CN115646113A

CN115646113A - A dust collecting equipment for carbon neutralization

Info

Publication number: CN115646113A
Application number: CN202211428683.1A
Authority: CN
Inventors: 请求不公布姓名
Original assignee: China Construction Fifth Engineering Bureau Co Ltd
Current assignee: China Construction Fifth Engineering Bureau Co Ltd
Priority date: 2021-12-24
Filing date: 2021-12-24
Publication date: 2023-01-31
Also published as: CN114225609A; CN114225609B; CN115569476A

Abstract

The invention discloses dust removal equipment for carbon neutralization, and particularly relates to the field of cyclic dust removal. According to the invention, when the fan blades are impacted by airflow, the spherical sliding block is driven to slide in the circular backflow cover, so that the flow direction of the gas entering the inner cavity of the circular backflow cover is changed into vortex-shaped airflow, thereby continuously colliding and bonding dust in the gas and accelerating the falling of the dust in the gas.

Description

A dust collecting equipment for carbon neutralization

Technical Field

The invention relates to the technical field of circulating dust removal, in particular to dust removal equipment for carbon neutralization.

Background

Carbon neutralization is an energy-saving and emission-reducing term, and means that enterprises, groups or individuals measure and calculate the total amount of greenhouse gas emission generated directly or indirectly within a certain time, and the emission of carbon dioxide generated by the enterprises or groups is counteracted through the forms of tree planting, energy saving and emission reduction and the like, so that zero emission of the carbon dioxide is realized.

The traditional dust removal method at present can generate the flying phenomenon of dust under the influence of induced airflow, and if proper protection measures are not taken, the dust can be directly sucked into the lungs of operators and seriously harms the health of workers, so the invention relates to dust removal equipment for carbon neutralization to solve the problems.

Disclosure of Invention

In order to overcome the above-mentioned drawbacks of the prior art, embodiments of the present invention provide a dust removing apparatus for carbon neutralization, in which when a fan blade is impacted by an airflow, a spherical sliding block is driven to slide in a circular backflow cover, so that the flow direction of the gas entering an inner cavity of the circular backflow cover is changed into a vortex-shaped airflow, thereby continuously colliding and bonding dust in the gas, so as to solve the problems in the background art.

In order to achieve the purpose, the invention provides the following technical scheme: a dust removal device for carbon neutralization comprises a first flow guide mechanism, wherein a mixing mechanism for mixing dust particles is arranged on one side of the first flow guide mechanism in a communicating mode, a second flow guide mechanism for reducing the flow velocity of the dust particles is arranged on the bottom of the mixing mechanism in a communicating mode, a spraying mechanism for cleaning the inner cavity of the mixing mechanism is arranged inside the mixing mechanism, the first flow guide mechanism comprises a first flow guide cover, a second flow guide cover is fixedly arranged on one side of the first flow guide cover, a hanging frame is fixedly arranged on the outer wall of the second flow guide cover, the first flow guide cover and the second flow guide cover are arranged in a mutually communicated mode, a dust blocking curtain used for being connected with the first flow guide cover is arranged at the air inlet of the first flow guide cover, a plurality of blocking rods are sequentially arranged on the inner wall of the first flow guide cover at equal intervals, and the outer walls of the blocking rods are connected with a rotary drum in a rotating mode, the mixing mechanism comprises a circular backflow cover, the circular backflow cover is communicated with one side of a first flow guide cover far away from a second flow guide cover, an exhaust pipe is communicated with the vertical center line of the circular backflow cover, an annular supporting plate connected with the exhaust pipe is fixedly installed on the inner wall of the circular backflow cover, sliding grooves are formed in the inner walls of the two sides of the circular backflow cover, a spherical sliding block is slidably installed in an inner cavity of each sliding groove, a connecting rod is fixedly installed on the outer wall of each spherical sliding block, fan blades used for guiding the spherical sliding blocks to move are arranged on the outer wall of each connecting rod, brushes used for cleaning floating dust on the annular supporting plate are arranged on the outer wall of each connecting rod, the brushes and the fan blades are arranged in a one-to-one correspondence manner, connecting sleeves used for being connected with the connecting rods are fixedly installed on one sides of the brushes and the fan blades, and the second flow guide mechanism comprises a third flow guide cover, the third kuppe intercommunication sets up in the bottom of blast pipe, just the inner chamber equidistance of third kuppe is equipped with a plurality of damping plates, set up a plurality of round holes that are used for reducing the air current velocity of flow on the damping plate, the outer wall fixed mounting of third kuppe has the support bracket.

In a preferred embodiment, the number of the blocking rods is at least two, and the two blocking rods are symmetrically arranged about a horizontal center line of the first air guide sleeve.

In a preferred embodiment, the first air guide sleeve is in an arc curve shape, a bent concave part is arranged vertically towards the center of the first air guide sleeve, a connecting plate is fixedly installed in the inner cavity of the bent concave part of the first air guide sleeve, a plurality of connecting chains are hinged to the inner wall of the connecting plate, and an elastic sleeve is fixedly connected to one side of each connecting chain.

In a preferred embodiment, a slot is formed in an outer wall of the third air guide sleeve, a bearing plate is fixedly mounted on an inner wall of the third air guide sleeve, the damping plate is inserted into an inner cavity of the slot, and the damping plate is arranged at the top of the bearing plate.

In a preferred embodiment, the quantity of spherical slider sets up to a plurality ofly, and is a plurality of spherical slider is the annular equidistance setting in proper order around the inner circumference line of spout, and is a plurality of the equal fixed mounting in inner chamber of spherical slider has the bull stick, just the bull stick rotates the inner chamber of connecting at the spout.

In a preferred embodiment, a dust monitor for monitoring the dust content in the inner cavity of the circular backflow cover is fixedly mounted on the inner wall of the circular backflow cover, and a controller for connecting with the dust monitor is fixedly mounted on the outer wall of the circular backflow cover.

In a preferred embodiment, the spraying mechanism comprises a first water pipe, the first water pipe is attached to the outer wall of the circular backflow cover and wound on the outer wall of the exhaust pipe, a water pump is fixedly mounted at one end of the first water pipe, an electronic switch valve is fixedly mounted on the water pump, a second water pipe is arranged on one side of the water pump in a communicated mode, a third water pipe communicated with the first water pipe is fixedly mounted inside the annular supporting plate, and a spraying head is arranged on the top of the third water pipe in a communicated mode.

In a preferred embodiment, the water pump is electrically connected with the electronic switch valve, and the controller is electrically connected with the electronic switch valve and the water pump.

In a preferred embodiment, a dust settling method for a carbon-neutralized dust removing apparatus comprises the steps of:

s1: the second air guide sleeve is communicated and installed at an indoor air outlet, air enters the inner cavity of the first air guide sleeve from the second air guide sleeve, and blows the stop lever to rotate, so that the air entering the inner cavity of the first air guide sleeve from linear motion is dispersed all around, and the air is guided to uniformly enter the inner cavity of the first air guide sleeve at the inlet of the first air guide sleeve;

s2: in the step S1, the gas entering the inner cavity of the first flow guide cover enters the inner cavity of the circular backflow cover along the shape trend of the first flow guide cover, and blows the fan blades to drive the spherical sliding block to slide in the inner cavity of the sliding chute through the flow direction of the gas, so that the fan blades rotate in the inner cavity of the circular backflow cover ceaselessly, and the flow direction of the gas entering the inner cavity of the circular backflow cover is changed into a vortex-shaped gas flow;

s3: the vortex-shaped airflow formed by the inner cavity of the circular backflow hood collides with the gas which moves from the inner cavity of the first flow guide hood successively, so that dust in the gas is continuously collided and bonded, small-particle dust in the gas is collided and bonded with each other to form larger particles, and the larger particles fall under the action of gravity;

s4: in the step S2, when the content of dust in the gas entering the inner cavity of the circular backflow cover is large, the dust is detected and fed back through the dust monitor, so that the controller receives feedback information of the dust monitor and transmits the information to the electronic switch valve, the water pump operates to convey cleaning water to the third water pipe to be sprayed out from the spraying head, and the water sprayed out from the spraying head humidifies the gas in the inner cavity of the circular backflow cover, so that the weight of the dust is increased, and the dust falls under the influence of gravity;

s5: the dust granule and the gas of whereabouts circulate to the third kuppe inner chamber from blast pipe department, and when gas was located via the damping plate, the round hole that receives the damping plate inner chamber and seted up influenced, made gaseous flow velocity reduce, increased the collision number of times of dust in the dusty air current simultaneously for the dust descends, and makes the dust granule adsorb and fall on the damping plate.

The invention has the technical effects and advantages that:

1. the rotatable fan blades are arranged in the inner cavity of the circular backflow cover, so that the fan blades drive the spherical sliding block to slide in the circular backflow cover when being impacted by airflow, the flow direction of the gas entering the inner cavity of the circular backflow cover is changed into vortex-shaped airflow, the gas circularly stays in the inner cavity of the circular backflow cover and is mixed and collided with the gas subsequently entering the inner cavity of the circular backflow cover, and therefore dust in the gas is continuously collided and bonded, small particle dust in the gas is mutually collided and bonded into larger particles, and the larger particles fall under the action of gravity;

2. according to the invention, the rotating rod is arranged in the inner cavity of the circular backflow cover to monitor the dust content in real time, and when the dust content is larger, the water pump is triggered to operate, so that the cleaning water source sprays water mist from the spray head, the humidity of the inner cavity of the circular backflow cover is enhanced, the dust is wetted, the weight of the dust is accelerated, and the dust falls off quickly.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention.

Fig. 2 is a sectional view of the overall structure of the present invention.

FIG. 3 is an enlarged view of the portion A of FIG. 2 according to the present invention.

FIG. 4 is an enlarged view of the portion B of FIG. 2 according to the present invention.

Fig. 5 is a structural sectional view of a mixing mechanism and a second deflector mechanism of the present invention.

FIG. 6 is an enlarged view of the structure of the portion C of FIG. 5 according to the present invention.

FIG. 7 is an enlarged view of the structure of the portion D in FIG. 5 according to the present invention.

The reference signs are: the device comprises a first flow guide mechanism 1, a first flow guide cover 101, a second flow guide cover 102, a dust blocking curtain 103, a blocking rod 104, a rotary drum 105, a hanging rack 106, a connecting plate 107, a connecting chain 108, an elastic sleeve 109, a mixing mechanism 2, a circular backflow cover 21, an exhaust pipe 22, an annular supporting plate 23, a sliding chute 24, a spherical sliding block 25, a connecting rod 26, a brush 27, a fan blade 28, a connecting sleeve 29, a rotating rod 210, a dust monitor 211, a dust monitor 212, a second flow guide mechanism 3, a third flow guide cover 31, a damping plate 32, a supporting bracket 33, a circular hole 34, a slot 35, a supporting plate 36, a spraying mechanism 4, a first water pipe 41, a water pump 42, an electronic switch valve 43, a second water pipe 44, a third water pipe 45 and a spraying head 46.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-7 of the specification, a dust removing apparatus for carbon neutralization according to an embodiment of the present invention, as shown in fig. 1, includes a first guiding mechanism 1, a mixing mechanism 2 for mixing and processing dust particles is provided in communication with one side of the first guiding mechanism 1, a second guiding mechanism 3 for reducing a flow velocity of the dust particles is provided in communication with a bottom of the mixing mechanism 2, a spraying mechanism 4 for cleaning an inner cavity of the mixing mechanism 2 is provided in the mixing mechanism 2, as shown in fig. 2-3, the first guiding mechanism 1 includes a first guiding cover 101, a second guiding cover 102 is mounted in a suspended manner by a hanger 106, a second guiding cover 102 is fixedly mounted on one side of the first guiding cover 101, a hanger 106 is fixedly mounted on an outer wall of the second guiding cover 102, the first guiding cover 101 and the second guiding cover 102 are arranged in a mutually communicated state, a dust blocking curtain 103 for connecting with the first guiding cover 101 is provided at an air inlet of the first guiding cover 101, and the dust blocking curtain 103 is closed relative to the first guiding cover 101 so as to prevent a dust flying curtain in the inner cavity of the first guiding cover 101 from being disturbed by air.

In order to make the gas more even that gets into at the entrance of first kuppe 101, equidistance is provided with a plurality of pin 104 in proper order on the inner wall of first kuppe 101, and the outer wall of a plurality of pin 104 all rotates and is connected with rotary drum 105, makes gas blow when rotary drum 105 carries out the rotation, can collide with the gas of blowing in, thereby makes the gas flow direction disperse all around, thereby passes in the gap between from a plurality of rotary drums 105 and between first kuppe 101 inner wall and the rotary drum 105.

Referring to fig. 2 and 5, the mixing mechanism 2 includes a circular backflow cover 21, the circular backflow cover 21 is disposed on one side of the first dome 101 away from the second dome 102 in a communicating manner, an exhaust pipe 22 is disposed on a vertical centerline of the circular backflow cover 21 in a communicating manner, gas enters an inner cavity of the circular backflow cover 21 from the first dome 101 and is exhausted from the exhaust pipe 22, as shown in fig. 6, an annular supporting plate 23 for connecting with the exhaust pipe 22 is fixedly mounted on an inner wall of the circular backflow cover 21, sliding grooves 24 are disposed on inner walls of two sides of the circular backflow cover 21, a spherical sliding block 25 is slidably mounted in the inner cavity of the sliding groove 24, an engaging rod 26 is fixedly mounted on an outer wall of the spherical sliding block 25, a fan blade 28 for guiding the spherical sliding block 25 to move is disposed on an outer wall of the engaging rod 26, and a brush 27 for cleaning floating dust on the annular supporting plate 23 is disposed on the outer wall of the engaging rod 26.

The brushes 27 and the fan blades 28 are arranged in a one-to-one correspondence manner, one side of each brush 27 and one side of each fan blade 28 are fixedly provided with a connecting sleeve 29 used for being connected with a connecting rod 26, meanwhile, in order to enhance the smoothness of the rotation of the fan blades 28 in the inner cavity of the circular backflow hood 21, the number of the spherical sliding blocks 25 is set to be multiple, the spherical sliding blocks 25 are sequentially arranged in an annular manner at equal intervals around the inner circumferential line of the sliding chute 24, the inner cavities of the spherical sliding blocks 25 are fixedly provided with rotating rods 210, the rotating rods 210 are YR-FD100 series dust concentration monitoring alarm equipment, the rotating rods 210 are rotatably connected to the inner cavity of the sliding chute 24, when the circular backflow hood 21 is used, gas entering the inner cavity of the circular backflow hood 101 enters the inner cavity of the circular backflow hood 21 along the shape of the first backflow hood 101, the fan blades 28 are blown to drive the spherical sliding blocks 25 to slide in the inner cavity of the sliding chute 24 through the flowing direction of the gas, the inner cavity of the circular backflow hood 21 continuously rotates, the gas flowing direction of the gas, the gas entering the inner cavity of the circular backflow hood 21 flows into vortex-shaped airflow, and the vortex airflow continuously collides with the gas moving from the inner cavity of the first backflow hood 101, and the exhaust pipe, so that small dust particles in the dust fall into the exhaust pipe, and collide with the dust, and then fall into the exhaust pipe, and the dust particles, and the dust particles.

Meanwhile, the second guiding mechanism 3 includes a third guiding cover 31, the third guiding cover 31 is communicated with and arranged at the bottom of the exhaust pipe 22, an inner cavity of the third guiding cover 31 is equidistantly provided with a plurality of damping plates 32, a plurality of round holes 34 used for reducing the flow velocity of the air current are formed in the damping plates 32, a support bracket 33 is fixedly mounted on the outer wall of the third guiding cover 31, when the dust collecting device is used, the falling gas and dust particles from the exhaust pipe 22 are blocked by the damping plates 32 and the round holes 34, the flow velocity of the gas is reduced, and the dust particles blocked on the damping plates 32 collide with the third guiding cover 31, the damping plates 32 and the dust in the gas again, so that the falling of the dust is accelerated and fall on the damping plates 32.

Further, as shown in fig. 3, at least two blocking rods 104 are provided, and the two blocking rods 104 are symmetrically disposed about a horizontal center line of the first nacelle 101, so that the blocking rods 104 and the drum 105 are combined with each other at an inlet of the first nacelle 101 to divide the inlet into a plurality of small openings at equal intervals, thereby enhancing uniformity of gas flow.

Meanwhile, as shown in fig. 4, when the gas forms a vortex-shaped airflow in the inner cavity of the circular backflow hood 21 for circulation repeatedly, in order to prevent the gas from flowing reversely through the first airflow guiding hood 101, the first airflow guiding hood 101 is arranged in an arc-shaped curve shape, a curved concave portion is arranged vertically towards the center of the first airflow guiding hood 101, a connecting plate 107 is fixedly installed in the curved concave portion inner cavity of the first airflow guiding hood 101, a plurality of connecting chains 108 are hinged to the inner wall of the connecting plate 107, elastic sleeves 109 are fixedly connected to one sides of the connecting chains 108, the elastic sleeves 109 are arranged in a conical shape, a plurality of rectangular empty slots are formed in the elastic sleeves 109, and when the gas enters the inner cavity of the first airflow guiding hood 101 from the second airflow guiding hood 102, the elastic sleeves 109 are deformed and expanded outwards by the impact of the airflow, so that the rectangular empty slots are enlarged, the gas is discharged from the rectangular empty slots, and the gas which is impacted reversely cannot impact the elastic sleeves 109, thereby preventing the circulation of the reverse airflow.

In order to clean dust on the damping plate 32 conveniently and improve the reutilization of the damping plate 32, a slot 35 is formed in the outer wall of the third air guide sleeve 31, a bearing plate 36 is fixedly mounted on the inner wall of the third air guide sleeve 31, the damping plate 32 is inserted into the inner cavity of the slot 35, and the damping plate 32 is arranged at the top of the bearing plate 36, so that the damping plate 32 can be conveniently and quickly disassembled and assembled in an inserting mode.

As shown in fig. 5-6, when the dust content in the gas is too large, the vortex-shaped airflow in the inner cavity of the circular backflow cover 21 cannot knock down the dust, the dust monitor 211 for monitoring the dust content in the inner cavity of the circular backflow cover 21 is fixedly mounted on the inner wall of the circular backflow cover 21, so that the dust monitor 211 can monitor the dust content in the inner cavity of the circular backflow cover 21 in real time, the spraying mechanism 4 is guided to assist dust fall, and meanwhile, the controller 212 connected with the dust monitor 211 is fixedly mounted on the outer wall of the circular backflow cover 21.

Further, the spraying mechanism 4 includes a first water pipe 41, the first water pipe 41 is attached to the outer wall of the circular backflow cover 21 and wound on the outer wall of the exhaust pipe 22, a water pump 42 is fixedly installed at one end of the first water pipe 41, an electronic switch valve 43 is fixedly installed on the water pump 42, a second water pipe 44 is communicated with one side of the water pump 42, the second water pipe 44 is communicated with the cleaning water tank, a third water pipe 45 for communicating with the first water pipe 41 is fixedly installed inside the annular supporting plate 23, an atomizing head 46 is communicated with the top of the third water pipe 45, when the water pump 42 operates, the second water pipe 44 extracts the water source of the cleaning water tank, and transmits the water to the third water pipe 45 through the first water pipe 41 to spray water mist from the atomizing head 46, so as to wet the gas in the inner cavity of the circular backflow cover 21, with the weight of the dust granule in the reinforcing gas, the whereabouts of dust is accelerated, wherein, be electric connection between water pump 42 and the electronic switch valve 43, and controller 212 and electronic switch valve 43, be electric connection between the water pump 42, when using, when the dust content is great in the gas that gets into circular backward flow cover 21 inner chamber, detect and feed back out through dust monitor 211, make controller 212 receive dust monitor 211's feedback information and give information transmission to electronic switch valve 43, make water pump 42 operate and carry the clean water to third water pipe 45 and spout from atomising head 46, and the water that spouts from atomising head 46 is with the gas of circular backward flow cover 21 inner chamber humidification, thereby make the dust weight increase, make the dust fall by gravity influence.

A dust falling method for carbon-neutralized dust removing equipment comprises the following steps:

s1: the second air guide sleeve 102 is communicated and installed at an indoor air outlet, air enters the inner cavity of the first air guide sleeve 101 from the second air guide sleeve 102, and the air blows the stop lever 104 to rotate, so that the air entering the inner cavity of the first air guide sleeve 101 from linear motion is dispersed all around, and the air is guided to uniformly enter the inner cavity of the first air guide sleeve 101 at the inlet of the first air guide sleeve 101;

s2: in the step S1, the gas entering the inner cavity of the first air guide sleeve 101 enters the inner cavity of the circular backflow sleeve 21 along the shape of the first air guide sleeve 101, and blows the fan blades 28 to drive the spherical sliding blocks 25 to slide in the inner cavity of the sliding grooves 24, so that the fan blades 28 rotate continuously in the inner cavity of the circular backflow sleeve 21, and the gas entering the inner cavity of the circular backflow sleeve 21 changes into a vortex-shaped gas flow;

s3: the vortex-shaped airflow formed by the inner cavity of the circular backflow hood 21 collides with the gas which moves from the inner cavity of the first flow guide hood 101 in sequence, so that the dust in the gas is continuously collided and bonded, and the small-particle dust in the gas is collided and bonded into larger particles and falls under the action of gravity;

s4: in the step S2, when the content of dust in the gas entering the inner cavity of the circular backflow cover 21 is relatively large, the dust is detected and fed back through the dust monitor 211, so that the controller 212 receives the feedback information of the dust monitor 211 and transmits the information to the electronic switch valve 43, the water pump 42 operates to convey the cleaning water to the third water pipe 45 to be sprayed out from the spray head 46, and the water sprayed out from the spray head 46 humidifies the gas in the inner cavity of the circular backflow cover 21, so that the weight of the dust is increased, and the dust falls under the influence of gravity;

s5: the falling dust particles and gas flow from the exhaust pipe 22 to the inner cavity of the third air guide sleeve 31, and when the gas passes through the damping plate 32, the gas is influenced by the round hole 34 formed in the inner cavity of the damping plate 32, so that the flowing speed of the gas is reduced, the collision frequency of the dust in the dust-containing gas flow is increased, the dust falling is accelerated, and the dust particles are adsorbed and fall on the damping plate 32

It should be noted that: through utilizing gaseous flabellum 28 that blows circular backward flow cover 21 inner chamber, make flabellum 28 drive spherical slider 25 and rotate at the inner chamber of circular backward flow cover 21 repeatedly, make the gaseous vortex air current that forms of entering circular backward flow cover 21 inner chamber and circulate round, thereby with the gaseous dust and the gaseous intermixing collision that successively gets into circular backward flow cover 21 inner chamber in the circular backward flow cover 21 inner chamber, make the small dust particle collision among the gas adhere into the large granule, finally through the increase of dust self weight, receive self gravity influence to fall with higher speed, thereby make the dust content among the gas of emission department reduce.

The points to be finally explained are: first, in the description of the present application, it should be noted that, unless otherwise specified and limited, the terms "mounted," "connected," and "connected" should be understood broadly, and may be a mechanical connection or an electrical connection, or a communication between two elements, and may be a direct connection, and "upper," "lower," "left," and "right" are only used to indicate a relative positional relationship, and when the absolute position of the object to be described is changed, the relative positional relationship may be changed;

secondly, the method comprises the following steps: in the drawings of the disclosed embodiment of the invention, only the structures related to the disclosed embodiment are related, other structures can refer to common design, and the same embodiment and different embodiments of the invention can be combined mutually under the condition of no conflict;

and finally: the above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the present invention, and any modifications, equivalents, improvements and the like made within the spirit and principle of the present invention should be included in the scope of the present invention.

Claims

1. The utility model provides a dust collecting equipment for carbon neutralization, includes first water conservancy diversion mechanism (1), one side intercommunication of first water conservancy diversion mechanism (1) is equipped with mixing mechanism (2) that are used for the hybrid processing dust granule, the bottom intercommunication of mixing mechanism (2) is equipped with second water conservancy diversion mechanism (3) that are used for reducing the dust granule velocity of flow, the inside of mixing mechanism (2) is equipped with spraying mechanism (4) that are used for cleaning its inner chamber, its characterized in that: the first air guide mechanism (1) comprises a first air guide sleeve (101), a second air guide sleeve (102) is fixedly mounted on one side of the first air guide sleeve (101), a hanging rack (106) is fixedly mounted on the outer wall of the second air guide sleeve (102), the first air guide sleeve (101) and the second air guide sleeve (102) are arranged in a mutually communicated state, a dust blocking curtain (103) used for being connected with the first air guide sleeve (101) is arranged at an air inlet of the first air guide sleeve (101), a plurality of blocking rods (104) are sequentially arranged on the inner wall of the first air guide sleeve (101) at equal intervals, and the outer walls of the blocking rods (104) are rotatably connected with a rotary drum (105);

the mixing mechanism (2) comprises a circular backflow cover (21), the circular backflow cover (21) is communicated with and arranged on one side, away from a second flow guide cover (102), of a first flow guide cover (101), an exhaust pipe (22) is communicated with the center line vertically of the circular backflow cover (21), an annular supporting plate (23) connected with the exhaust pipe (22) is fixedly arranged on the inner wall of the circular backflow cover (21), sliding grooves (24) are formed in the inner walls of the two sides of the circular backflow cover (21), a spherical sliding block (25) is slidably arranged in an inner cavity of each sliding groove (24), a connecting rod (26) is fixedly arranged on the outer wall of each spherical sliding block (25), fan blades (28) used for guiding the spherical sliding block (25) to move are arranged on the outer wall of the connecting rod (26), brushes (27) used for cleaning floating dust on the annular supporting plate (23) are arranged on the outer wall of the annular supporting rod (25), the brushes (27) and the fan blades (28) are arranged in one-to-one correspondence, and connecting sleeves (29) connected with the fan blades (26) are fixedly arranged on one side of the brushes (27) and the connecting rod (28);

the second air guide mechanism (3) comprises a third air guide sleeve (31), the third air guide sleeve (31) is communicated with the bottom of the exhaust pipe (22), a plurality of damping plates (32) are arranged in the inner cavity of the third air guide sleeve (31) at equal intervals, a plurality of round holes (34) used for reducing the flow velocity of air flow are formed in each damping plate (32), and a support bracket (33) is fixedly installed on the outer wall of the third air guide sleeve (31);

the number of the spherical sliding blocks (25) is set to be a plurality, the spherical sliding blocks (25) are sequentially arranged around the inner circumferential line of the sliding chute (24) in an annular mode at equal intervals, rotating rods (210) are fixedly arranged in inner cavities of the spherical sliding blocks (25), and the rotating rods (210) are rotatably connected to the inner cavity of the sliding chute (24);

the spraying mechanism (4) comprises a first water pipe (41), the first water pipe (41) is attached to the outer wall of the circular backflow cover (21) and wound on the outer wall of the exhaust pipe (22), a water pump (42) is fixedly installed at one end of the first water pipe (41), an electronic switch valve (43) is fixedly installed on the water pump (42), a second water pipe (44) is communicated with one side of the water pump (42), a third water pipe (45) communicated with the first water pipe (41) is fixedly installed inside the annular supporting plate (23), and the top of the third water pipe (45) is communicated with a spraying head (46);

the shape of first kuppe (101) is the setting of arc curve form, the vertical of first kuppe (101) is equipped with a curved concave part to center department, just the curved concave part inner chamber fixed mounting of first kuppe (101) has linkage plate (107), it has a plurality of links up chain (108) to articulate on the inner wall of linkage plate (107), and is a plurality of link up the equal fixedly connected with elastic sleeve (109) in one side of chain (108).

2. A dust removal apparatus for carbon neutralization according to claim 1, characterized in that: the number of the stop levers (104) is at least two, and the two stop levers (104) are symmetrically arranged relative to the horizontal center line of the first air guide sleeve (101).

3. A dust removal apparatus for carbon neutralization according to claim 2, characterized in that: fixed mounting has dust monitor (211) that is used for monitoring its inner chamber dust content on the inner wall of circular backward flow cover (21), fixed mounting has controller (212) that is used for being connected with dust monitor (211) on the outer wall of circular backward flow cover (21).