon powder is adhered to the surface of the carbonized materials, the carbon powder gathers along with the carbonized materials close to the air vent 21 facing the water vapor, and the carbonized materials close to the air vent 21 facing the water vapor are directly contacted with the water vapor due to the surface carbon powder, so that the carbon powder on the surface of the carbonized materials is overfired to generate carbon ash, and the generation of a large amount of carbon ash easily causes a nodulation phenomenon, so that the air vent 21 of the product channel 116 is easily blocked, and the activation effect and activation efficiency of the carbonized materials in the product channel 116 are reduced;

When the device works, a worker opens an external high-pressure air pump, so that the water vapor in the conveying regenerator 115 of the high-pressure air pump enters the shell 1, and the water vapor forms high-speed air flow in the shell 1, thereby ensuring that the water vapor can push a rotating mechanism in the shell 1 to rotate; pouring the carbonized material into the shell 1 through the charging tank, so that the carbonized material enters the preheating zone 111 of the shell 1, preheating and removing moisture of the carbonized material, when the discharge opening 11 is opened, taking out the carbonized material after the bottom end of the product channel 116 is activated, at the moment, the carbonized material located in the preheating zone 111 falls to the supplementary carbonized zone 112 under the action of gravity, so that the carbonized material is indirectly heated at high temperature in the supplementary carbonized zone 112, thereby carrying out supplementary carbonization on the carbonized material, the carbonized material after the activation in the product channel 116 is taken out, the carbonized material of the supplementary carbonized zone 112 falls into the blanking tube 2 of the activation zone 113, and as the heat storage chamber 115 continuously passes through overheated vapor in the shell 1, the vapor flows in the activation zone 113, and flows into the vent hole 21, and is gushed out to one end of the product channel 116 away from the vent hole 21, so that the carbonized material is directly contacted with the vapor for activation, the gas rotates through the blowing rotating mechanism, the rotating mechanism drives the blanking tube 2 to rotate, the carbonized material 2 drives the blanking tube 2 to rotate through the internal groove 22, and the ash is prevented from entering the vent hole 21, the vent hole 21 is prevented from being blown into the vent hole 2, and the dust is prevented from entering the vent hole 21, and the activated material is prevented from entering the vent hole 21, and the surface of the activated material is prevented from entering the vent hole 21, and the vent hole is prevented from being blown into the surface into the vent hole, and the vent hole from the activated hole from the surface, and the activated material; when the discharge opening 11 is opened, taking out the carbonized material after the activation at the bottom end of the product channel 116, so that the carbonized material of the activation belt falls to the cooling belt 114 for cooling, the next time the discharge opening 11 is opened is facilitated, and staff can take out the carbonized material in the cooling belt 114;

According to the invention, through the arrangement of the blanking pipe 2, the blanking pipe 2 can rotate under the drive of the rotating mechanism, so that the position of the vent hole 21 for entering water vapor is changed, the condition that the water content of carbonized materials is too high due to the fact that the water vapor enters only from a single vent hole 21 facing the water vapor is avoided, the aggregation of carbon ash on the surfaces of the carbonized materials is reduced, the carbon ash nodulation at the position of the vent hole 21 due to the over-burning of the carbon powder is avoided, the water vapor inlet amount of the vent hole 21 is improved, and the activation effect and activation efficiency of the carbonized materials in the product channel 116 are improved.

As one embodiment of the present invention, the rotating mechanism includes a blade 12; the blade plate 12 is fixed on the surface of the blanking pipe 2; the blade 12 is arranged obliquely; a baffle 4 is arranged in the shell 1; when the high-pressure air pump works, the blades 12 are obliquely arranged, so that the water vapor conveyed by the high-pressure air pump forms high-speed air flow in the shell 1 and pushes the blades 12 to rotate; the surface of the blade 12, which is close to the blanking pipe 2, and the surface of the blanking pipe 2 are blocked, so that the steam blown between the blade 12 and the blanking pipe 2 can push the blade 12 to drive the blanking pipe 2 to rotate, the steam blown to the surface of the blade 12, which is far away from the blanking pipe 2, flows along the surface of the blade 2, which is far away from the blanking pipe 2, so that the blade 12 has a diversion effect on the steam, which is far away from the blanking pipe 2, and the baffle 4 is arranged, so that the steam entering the shell 1 can be shone into the blanking pipe 2 under the blocking of the baffle 4, thereby avoiding the steam from shoving into two sides of the blanking pipe 2, improving the thrust of the steam on the surface of the blanking pipe 2, and further ensuring that the blade 12 is pushed by enough steam to drive the blanking pipe 2 to rotate; when the steam flows to the discharging pipe 2, the steam can blow the blade 12 on the surface of the discharging pipe 2, so that the blade 12 drives the discharging pipe 2 to rotate, and when the discharging pipe 2 rotates, the grid grooves 22 can drive the internal carbonized material to rotate, so that the steam is prevented from entering from the surface part of the discharging pipe 2 towards the steam vent holes 21, the too high moisture of the carbonized material near the steam vent holes 21 is prevented, and the blade 12 is obliquely arranged, so that the steam vertically blown to the discharging pipe 2 can push the blade 12 to rotate towards one direction, thereby improving the rotating effect of the blade 12, and improving the practicability of the invention.

As an embodiment of the present invention, the cross-sectional shape of the blade 12 is arc-shaped; the concave surface of the arc-shaped blade plate 12 faces the blanking pipe 2; when the blanking pipe is in operation, the shape of the blade 12 is arc, so that the closer the blade 12 is to the central part of the blanking pipe 2, the more the blade is blocked to water vapor, the more the pushing force of the water vapor is concentrated on the edge of the central part of the blanking pipe 2, and the pushing force of the water vapor to the blanking pipe 2 is concentrated, thereby improving the pushing effect of the water vapor to the blanking pipe 2, accelerating the rotation of the blanking pipe 2, further preventing the excessive water content of the carbonized material at the position caused by the water vapor entering from the single vent hole 21 facing the water vapor, and further improving the practicability of the blanking pipe.

As an embodiment of the present invention, the middle part of the blade 12 is provided with an arc hole 13; the inner wall of the blanking pipe 2 is connected with a pushing module in a sliding manner; the pushing module comprises a push rod 3 and a push plate 31; the outer wall of the blanking pipe 2 is provided with a mounting groove 32 communicated to the inside; the push rod 3 is rotatably connected in the mounting groove 32 through a torsion spring; the pushing plate 31 is connected to the inner wall of the blanking pipe 2 in a sliding manner; one end of the push rod 3 is hinged with the push plate 31, and the other end of the push rod is fixedly connected with the wind shield 33; the wind shield 33 is opposite to the arc-shaped hole 13; arc plates 5 are arranged on two sides of the blanking pipe 2; two adjacent arc plates 5 are positioned between the shell 1 and the baffle 4, and one surface of each adjacent arc plate 5, which is far away from each other, is fixedly connected with the shell 1 and the baffle 4 respectively; during operation, in an initial state, the wind shield 33 is in contact with the groove wall of the mounting groove 32, the wind shield 33 is in sliding contact with one surface of the arc plate 5, which is close to the blanking pipe 2, when water vapor enters the activation belt 113, the water vapor enters between the two arc plates 5 under the guidance of inclined surfaces at two ends of the arc plate 5, so that the water vapor blows the blade plate 12 to drive the whole blanking pipe 2 to rotate, and when part of water vapor air current blows to one surface of the blade plate 12, which is far away from the blanking pipe 2, the water vapor air current flows to the wind shield 33 under the guidance of the inclined surfaces of the blade plate 12, so that the water vapor air current pushes the wind shield 33 to the mounting groove 32, the wind shield 33 is blocked by the mounting groove 32, so that the wind shield 33 generates thrust to the groove wall of the mounting groove 32 under the air current blowing, and the wind shield 33 drives the whole blanking pipe 2 to rotate through pushing the groove wall of the mounting groove 32, and in sliding contact between the wind shield 33 and the arc plate 5, so that the air current blows the wind shield 33 drives the whole blanking pipe 2 to rotate between the two arc plates 5, and the wind shield 33 is blocked by the surface of the arc plate 5, and the effect of the air current is not diffused to the wind shield 33 is improved; so that the blowing force of the air flow to the wind shield 33 is improved, and the pushing force of the water vapor to the blanking pipe 2 is further improved; the end of the wind shield 33, which is far away from the push plate 31, is a curved end, and in the process of rotating the wind shield 33, the curved end of the wind shield 33 is in line contact with the inner wall of the arc plates 5, so that friction between the wind shield 33 and the arc plates 5 is reduced, and the water vapor is ensured to push the wind shield 33 to rotate between the two arc plates 5; when the blade 12 rotates to the direction facing the steam, the diameter of the arc-shaped hole 13 is smaller than the gap formed between the blade 12 and the outer wall of the blanking pipe 2, so that the blade 12 still has a blocking effect on the steam, the steam blows the blade 12 to rotate, the steam flows along the surface of the blade 12 close to the outer wall of the blanking pipe 2 towards the arc-shaped hole 13, the steam is compressed between the blade 12 and the outer wall of the blanking pipe 2, the steam flow velocity flowing out of the arc-shaped hole 13 is increased, and the force of the steam blowing to the wind shield 33 through the arc-shaped hole 13 is increased; because the hinge point of the torsion spring and the push rod 3 is positioned at the center of the push rod 3; the wind shield 33 drives the push rod 3 to rotate in the mounting groove 32 under the pushing of the water vapor, so that the push rod 3 overcomes the torsion force of the torsion spring, the push rod 3 rotates along the hinging point in the center of the push rod 3, one end of the push rod 3 far away from the wind shield 33 drives the push plate 31 to move, the push plate 31 slides in the blanking pipe 2, the charred material is filled in the blanking pipe 2, the push plate 31 is contacted with the charred material, the charred material positioned in the sliding direction of the push plate 31 is pushed by one end of the push plate 31 in the moving process of the push plate 31, the charred material is pushed by the push plate 31 to synchronously move with the push plate 31, the push plate 31 pushes the charred material in the advancing direction of the push plate to move, when the blade 12 rotates to the direction opposite to the water vapor, the water vapor is not blown to the blade 12 any more, so that the wind shield 33 is not pushed by the water vapor any more, and at the moment, the push rod 3 drives the push plate 31 to reset under the action of the restoring force of the torsion spring, so that the push plate 31 can continuously push the carbonized material at the vent hole 21 to shake, so that the carbon powder and the carbon ash adhered to the carbonized material around the vent hole 21 can fall off under the shake of the push plate 31, the carbon ash falls off to the cooling belt 114, the quantity of the carbon ash adhered to the carbonized material at the vent hole 21 is reduced, the nodulation of the carbon ash is reduced, the water vapor inlet quantity of the vent hole 21 is further improved, and the activation effect and activation efficiency of the carbonized material in the product channel 116 are improved.

As an embodiment of the present invention, a square groove 34 is formed on one surface of the wind deflector 33 close to the arc hole 13; in operation, the square groove 34 is arranged on one surface of the wind deflector 33 close to the arc hole 13, so that the square groove 34 blocks the quantity of water vapor blown out of the arc hole 13 to be increased, most of the water vapor entering between two adjacent arc plates 5 can flow between the blanking pipe 2 and the blade 12 along the outer wall of the blanking pipe 2 due to the blocking of the outer wall of the blanking pipe 2, the side wall of the air flow close to the blanking pipe 2 by the blade 12 is blocked, the air flow pushes the side wall of the blade 12 close to the blanking pipe 2, the air flow pushes the blade 12 to drive the whole blanking pipe 2 to rotate, the air flow still containing part of the water vapor blows to the surface of the blade 12 far away from the blanking pipe 2, the surface of the blade 12 far away from the blanking pipe 2 is an inclined surface, the water vapor air flow flows to the wind deflector 33 along the inclined surface of the blade 12 under the diversion effect of the inclined surface of the blade 12, the air flow blows to the groove 34 of the wind deflector 33, most of the water vapor entering between the blade 12 and the blanking pipe 2 flows to the arc-shaped hole 13 along the surface of the blade 12 close to the blanking pipe 2 in the process of pushing the blade 12 to rotate and is sprayed out from the arc-shaped hole 13, and the air flow entering between the blanking pipe 2 and the blade 12 is more due to the smaller arc-shaped hole 13, so that the water vapor along the surface of the blade 12 close to the blanking pipe 2 is blocked and compressed by the surface of the blade 12 close to the blanking pipe 2 and the outer wall of the blanking pipe 2, the converged and compressed water vapor enters the arc-shaped hole 13 and is sprayed to the wind shield 33, at the moment, the air flow sprayed out from the arc-shaped hole 13 impacts the wind shield 33, the air flow sprayed out from the arc-shaped hole 13 is guided by the inclined surface of the wind shield 33 to be converged with the water vapor flowing towards the wind shield 33, so that the two water vapors are blown towards the wind shield 33 together and push the wind shield 33 to rotate, and the driving force of the water vapor to the wind shield 33 is improved, not only quickening the swing of the wind shield 33 and driving the push plate 31 to push the carbonized material to move and quickening the dropping of the charcoal ash, but also improving the pushing force of the wind shield 33 to the wall of the installation groove 32, so that the pushing force of the wind shield 33 to the blanking pipe 2 is improved, and further the practical application effect of the invention is improved.

As an embodiment of the present invention, a semicircular groove 34 is formed on one surface of the wind deflector 33 near the arc hole 13;

during operation, the semicircular groove 34 is formed in one surface of the wind shield 33 close to the arc-shaped hole 13, so that water vapor blocked by the semicircular groove 34 is concentrated in the center of the groove bottom of the semicircular groove 34, and the pushing force of the water vapor to the wind shield 33 is mainly concentrated in the center of the semicircular groove 34, so that the pushing force of the water vapor to the wind shield 33 is improved, the pushing plate 31 can quickly push carbonized materials to move, dropping of charcoal ash is accelerated, the same groove depth is achieved, the semicircular groove 34 formed in the wind shield 33 is less in material removed compared with the square groove 34, the structural strength of the wind shield 33 formed in the semicircular groove 34 is improved, and the practicability of the wind shield is improved.

As one embodiment of the present invention, the number of the blanking pipes 2 is at least 4; the two adjacent blanking pipes 2 are connected through threads; the inclined directions of the blades 12 of the two adjacent blanking pipes 2 are opposite; the screw thread rotation directions of the two adjacent screw thread joints are opposite; the outer wall of the blanking pipe 2 is connected with a sleeve 14 in a sliding manner; the sleeve 14 is positioned at the threaded connection part of two adjacent blanking pipes 2; when the device works, at least four blanking pipes 2 in the same water vapor channel are in a covering state in an initial state, and the four blanking pipes 2 are not connected to a tight thread; when the water vapor blows the discharging pipe 2 to rotate, the blade 12 of the two adjacent discharging pipes 2 is opposite in inclination direction, so that the two adjacent discharging pipes 2 rotate in opposite directions, the uppermost discharging pipe 2 and the discharging pipe 2 adjacent below the uppermost discharging pipe rotate in a threaded manner and are far away from each other, and in the same way, the two discharging pipes 2 positioned in the middle rotate to be fixedly connected, so that the gap between the two discharging pipes 2 positioned in the middle is reduced, at the moment, the uppermost discharging pipe 2 is lowered, at the moment, the uppermost discharging pipe 2 is still in rotary connection with the shell 1, and the uppermost discharging pipe 2 is lowered, so that a gap is formed between the uppermost discharging pipe 2 and the shell 1, and the two discharging pipes 2 which are far away from each other cannot be separated due to the arrangement of the sleeve 14, and the uppermost discharging pipe 2 and the shell 1 are in rotary connection, so that when the uppermost discharging pipe 2 ascends, the uppermost discharging pipe 2 cannot be in contact with the shell 1, the gap between the uppermost discharging pipe 2 and the uppermost discharging pipe 2 is not in the rotary connection, and the uppermost discharging pipe 2 can be prevented from being separated from each other due to the fact that the gravity force acts on the uppermost discharging pipe 2, and the uppermost discharging pipe 2 is separated to the uppermost discharging pipe 2 after the upper end is in a shaking state, and the uppermost discharging pipe is separated under the condition; similarly, the lowermost blanking pipe 2 cannot continuously descend, and the two blanking pipes 2 in the middle are lifted to be separated from the lowermost blanking pipe 2 and then descend, so that the charring material in the blanking pipe 2 is in a shaking state all the time, the charring material is accelerated to fall to the cooling belt 114, the amount of the charring material adhered to the charring material at the vent hole 21 is further reduced, the caking of the charring material is reduced, and meanwhile, the inflow amount and inflow speed of water vapor in the charring material are improved, so that the practical application effect of the invention is effectively improved.

As an embodiment of the present invention, an annular tube 15 is disposed in the blanking tube 2; the grid grooves 22 are formed in the inner wall of the annular tube 15; a T-shaped groove 16 is formed in the inner wall of the blanking pipe 2; a connecting rod 161 is slidably connected to the T-shaped groove 16; one end of the connecting rod 161 stretches into the annular tube 15, and the other end is fixedly connected with a sliding block 162; a spring 163 is fixedly connected to one surface of the sliding block 162 away from the connecting rod 161; one end of the spring 163 far away from the sliding block 162 is in sliding contact with the bottom of the T-shaped groove 16; the inner wall of the T-shaped groove 16 is provided with a clamping groove 164; when the blanking pipe is in operation, the outer wall of the annular pipe is provided with a limit groove, a spring 163 is made of nickel-based superalloy material, in an initial state, a slide block 162 is positioned in a clamping groove 164 and is inserted into the limit groove, so that when the blanking pipe 2 rotates, the slide block 162 is driven by the wall of the clamping groove 164 to rotate, the slide block 162 inserted into the limit groove can push the annular pipe 15 to rotate, the spring 163 is in sliding contact with the groove bottom of a T-shaped groove 16, when the blade 12 drives the blanking pipe 2 to rotate, the blanking pipe 2 drives the annular pipe 15 to synchronously rotate through the slide block 162 and a connecting rod 161 which are clamped with the clamping groove 164, and when carbonized materials in the blanking pipe 2 are excessive, the carbonized materials can extrude the connecting rod 161, so that the connecting rod 161 pushes the slide block 162 to extrude the spring 163, and the slide block 162 stretches out of the limit groove and enters the T-shaped groove 16 through the clamping groove 164; at this time, along with the rotation of the blanking pipe 2, the sliding block 162 can drive the spring 163 to slide at the bottom of the T-shaped groove 16, so that the limiting groove of the sliding block 162, which cannot push the surface of the annular pipe 15, drives the annular pipe 15 to rotate, and further, the annular pipe 15 is prevented from driving excessive carbonized materials in the annular pipe to mutually extrude to cause the carbonized materials to be broken, the generation of carbon powder is reduced, the generation of carbon ash is reduced, the carbon ash nodulation at the position of the vent hole 21 caused by the over-combustion of the carbon powder is avoided, the steam inlet amount of the vent hole 21 is further improved, the activation effect and activation efficiency of the carbonized materials in the product channel 116 are improved, and the practicability of the invention is effectively improved.

The invention discloses an activation process for producing active carbon, which is suitable for an activation device provided with a pushing module and comprises the following steps:

s1: the worker closes the discharge opening 11 and then adds the carbonized material from the feed tank so that the carbonized material fills the product channel 116 and the discharge pipe 2 at the cooling belt 114; the controller controls the opening of the heat storage chamber 115, so that the overheated water vapor in the heat storage chamber 115 enters the supplementary carbonization zone 112 and flows from the supplementary carbonization zone 112 to the activation zone 113, and the water vapor flows in a zigzag manner in the activation zone 113 as an activation medium;

s2: when the water vapor flows through the blanking pipe 2, the water vapor which is positively flushed towards the blanking pipe 2 can enter the blanking pipe 2 through the vent holes 21 of the blanking pipe 2, so that the water vapor which enters the blanking pipe 2 continuously flows into the blanking pipe 2, the water vapor activates carbonized materials in the blanking pipe 2, the water vapor blown to the blades 12 on the outer wall of the blanking pipe 2 pushes the blades 12 and drives the blanking pipe 2 to rotate, the rotation directions of two adjacent blanking pipes 2 are opposite, the two blanking pipes 2 in the middle are fixedly connected through rotation threads, and the uppermost blanking pipe 2 is lowered under the action of gravity after being rotationally lifted to the separation of the threads; so that the uppermost blanking pipe 2 and the two blanking pipes 2 which are in threaded connection in the middle are always in a shaking state;

S3: the water vapor blocked by the blade 12 can flow along the surface of the blade 12, which is close to the outer wall of the blanking pipe 2, towards the arc-shaped holes 13, so that the water vapor is sprayed from the arc-shaped holes 13 to the wind shield 33; the wind shield 33 drives the push rod 3 to overcome the torsion of the torsion spring under the blowing of the water vapor, so that the push rod 3 rotates along the hinge point between the push rod 3 and the torsion spring, the push rod 3 pushes the push plate 31 to swing along the inner wall of the blanking pipe 2, and the push plate 31 can push the carbonized material to swing in the blanking pipe 2;

s4: after the carbonized material is activated, opening the discharge opening 11 to take out the carbonized material of the cooling belt 114, at the moment, dropping the carbonized material in the activating belt 113 to the cooling belt 114, closing the discharge opening 11, at the moment, dropping the carbonized material of the supplementary carbonized belt 112 to the area of the activating belt 113, dropping the carbonized material of the preheating belt 111 to the area of the supplementary carbonized belt 112, adding the carbonized material from a feeding tank by a worker, thereby supplementing the carbonized material in the preheating belt 111, and after the carbonized material in the activating belt 113 is activated, at the moment, cooling the carbonized material after the activated in the cooling belt 114, and taking out the carbonized material in the cooling belt 114 by the worker to obtain the carbonized material;

s5: when the activated carbonized material is taken out, firstly removing dust in activated pores of the carbonized material by a negative pressure adsorption box, and then drying the carbonized material with the dust removed, thereby finally obtaining the required activated carbon.

The invention discloses an activation process for producing active carbon, which is suitable for an activation device provided with an annular pipe 15 and comprises the following steps:

s1: the worker closes the discharge opening 11 and then adds the carbonized material from the feed tank so that the carbonized material fills the product channel 116 and the discharge pipe 2 at the cooling belt 114; the controller controls the opening of the heat storage chamber 115, so that the overheated water vapor in the heat storage chamber 115 enters the supplementary carbonization zone 112 and flows from the supplementary carbonization zone 112 to the activation zone 113, and the water vapor flows in a zigzag manner in the activation zone 113 as an activation medium;

s2: when the water vapor flows through the blanking pipe 2, the water vapor which is positively flushed towards the blanking pipe 2 can enter the blanking pipe 2 through the vent holes 21 of the blanking pipe 2, so that the water vapor which enters the blanking pipe 2 continuously flows into the blanking pipe 2, the water vapor activates carbonized materials in the blanking pipe 2, the water vapor blown to the blades 12 on the outer wall of the blanking pipe 2 pushes the blades 12 and drives the blanking pipe 2 to rotate, the rotation directions of two adjacent blanking pipes 2 are opposite, the two blanking pipes 2 in the middle are fixedly connected through rotation threads, and the uppermost blanking pipe 2 is lowered under the action of gravity after being rotationally lifted to the separation of the threads; so that the uppermost blanking pipe 2 and the two blanking pipes 2 which are in threaded connection in the middle are always in a shaking state;

S3: in the process that the blade 12 drives the blanking pipe 2 to rotate, the blanking pipe 2 drives the annular pipe 15 to synchronously rotate through the sliding block 162 and the connecting rod 161 which are clamped with the clamping groove 164, when the carbonized materials in the blanking pipe 2 are excessive, the carbonized materials can extrude the connecting rod 161, so that the connecting rod 161 pushes the sliding block 162 to extrude the spring 163, the sliding block 162 extends out of the clamping groove 164, and the sliding block 162 is ensured to slide in the T-shaped groove 16;

s4: after the carbonized material is activated, opening the discharge opening 11 to take out the carbonized material of the cooling belt 114, at the moment, dropping the carbonized material in the activating belt 113 to the cooling belt 114, closing the discharge opening 11, at the moment, dropping the carbonized material of the supplementary carbonized belt 112 to the area of the activating belt 113, dropping the carbonized material of the preheating belt 111 to the area of the supplementary carbonized belt 112, adding the carbonized material from a feeding tank by a worker, thereby supplementing the carbonized material in the preheating belt 111, and after the carbonized material in the activating belt 113 is activated, at the moment, cooling the carbonized material after the activated in the cooling belt 114, and taking out the carbonized material in the cooling belt 114 by the worker to obtain the carbonized material;

s5: when the activated carbonized material is taken out, firstly removing dust in activated pores of the carbonized material by a negative pressure adsorption box, and then drying the carbonized material with the dust removed, thereby finally obtaining the required activated carbon.

Claims (6)

1. An activation device for producing active carbon comprises an activation furnace; the method is characterized in that: the activation furnace includes: a housing (1); the shell (1) is divided into a preheating zone (111), a supplementary carbonization zone (112), an activation zone (113) and a cooling zone (114) from top to bottom; a regenerator (115) is arranged on one side of the shell (1); the regenerator (115) is communicated with a complementary carbonization zone (112) inside the shell (1); the upper end of the shell (1) is provided with a feeding groove; the lower end of the shell (1) is provided with a discharge opening (11);

a product lane (116); the middle part of the product channel (116) is rotationally connected with a blanking pipe (2); the blanking pipe (2) is positioned in the area of an activation belt (113) of the shell (1); the outer wall of the blanking pipe (2) is provided with a vent hole (21); the product channel (116) is vertically arranged inside the shell (1); one end of the product channel (116) is communicated with the feeding groove, and the other end of the product channel is communicated with the discharge opening (11); a grid groove (22) is formed in the blanking pipe (2);

a rotating mechanism; the rotating mechanism is arranged on the outer wall of the blanking pipe (2); the rotating mechanism drives the blanking pipe (2) to rotate under the pushing of water vapor;

a controller; the controller is used for controlling the operation of the whole activation furnace;

the rotating mechanism comprises a blade plate (12); the blade plate (12) is fixed on the surface of the blanking pipe (2); the blade plate (12) is obliquely arranged; a baffle (4) is arranged in the shell (1);

The cross section of the blade plate (12) is arc-shaped; the concave surface of the arc-shaped blade plate (12) faces the blanking pipe (2);

an arc-shaped hole (13) is formed in the middle of the blade plate (12); the inner wall of the blanking pipe (2) is connected with a pushing module in a sliding manner; the pushing module comprises a push rod (3) and a push plate (31); the outer wall of the blanking pipe (2) is provided with a mounting groove (32) communicated to the inside; the push rod (3) is rotationally connected in the mounting groove (32) through a torsion spring; the pushing plate (31) is connected to the inner wall of the blanking pipe (2) in a sliding manner; one end of the push rod (3) is hinged with the push plate (31), and the other end of the push rod is fixedly connected with the wind shield (33); the wind shield (33) is opposite to the arc-shaped hole (13); arc plates (5) are arranged on two sides of the blanking pipe (2); two adjacent arc plates (5) are positioned between the shell (1) and the baffle (4), and one surface of each adjacent arc plate (5) which is far away from each other is fixedly connected with the shell (1) and the baffle (4) respectively;

an annular pipe (15) is arranged in the blanking pipe (2); the grid grooves (22) are formed in the inner wall of the annular tube (15); a T-shaped groove (16) is formed in the inner wall of the blanking pipe (2); a connecting rod (161) is connected in a sliding way in the T-shaped groove (16); one end of the connecting rod (161) stretches into the annular tube (15), and the other end of the connecting rod is fixedly connected with a sliding block (162); a spring (163) is fixedly connected to one surface of the sliding block (162) far away from the connecting rod (161); one end of the spring (163) far away from the sliding block (162) is in sliding contact with the bottom of the T-shaped groove (16); the inner wall of the T-shaped groove (16) is provided with a clamping groove (164).

2. An activating apparatus for activated carbon production as set forth in claim 1, wherein: a square groove (34) is formed in one surface, close to the arc-shaped hole (13), of the wind shield (33).

3. An activating apparatus for activated carbon production as set forth in claim 1, wherein: a semicircular groove (34) is formed in one surface, close to the arc-shaped hole (13), of the wind shield (33).

4. An activating apparatus for activated carbon production as claimed in claim 2 or 3, characterized in that: the number of the blanking pipes (2) is at least 4; the two adjacent blanking pipes (2) are connected through threads; the inclination directions of the blades (12) of two adjacent blanking pipes (2) are opposite; the screw thread rotation directions of the two adjacent screw thread joints are opposite; the outer wall of the blanking pipe (2) is connected with a sleeve (14) in a sliding manner; the sleeve (14) is positioned at the threaded connection position of two adjacent blanking pipes (2).

5. An activation process for activated carbon production, which is suitable for the activation apparatus as claimed in any one of claims 1 to 4, characterized in that: the process comprises the following steps:

s1: the worker closes the discharge opening (11) first, and then adds the carbonized material from the feeding tank, so that the carbonized material fills the product channel (116) and the blanking pipe (2) at the cooling belt (114); the controller controls the opening of the heat storage chamber (115) so that the overheated water vapor in the heat storage chamber (115) enters the supplementary carbonization zone (112) and flows to the activation zone (113) from the supplementary carbonization zone (112), and the water vapor flows in a zigzag shape in the activation zone (113) as an activation medium;

S2: when the water vapor flows through the blanking pipe (2), the water vapor which is positively flushed towards the blanking pipe (2) can enter the blanking pipe (2) through the vent holes (21) of the blanking pipe (2), so that the water vapor which enters the blanking pipe (2) continuously flows into the blanking pipe (2), the carbonized material in the blanking pipe (2) is activated by the water vapor, the water vapor blown to the blades (12) on the outer wall of the blanking pipe (2) pushes the blades (12) and drives the blanking pipe (2) to rotate, the rotation directions of the two adjacent blanking pipes (2) are opposite, the two blanking pipes (2) in the middle are fixedly connected through rotation threads, and the uppermost blanking pipe (2) is lowered under the action of gravity after the rotation of the uppermost blanking pipe (2) is lifted to the thread separation; the uppermost blanking pipe (2) and the two blanking pipes (2) which are in threaded connection with the middle part are always in a shaking state;

s3: the water vapor blocked by the blade plate (12) can flow along the surface of the blade plate (12) close to the outer wall of the blanking pipe (2) towards the direction of the arc-shaped holes (13), so that the water vapor is sprayed from the arc-shaped holes (13) to the wind shield (33); the wind shield (33) drives the push rod (3) to overcome the torsion of the torsion spring under the blowing of the water vapor, so that the push rod (3) rotates along the hinge point between the push rod and the torsion spring, the push rod (3) pushes the push plate (31) to swing along the inner wall of the blanking pipe (2), and the push plate (31) can push the carbonized material to swing in the blanking pipe (2);

S4: after the carbonization material is activated, the discharge opening (11) is opened, so that the carbonization material in the cooling belt (114) is taken out, at the moment, the carbonization material in the activation belt (113) is dropped into the cooling belt (114), the discharge opening (11) is closed, at the moment, the carbonization material in the supplementary carbonization belt (112) is dropped into the activation belt (113) area, the carbonization material in the preheating belt (111) is dropped into the supplementary carbonization belt (112) area, the worker adds the carbonization material into the carbonization material from the feeding tank, and therefore the carbonization material in the preheating belt (111) is supplemented, after the activation of the carbonization material in the activation belt (113) is completed, at the moment, the carbonization material after the activation in the cooling belt (114) is cooled, and the worker takes out the carbonization material in the cooling belt (114) to obtain the carbonization material;

s5: when the activated carbonized material is taken out, firstly removing dust in activated pores of the carbonized material by a negative pressure adsorption box, and then drying the carbonized material with the dust removed, thereby finally obtaining the required activated carbon.

6. An activation process for activated carbon production, which is suitable for the activation apparatus as claimed in any one of claim 1, characterized in that: the process comprises the following steps:

s1: the worker closes the discharge opening (11) first, and then adds the carbonized material from the feeding tank, so that the carbonized material fills the product channel (116) and the blanking pipe (2) at the cooling belt (114); the controller controls the opening of the heat storage chamber (115) so that the overheated water vapor in the heat storage chamber (115) enters the supplementary carbonization zone (112) and flows to the activation zone (113) from the supplementary carbonization zone (112), and the water vapor flows in a zigzag shape in the activation zone (113) as an activation medium;

S2: when the water vapor flows through the blanking pipe (2), the water vapor which is positively flushed towards the blanking pipe (2) can enter the blanking pipe (2) through the vent holes (21) of the blanking pipe (2), so that the water vapor which enters the blanking pipe (2) continuously flows into the blanking pipe (2), the carbonized material in the blanking pipe (2) is activated by the water vapor, the water vapor blown to the blades (12) on the outer wall of the blanking pipe (2) pushes the blades (12) and drives the blanking pipe (2) to rotate, the rotation directions of the two adjacent blanking pipes (2) are opposite, the two blanking pipes (2) in the middle are fixedly connected through rotation threads, and the uppermost blanking pipe (2) is lowered under the action of gravity after the rotation of the uppermost blanking pipe (2) is lifted to the thread separation; the uppermost blanking pipe (2) and the two blanking pipes (2) which are in threaded connection with the middle part are always in a shaking state;

s3: in the process that the blade plate (12) drives the blanking pipe (2) to rotate, the blanking pipe (2) drives the annular pipe (15) to synchronously rotate through the sliding block (162) and the connecting rod (161) which are clamped with the clamping groove (164), when the carbonized materials in the blanking pipe (2) are excessive, the carbonized materials can squeeze the connecting rod (161), so that the connecting rod (161) pushes the sliding block (162) to squeeze the spring (163), the sliding block (162) stretches out of the clamping groove (164), and the sliding block (162) is ensured to slide in the T-shaped groove (16);

S4: after the carbonization material is activated, the discharge opening (11) is opened, so that the carbonization material in the cooling belt (114) is taken out, at the moment, the carbonization material in the activation belt (113) is dropped into the cooling belt (114), the discharge opening (11) is closed, at the moment, the carbonization material in the supplementary carbonization belt (112) is dropped into the activation belt (113) area, the carbonization material in the preheating belt (111) is dropped into the supplementary carbonization belt (112) area, the worker adds the carbonization material into the carbonization material from the feeding tank, and therefore the carbonization material in the preheating belt (111) is supplemented, after the activation of the carbonization material in the activation belt (113) is completed, at the moment, the carbonization material after the activation in the cooling belt (114) is cooled, and the worker takes out the carbonization material in the cooling belt (114) to obtain the carbonization material;

s5: when the activated carbonized material is taken out, firstly removing dust in activated pores of the carbonized material by a negative pressure adsorption box, and then drying the carbonized material with the dust removed, thereby finally obtaining the required activated carbon.