CN213613063U - Pulse dust collector on full-automatic active carbon production line - Google Patents

Abstract

The utility model relates to an active carbon production technical field just discloses a pulse dust collector on full-automatic active carbon production line, including the transfer tank, the bottom in transfer tank is located the position fixedly connected with conveyor motor who leans on a left side, the top in transfer tank is located the position fixedly connected with who leans on a left side and carries the body, the exhaust hole has been seted up to the outer wall of carrying the body. This pulse dust remover on full-automatic active carbon production line, set up pulse gas transmission device, the intensity of air current reduces along with the rotation crescent of pulse accuse stream piece, thereby make the inside air current of conveying pipe body keep changing at any time, the intensity that makes inside air current maintains the flow of non-stability, thereby remove dust to the inside dust of active carbon, the effect of removing dust has been improved, thereby the adsorption efficiency of active carbon to the dust has been improved, set up filter equipment, filter the dust of the inside suction of active carbon through filter equipment and subside, prevent air pollution.

Description

Pulse dust collector on full-automatic active carbon production line

Technical Field

The utility model relates to an active carbon production technical field specifically is a pulse dust collector on full-automatic active carbon production line.

Background

The active carbon is usually powdery or granular porous amorphous carbon with strong adsorption capacity, and is obtained by carbonizing a solid carbonaceous material at 600-900 ℃ under the condition of air isolation, and then oxidizing and activating the carbonized material by using air, carbon dioxide, water vapor or a mixed gas of the air, the carbon dioxide and the water vapor at 400-900 ℃, wherein a certain amount of dust can be contained in the processed active carbon, and the ash content in the active carbon has great influence on the adsorption activity of the carbon, so that the adsorption effect of the active carbon is reduced.

SUMMERY OF THE UTILITY MODEL

Technical problem to be solved

Not enough to prior art, the utility model provides a pulse dust collector on full-automatic active carbon production line has solved the activated carbon processing and has accomplished the problem that the rear surface adheres to the adsorption effect that has the dust to influence the activated carbon.

(II) technical scheme

In order to achieve the above object, the present invention provides the following technical solutions: a pulse dust collector on a full-automatic active carbon production line comprises a transit tank, wherein the bottom of the transit tank is fixedly connected with a conveying motor at the position close to the left, the top of the transfer groove is fixedly connected with a conveying pipe body at the position close to the left, the outer wall of the conveying pipe body is provided with an exhaust hole, the top of the transit trough and the position at the inner side of the conveying pipe body are rotationally connected with a conveying rotating shaft through a bearing, the outer wall of the conveying rotating shaft is fixedly connected with a conveying blade, the outer wall of the conveying pipe body is fixedly connected with a connecting sleeve at the position above the exhaust hole, the front side of the connecting sleeve is provided with a pulse gas transmission device, the bottom of the connecting sleeve is fixedly connected with a sealed shell, the bottom of the sealed shell is fixedly connected with a dust absorption pipeline, the left side wall of the transit trough is fixedly connected with an adsorption water pool through a support, and a filtering device is arranged inside the adsorption water pool;

the pulse gas transmission device comprises a gas inlet pipeline, a partition plate, a pulse flow control block and a vent pipeline, wherein the partition plate is fixedly connected with the inner wall of the gas inlet pipeline and is positioned at a position close to the rear side wall, the pulse flow control block is rotatably connected with the front side wall of the partition plate and is positioned at the middle position through a bearing, the vent pipeline is fixedly connected with the outer wall of the gas inlet pipeline and is positioned at the left side of the partition plate, and one end, far away from the gas inlet pipeline, of the vent pipeline penetrates through a connecting sleeve and extends into the conveying pipe body.

Preferably, filter equipment includes the filter screen cover, connects pivot, plug flow blade and dust absorption motor, the filter screen cover passes through the bearing and is connected with dust absorption pipeline's outer wall and is located the position rotation of keeping away from seal housing, the inner wall that leans on the upper end through bearing and support and dust absorption pipeline of connecting the pivot rotates and is connected, plug flow blade and the outer wall fixed connection who is connected the pivot, plug flow blade leans on the inner wall fixed connection of lateral wall and filter screen cover, the inner wall fixed connection in dust absorption motor and absorption pond, the output of dust absorption motor with be connected pivot fixed connection.

Preferably, the output end of the conveying motor penetrates through the transit groove and is fixedly connected with the bottom of the conveying rotating shaft, and the conveying rotating shaft is driven by the conveying motor to rotate to convey the activated carbon.

Preferably, the exhaust hole and the contained angle of horizontal plane are 30, and the condition of air current refluence prevents to appear in the exhaust hole that the downward sloping was seted up when exhausting, guarantees to carry the inside air current of body to the stability of outside flow.

Preferably, one side surface of the pulse flow control block close to the partition plate is semicircular, one side surface of the pulse flow control block far away from the partition plate is spiral, and the strength of the airflow entering the ventilation pipeline is controlled by the rotation of the pulse flow control block, so that the strength of the airflow is changed in a pulse mode.

Preferably, the partition plate is vertically arranged, one end of the ventilation pipeline, which is connected with the air inlet pipeline, is perpendicular to the side face of the partition plate, and the air inlet pipeline is divided into two parts through the partition plate, so that the air flow strength at two sides is enhanced and weakened once.

Preferably, the flow pushing blade is spiral, and rotates to press the air in the filter screen sleeve downwards so that the air is discharged outwards and the dust gas in the dust suction pipeline is sucked into the filter screen sleeve.

Preferably, the water surface in the adsorption water tank is higher than the highest position of the bottom surface of the filter screen cylinder, air is filtered through the filter screen cylinder, and the filter screen cylinder is cleaned through water.

Preferably, the upper surface of the conveying blade, which is located on the inner side of the sealing shell, is provided with a through hole, and the through hole enables airflow to vertically flow downwards in the conveying pipe body.

Compared with the prior art, the utility model provides a pulse dust collector on full-automatic active carbon production line possesses following beneficial effect:

1. the pulse dust collector on the full-automatic active carbon production line is provided with an air inlet pipeline, a partition plate, a pulse flow control block and an air vent pipeline, wherein the air inlet pipeline is fixedly connected with the front end of the air inlet pipeline, air is supplemented to the air inlet pipeline through the air supplementing pipeline, air flows enter the inside of the air inlet pipeline and contact with the pulse flow control block, the pulse flow control block is pushed by high-speed air flow to rotate, the air flows entering the rear end of the air inlet pipeline and positioned on the left side of the partition plate are reduced when the pulse flow control block rotates to the position close to the right side of the partition plate, the blocking on the left side of the partition plate is removed when the pulse flow control block rotates, the air flows enter the inside of the air vent pipeline and then enter the inside of a conveying pipe body to carry out air flow blowing dust removal on active carbon, the strength of the air flows is gradually increased and then reduced along with the rotation of, the intensity of the internal airflow maintains the unstable flow, so that the dust in the activated carbon is removed, and the dust removal effect is improved.

2. This pulse dust collector on full-automatic active carbon production line, set up the filter screen cover, connect the pivot, plug blade and dust absorption motor, the dust absorption motor drives and connects the pivot and rotate, it drives plug blade and rotates to connect the pivot, plug blade rotates and extrudes the inside air of filter screen cover downwards and makes the air outwards arrange and inhale the inside dust gas of dust absorption pipeline to the inside of filter screen cover, plug blade drives the filter screen cover simultaneously and rotates, it will be close to upside and air contact position and wash with the water contact to filter screen cover rotation, prevent to take place to block up, and make the filter screen section of thick bamboo remain moist state all the time, thereby the absorbent effect to the dust has been improved, thereby the filterable effect of dust has been improved, prevent air pollution.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of the cross-sectional structure of the inside of the conveying pipe body of the present invention;

FIG. 3 is a schematic view of the sectional structure of the pulse gas transmission device of the present invention;

fig. 4 is a schematic view of the internal sectional structure of the filtering device of the present invention.

Wherein: 1. a transit trough; 2. a conveying motor; 3. conveying the pipe body; 31. an exhaust hole; 4. a conveying rotating shaft; 5. a conveying blade; 6. connecting sleeves; 7. a pulse gas transmission device; 71. an air intake duct; 72. a partition plate; 73. a pulse flow control block; 74. an air duct; 8. sealing the housing; 9. a dust collection duct; 10. a filtration device; 101. a filter screen sleeve; 102. connecting the rotating shaft; 103. a plug flow blade; 104. a dust collection motor; 11. and (4) an adsorption water tank.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-4, the utility model provides a pulse dust collector on a full-automatic active carbon production line, which comprises a transit trough 1, a conveying motor 2 is fixedly connected to the bottom of the transit trough 1 and is positioned at the left position, a conveying pipe body 3 is fixedly connected to the top of the transit trough 1 and is positioned at the left position, an exhaust hole 31 is arranged on the outer wall of the conveying pipe body 3, the included angle between the exhaust hole 31 and the horizontal plane is 30 degrees, the exhaust hole arranged in downward inclination prevents the air flow from flowing backwards when exhausting, the stability of the air flow inside the conveying pipe body 3 flowing outwards is ensured, a conveying rotating shaft 4 is rotatably connected to the top of the transit trough 1 and is positioned at the inner side of the conveying pipe body 3 through a bearing, the output end of the conveying motor 2 penetrates through the transit trough 1 and is fixedly connected with the bottom of the conveying rotating shaft 4, the conveying rotating shaft 4 is driven by the conveying, the outer wall of the conveying rotating shaft 4 is fixedly connected with a conveying blade 5, the upper surface of the conveying blade 5, which is positioned on the inner side of the sealed shell 8, is provided with a through hole, so that air flow can vertically flow downwards in the conveying pipe body 3, the outer wall of the conveying pipe body 3 and the position, which is positioned on the upper side of the exhaust hole 31, of the conveying pipe body are fixedly connected with a connecting sleeve 6, the front side of the connecting sleeve 6 is provided with a pulse air conveying device 7, the bottom of the connecting sleeve 6 is fixedly connected with the sealed shell 8, the bottom of the sealed shell 8 is fixedly connected with a dust suction pipeline 9, the left side wall of the transfer tank 1 is fixedly connected with an adsorption water tank 11 through a support, the interior of the adsorption water tank 11 is provided with a filtering device 10, the water surface in the adsorption water tank 11 does not pass through the;

the pulse gas transmission device 7 comprises an air inlet pipeline 71, a partition plate 72, a pulse flow control block 73 and an air duct 74, wherein the partition plate 72 is fixedly connected with the inner wall of the air inlet pipeline 71 and is positioned at a position close to the rear side wall, the partition plate 72 is vertically arranged, one end of the air duct 74 connected with the air inlet pipeline 71 is vertical to the side surface of the partition plate 72, the air inlet pipeline 71 is divided into two parts by the partition plate 72, so that the air flow intensity at two sides is enhanced and weakened for one time, the pulse flow control block 73 is rotatably connected with the front side wall of the partition plate 72 and is positioned at the middle position through a bearing, the air duct 74 is fixedly connected with the outer wall of the air inlet pipeline 71 and is positioned at the left side of the partition plate 72, one side surface of the pulse flow control block 73 close to the partition plate 72 is semicircular, one side surface of the pulse flow control block 73 far away from the, the strength of the airflow is changed in a pulse mode, one end, far away from the air inlet pipeline 71, of the vent pipeline 74 penetrates through the connecting sleeve 6 and extends into the conveying pipe body 3, the air inlet pipeline 71, the partition plate 72, the pulse flow control block 73 and the vent pipeline 74 are arranged, the air supply pipeline is fixedly connected with the front end of the air inlet pipeline 71, air supply operation is carried out on the air inlet pipeline 71 through the air supply pipeline, the airflow enters the inside of the air inlet pipeline 71 and contacts with the pulse flow control block 73, the pulse flow control block 73 is pushed to rotate by high-speed airflow, the airflow entering from the rear end of the air inlet pipeline 71 and located on the left side of the partition plate 72 is reduced when the pulse flow control block 73 rotates to the right side position of the partition plate 72, blocking on the left side of the partition plate 72 is removed, the airflow enters the inside of the vent pipeline 74 and then enters the inside of the conveying pipe body 3 to carry out airflow, the intensity of the air current is gradually increased and reduced along with the rotation of the pulse flow control block 73, so that the air current in the conveying pipe body 3 is kept changing at any time, the intensity of the air current in the conveying pipe body is kept flowing unstably, dust in the activated carbon is removed, and the dust removal effect is improved.

The filtering device 10 comprises a filter screen sleeve 101, a connecting rotating shaft 102, a flow pushing blade 103 and a dust collection motor 104, wherein the filter screen sleeve 101 is rotatably connected with the outer wall of the dust collection pipeline 9 at a position far away from the sealing shell 8 through a bearing, the upper end of the connecting rotating shaft 102 is rotatably connected with the inner wall of the dust collection pipeline 9 through a bearing and a bracket, the flow pushing blade 103 is fixedly connected with the outer wall of the connecting rotating shaft 102, the flow pushing blade 103 is spiral, air in the filter screen sleeve 101 is downwards extruded through the rotation of the flow pushing blade 103 to enable the air to be outwards discharged and dust gas in the dust collection pipeline 9 to be sucked into the filter screen sleeve 101, the flow pushing blade 103 is fixedly connected with the inner wall of the filter screen sleeve 101 through the outer side wall, the dust collection motor 104 is fixedly connected with the inner wall of the absorption water tank 11, the output end of the dust collection motor 104 is fixedly connected with the connecting rotating shaft 102, Push away class blade 103 and dust absorption motor 104, dust absorption motor 104 drives and connects pivot 102 and rotate, it drives and pushes away class blade 103 and rotates to connect pivot 102, it drives and pushes away the inside air of filter screen cover 101 to make the air outwards move and inhale the inside dust gas of dust absorption pipeline 9 to the inside of filter screen cover 101 downwards to push away class blade 103, it rotates to push away class blade 103 simultaneously and drives filter screen cover 101, filter screen cover 101 rotates and will be close to the upside and rinse with the water contact with the air contact position, prevent to block up, and make filter screen cover 101 remain moist state all the time, thereby the effect to dust absorption has been improved, thereby the filterable effect has been improved, prevent air pollution.

When the device is used, activated carbon is placed in the transfer groove 1, the conveying motor 2 is started, the conveying motor 2 drives the conveying rotating shaft 4 to rotate, the conveying rotating shaft 4 drives the conveying blades 5 to rotate, the conveying blades 5 drive the activated carbon in the transfer groove 1 to move upwards along the conveying pipe body 3, meanwhile, air supplement operation is carried out on the air inlet pipeline 71 through the air supplement pipeline, air flow enters the interior of the air inlet pipeline 71 and contacts with the pulse flow control block 73, high-speed air flow pushes the pulse flow control block 73 to rotate, when the pulse flow control block 73 rotates, air flow entering the rear end of the air inlet pipeline 71 and located on the left side of the partition plate 72 is reduced, when the pulse flow control block 73 rotates to the position close to the right side of the partition plate 72, the blocking of the partition plate 72 is removed, the air flow enters the interior of the air vent pipeline 74 and then enters the interior of the conveying pipe body 3 to carry out air flow blowing dust removal on, the intensity of the air flow is gradually increased and then decreased along with the rotation of the pulse flow control block 73, so that the air flow inside the conveying pipe body 3 keeps changing at any time, the intensity of the air flow inside the conveying pipe body 3 keeps flowing unstably, dust inside the activated carbon is removed, the air flow enters the inside of the conveying pipe body 3 and then flows downwards, the air flow drives the dust on the surface of the activated carbon to enter the inside of the sealing shell 8 along the exhaust holes 31 and move downwards, the air flow with the dust enters the inside of the filtering device 10 through the dust suction pipeline 9, the dust suction motor 104 drives the connecting rotating shaft 102 to rotate, the connecting rotating shaft 102 drives the flow pushing blade 103 to rotate, the flow pushing blade 103 rotates to push the air inside the filter screen sleeve 101 downwards, so that the air is discharged outwards and the dust gas inside the dust suction pipeline 9 is sucked into the inside the filter screen sleeve 101, and simultaneously the flow pushing blade 103 drives the filter screen sleeve 101 to rotate, the filter screen sleeve 101 rotates to be close to the upside and is cleaned by contacting with water at the air contact position, so that blockage is prevented, the filter screen cylinder 101 is always kept in a wet state, the effect of dust adsorption is improved, the filter screen cylinder is connected with the top end of the conveying pipe body 3 through a pipeline, and the activated carbon inside the conveying pipe body 3 after dust removal is conveyed to the next processing stage through the pipeline.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (9)

1. The utility model provides a pulse dust collector on full-automatic active carbon production line, includes transfer tank (1), its characterized in that: the bottom of the transfer tank (1) is fixedly connected with a conveying motor (2) at a position close to the left, the top of the transfer tank (1) is fixedly connected with a conveying pipe body (3) at a position close to the left, an exhaust hole (31) is formed in the outer wall of the conveying pipe body (3), the top of the transfer tank (1) is rotatably connected with a conveying rotating shaft (4) at a position close to the inner side of the conveying pipe body (3) through a bearing, the outer wall of the conveying rotating shaft (4) is fixedly connected with a conveying blade (5), the outer wall of the conveying pipe body (3) is fixedly connected with a connecting sleeve (6) at a position above the exhaust hole (31), a pulse gas transmission device (7) is arranged at the front side of the connecting sleeve (6), a sealing shell (8) is fixedly connected with the bottom of the connecting sleeve (6), and a dust absorption pipeline (9) is fixedly connected with the, the left side wall of the transit trough (1) is fixedly connected with an adsorption water tank (11) through a support, and a filtering device (10) is arranged inside the adsorption water tank (11);

the pulse gas transmission device (7) comprises a gas inlet pipeline (71), a partition plate (72), a pulse flow control block (73) and a ventilation pipeline (74), wherein the partition plate (72) is fixedly connected with the inner wall of the gas inlet pipeline (71) and is located close to the rear side wall, the pulse flow control block (73) is rotatably connected with the front side wall of the partition plate (72) and is located in the middle position through a bearing, the ventilation pipeline (74) is fixedly connected with the outer wall of the gas inlet pipeline (71) and is located on the left side of the partition plate (72), and one end, far away from the gas inlet pipeline (71), of the ventilation pipeline (74) penetrates through a connecting sleeve (6) and extends into the conveying pipe body (3).

2. The pulse dust collector on the full-automatic activated carbon production line according to claim 1, characterized in that: filter equipment (10) are including filter screen cover (101), connection pivot (102), plug blade (103) and dust absorption motor (104), filter screen cover (101) pass through the outer wall of bearing and dust absorption pipeline (9) and are located the position rotation of keeping away from seal housing (8) and be connected, the inner wall that leans on the upper end through bearing and support and dust absorption pipeline (9) of connecting pivot (102) rotates and is connected, plug blade (103) and the outer wall fixed connection who is connected pivot (102), plug blade (103) lean on the inner wall fixed connection of lateral wall and filter screen cover (101), the inner wall fixed connection of dust absorption motor (104) and adsorption water basin (11), the output of dust absorption motor (104) with be connected pivot (102) fixed connection.

3. The pulse dust collector on the full-automatic activated carbon production line according to claim 1, characterized in that: the output end of the conveying motor (2) penetrates through the transit trough (1) and is fixedly connected with the bottom of the conveying rotating shaft (4).

4. The pulse dust collector on the full-automatic activated carbon production line according to claim 1, characterized in that: the included angle between the exhaust hole (31) and the horizontal plane is 30 degrees.

5. The pulse dust collector on the full-automatic activated carbon production line according to claim 1, characterized in that: one side surface of the pulse flow control block (73) close to the partition plate (72) is semicircular, and one side surface of the pulse flow control block (73) far away from the partition plate (72) is spiral.

6. The pulse dust collector on the full-automatic activated carbon production line according to claim 1, characterized in that: the partition plate (72) is vertically arranged, and one end of the ventilation pipeline (74) connected with the air inlet pipeline (71) is perpendicular to the side surface of the partition plate (72).

7. The pulse dust collector on the full-automatic activated carbon production line according to claim 2, characterized in that: the plug flow blade (103) is helical.

8. The pulse dust collector on the full-automatic activated carbon production line according to claim 2, characterized in that: the water surface height in the adsorption water tank (11) is higher than the highest position of the bottom surface of the filter screen sleeve (101).

9. The pulse dust collector on the full-automatic activated carbon production line according to claim 1, characterized in that: the upper surface of the conveying blade (5) positioned on the inner side of the sealing shell (8) is provided with a through hole.

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