CN115184552B - Carbon emission on-line monitoring system with edge information fusion - Google Patents

Abstract

The invention discloses a carbon emission online monitoring system for edge information fusion, which comprises a monitoring device, wherein a display screen is arranged on the front side of the monitoring device, a suction inlet for sucking air is arranged at the top of the monitoring device, a stand column is rotatably arranged in the middle of the top end of the monitoring device, sliding grooves are formed in the outer sides of the stand column in an equidistant and encircling mode, a sliding block is slidably arranged in the sliding grooves, the top of the sliding block is fixedly connected with the top wall of the sliding groove through a first spring, a ring plate is fixedly connected to the outer sides of the sliding block through a connecting rod, and a pipe body is sleeved in the ring plate. The invention can realize vibration cleaning of the pipe body while switching the pipe body, so that excessive impurities in the air are prevented from adhering to the inner wall of the pipe body, the condition of affecting the air inlet effect of the pipe body is avoided, and the impact on the outer side of the pipe body can be realized while switching the pipe body, so that vibration is generated, the vibration cleaning effect is further improved, and the pipe body is worthy of popularization and use.

Description

Carbon emission on-line monitoring system with edge information fusion

Technical Field

The invention belongs to the technical field of carbon emission on-line monitoring, and particularly relates to an edge information fusion carbon emission on-line monitoring system.

Background

Carbon emissions are a generic or shorthand term for greenhouse gas emissions. The most predominant gas in greenhouse gases is Carbon dioxide, and is therefore represented by the term Carbon. Although inaccurate, the method of best understanding the public is simply to understand "carbon emissions" as "carbon dioxide emissions".

Any activity of human beings can cause carbon emission, for example, common people can simply burn and cook, and exhaust gas generated after any object is burned can generate carbon emission.

The carbon emission on-line monitoring system for the edge information fusion is a technology for monitoring carbon emission, when the existing carbon emission on-line monitoring system for the edge information fusion is used, external air is sucked into the system through a pipe body, analysis is carried out through a monitoring device, and a data result of the carbon emission is obtained, but when the existing carbon emission on-line monitoring system for the edge information fusion is used, a large amount of impurities are easily attached to the inner wall of the pipe body for collecting the air, the suction collection of the air is influenced by excessive impurities, and the use of the system is further influenced.

Therefore, it is necessary to invent an on-line monitoring system for carbon emission with the integration of edge information to solve the above problems.

Disclosure of Invention

In order to solve the problems, the invention provides an on-line carbon emission monitoring system with edge information fusion, which solves the problems in the background art.

In order to achieve the above purpose, the present invention provides the following technical solutions: the utility model provides a carbon emission on-line monitoring system of marginal information integration, includes monitoring devices, monitoring devices's front side is equipped with the display screen, monitoring devices's top is equipped with the sunction inlet of inhaled air, monitoring devices's top mid-section rotation installs the stand, the outside equidistance of stand is encircleed and is offered the spout, sliding installation has the slider in the spout, the top of slider is through first spring and spout roof fixed connection, connecting rod fixedly connected with link plate is passed through in the outside of slider, the inside cover of link plate is equipped with the body, the top of body is equipped with the closure subassembly, is located in the body bottom embedding sunction inlet of sunction inlet top, monitoring devices's outside fixed mounting has the dead lever, the top of dead lever is through gag lever post fixed mounting has the carrier plate, the top fixed mounting of carrier plate has first motor, the output shaft of first motor wears overload plate and stand fixed connection, monitoring devices's top equidistance fixed mounting has the promotion structure that is used for pushing the body to rise.

Further, the pushing structure is specifically configured as a block-shaped member with a cambered surface at one side.

Further, the sealing assembly comprises a mounting plate which is symmetrically and fixedly arranged at the top of the pipe body, a movable shaft is rotatably arranged between the two mounting plates, a cover plate is fixedly sleeved outside the movable shaft, the cover plate is matched with the top of the pipe body, a second motor is fixedly arranged at the outer side of the mounting plate, and an output shaft of the second motor penetrates through the mounting plate and is fixedly connected with one end of the movable shaft.

Further, the outside equidistance of body encircles fixed mounting has many pairs of T shape poles, every pair all the slip cap is equipped with the collision board between the T shape pole, the outside cover of T shape pole is equipped with the second spring, the second spring is located the one side that the body was kept away from to the collision board, the outside fixed mounting of collision board has L shape pole, the body rotates the cover and establishes in the inside of annular plate, the outside of annular plate is equipped with the extrusion subassembly that is used for driving L shape pole outward movement, the outside upper portion cover of body is equipped with first torsional spring, the both ends of first torsional spring respectively with the outside fixed connection of annular plate and body, the outside of body is equipped with and is used for driving its forward pivoted drive assembly.

Further, the extrusion assembly comprises a connecting plate which is fixedly installed on the outer side of the annular plate in an encircling mode at equal intervals, a connecting shaft is installed at the top of the connecting plate in a rotating mode, an arc-shaped plate is fixedly installed below the connecting plate in a extending mode at the bottom end of the connecting shaft, a collision piece is fixedly installed on one side, close to the pipe body, of the arc-shaped plate, a second torsion spring is sleeved on the outer portion of the connecting shaft, and two ends of the second torsion spring are fixedly connected with the connecting plate and the connecting shaft respectively.

Further, the abutting piece is specifically arranged to be a block-shaped component with an arc surface, wherein the block-shaped component is arranged on one side, close to the pipe body, of the abutting piece, and the abutting piece is attached to the pipe body.

Further, the drive assembly includes the first tooth that encircles and set up in body outside upper portion, the top fixed mounting of dead lever has the annular frame, the inboard interval of annular frame is provided with multiunit and first tooth matched with second tooth, the group number of second tooth corresponds with pushing structure number.

Further, a falling opening is formed in the top of the monitoring device and between two adjacent pushing structures.

Further, the top end opening area of the tube body is larger than the bottom end opening area of the tube body.

Further, a first baffle is fixedly arranged at the bottom of the annular plate, and a second baffle matched with the first baffle is fixedly arranged at the outer side of the pipe body.

The invention has the technical effects and advantages that:

1. the invention can realize the vibration cleaning of the pipe body while switching the pipe body, so that the situation that the air inlet effect is affected due to excessive adhesion of impurities in the air on the inner wall of the pipe body can be avoided;

2. the invention can realize the impact on the outer side of the pipe while switching, so that vibration is generated, and the vibration cleaning effect is further improved;

the invention can realize vibration cleaning of the pipe body while switching the pipe body, so that excessive impurities in the air are prevented from adhering to the inner wall of the pipe body, the condition of affecting the air inlet effect of the pipe body is avoided, and the impact on the outer side of the pipe body can be realized while switching the pipe body, so that vibration is generated, the vibration cleaning effect is further improved, and the pipe body is worthy of popularization and use.

Additional features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention. The objectives and other advantages of the invention may be realized and attained by the structure particularly pointed out in the written description and drawings.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions of the prior art, the following description will briefly explain the drawings used in the embodiments or the description of the prior art, and it is obvious that the drawings in the following description are some embodiments of the present invention, and other drawings can be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 shows a schematic structural diagram of an on-line carbon emission monitoring system with edge information fusion according to an embodiment of the present invention;

FIG. 2 shows an enlarged schematic view of the structure of FIG. 1A in accordance with an embodiment of the present invention;

FIG. 3 shows an enlarged schematic view of the structure of FIG. 1 at B in accordance with an embodiment of the present invention;

fig. 4 shows a second schematic structural diagram of an on-line carbon emission monitoring system with edge information fusion according to an embodiment of the present invention;

FIG. 5 is a schematic structural view showing a part of the structure of an embodiment of the present invention;

FIG. 6 shows an enlarged schematic view of the structure of FIG. 5 at C in accordance with an embodiment of the invention;

in the figure: 1. a monitoring device; 2. a suction inlet; 3. a column; 4. a slide block; 5. a connecting rod; 6. a ring plate; 7. a tube body; 8. a fixed rod; 9. a limit rod; 10. a first motor; 11. a pushing structure; 12. A cover plate; 13. a T-bar; 14. a collision plate; 15. a second spring; 16. an L-shaped rod; 17. an arc-shaped plate; 18. a second torsion spring; 19. a contact member; 20. a first tooth; 21. an annular frame; 22. a second tooth; 23. a drop port; 24. a display screen; 25. a first torsion spring; 26. a first baffle; 27. a second baffle; 28. and a second motor.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is apparent that the described embodiments are some embodiments of the present invention, but not all embodiments of the present invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

The invention provides an on-line monitoring system for carbon emission of edge information fusion, as shown in fig. 1-6, comprising a monitoring device 1, wherein the front side of the monitoring device 1 is provided with a display screen 24, the top of the monitoring device 1 is provided with a suction inlet 2 for sucking air, the monitoring device 1 is provided with a device for monitoring carbon emission in the prior art, the middle part of the top end of the monitoring device 1 is rotatably provided with a stand column 3, the outer side of the stand column 3 is equidistantly and circularly provided with a sliding groove, a sliding block 4 is slidably arranged in the sliding groove, the top of the sliding block 4 is fixedly connected with the top wall of the sliding groove through a first spring, the outer side of the sliding block 4 is fixedly connected with a ring plate 6 through a connecting rod 5, the inner part of the ring plate 6 is sleeved with a pipe body 7, the top of the pipe body 7 is provided with a sealing component, the top of the pipe body 7 can be opened and closed through the sealing component, so that the top of the rest pipe body 7 can be in a top sealing state when not in use, dust and impurities are prevented from entering, the bottom end of a tube body 7 positioned above the suction inlet 2 is embedded into the suction inlet 2, a fixed rod 8 is fixedly arranged on the outer side of the monitoring device 1, a carrier plate is fixedly arranged at the top of the fixed rod 8 through a limiting rod 9, a first motor 10 is fixedly arranged at the top of the carrier plate, an output shaft of the first motor 10 penetrates through the carrier plate to be fixedly connected with the upright post 3, a pushing structure 11 for pushing the tube body 7 to ascend is fixedly arranged at the top of the monitoring device 1 at equal intervals, when the monitoring device is used, the monitoring device 1 sucks the outside air into the inside of the tube body through the suction inlet 2 and the tube body 7 to analyze the carbon emission, the analyzed data is displayed through a display screen 24, the first motor 10 can be started to enable the output shaft of the first motor to rotate to drive the upright post 3 to rotate, so that a sliding block 4, a connecting rod 5 and a ring plate 6 are driven to rotate through a chute, the tube body 7 is driven to rotate, and the tube body 7 is switched, when the pipe body 7 combined with the suction inlet 2 moves, the pipe body 7 can be extruded by the inner wall of the suction inlet 2 to enable the upward movement to drive the annular plate 6, the connecting rod 5 and the sliding block 4 to move along with the upward movement, so that the first spring is compressed to enable deformation of the first spring to generate acting force, after the pipe body 7 leaves the suction inlet 2, the first spring releases acting force to drive the sliding block 4, the connecting rod 5 and the annular plate 6 to descend and reset, and then the pipe body 7 is reset after the pipe body 7 moves to the bottom and is in contact with the pushing structure 11, the pipe body 7 can slide along the pushing structure 11 to be extruded and rise, compression deformation of the first spring can be achieved, when the pipe body 7 moves to be separated from the pushing structure 11, at the moment, the first spring releases acting force to drive the sliding block 4, the connecting rod 5 and the annular plate 6 to descend and reset, and then the pipe body 7 is reset, and meanwhile the sliding block 4 collides with the bottom wall of the sliding groove to generate vibration, so that impurities attached to the inner wall of the pipe body 7 fall out through the bottom opening of the pipe body 7, the condition that the impurities in the air are attached to the inner wall of the pipe body 7 is prevented from being excessive, the condition that the impurities in the inner wall of the pipe body 7 is influenced, the condition that the impurities are attached to the pipe body 2 is separated, the pipe body 7 is separated, and the pipe body 7 is switched to the inner wall, and the pipe body 2 is switched after the pipe body is moved to the inner wall, and the pipe body 2 is cleaned, and the suction inlet 2 is completely cleaned.

As shown in fig. 1, the pushing structure 11 is specifically configured as a block member with an arc surface on one side, so that the bottom of the pipe body 7 moves to collide with the arc surface of the pushing structure 11 and then slides along the arc surface to be extruded and rise.

As shown in fig. 1-2, the sealing assembly comprises mounting plates symmetrically and fixedly mounted at the top of the pipe body 7, a movable shaft is rotatably mounted between the two mounting plates, a cover plate 12 is fixedly sleeved outside the movable shaft, the cover plate 12 is matched with the top of the pipe body 7, a second motor 28 is fixedly mounted at the outer side of the mounting plates, an output shaft of the second motor 28 penetrates through the mounting plates and is fixedly connected with one end of the movable shaft, the second motor 28 can be started to enable the output shaft of the second motor 28 to rotate positively to drive the movable shaft to rotate, so that the cover plate 12 is driven to rotate and open the top of the pipe body 7, and conversely, the output shaft of the second motor 28 rotates reversely to enable the cover plate 12 to be closed so that the top of the pipe body 7 is closed.

As shown in fig. 1-3, a plurality of pairs of T-shaped rods 13 are fixedly installed around the outer side of the pipe body 7 at equal intervals, a collision plate 14 is arranged between each pair of T-shaped rods 13 in a sliding manner, a second spring 15 is arranged on the outer side of the T-shaped rods 13 in a sleeved manner, the second spring 15 is located on one side of the collision plate 14 away from the pipe body 7, an L-shaped rod 16 is fixedly installed on the outer side of the collision plate 14, the pipe body 7 is rotatably sleeved in the annular plate 6, an extrusion component for driving the L-shaped rods 16 to move outwards is arranged on the outer side of the annular plate 6, a first torsion spring 25 is sleeved on the upper portion of the outer side of the pipe body 7, two ends of the first torsion spring 25 are respectively fixedly connected with the annular plate 6 and the outer side of the pipe body 7, a driving component for driving the pipe body 7 to rotate in a intermittent manner, when the pipe body 7 moves along with the circumference of the upright post 3, the first torsion spring 25 is matched with the driving component to drive the pipe body 7 to rotate positively, and at the same time, the pipe body 7 moves upwards along the pushing structure 11, the pipe body 7 rotates upwards, the pipe body 7 is rotated, after the pipe body 7 leaves the pushing structure 11, the extrusion component for driving the pipe body 7 is arranged, the first torsion spring 25 is arranged on the outer side of the pipe body 7, the extrusion component is extruded by the first torsion spring 25, the second torsion spring is matched with the outer side of the pipe body 7, the second torsion spring 15 is compressed, the second impact body is produced, the second impact component is produced, the second impact force of the second impact component is produced by the impact force of the impact rod 16, and the second impact force of the pipe body 15, and the second impact component 16 is released, and the impact force of the impact component 16, and the impact force of the pipe 15 is made.

As shown in fig. 1, fig. 3, fig. 5 and fig. 6, the extrusion component includes the equidistant link plate that encircles fixed mounting in the annular plate 6 outside, the top rotation of link plate installs the connecting axle, the bottom of connecting axle extends to link plate below fixed mounting and has arc 17, one side that arc 17 is close to body 7 fixed mounting has conflict piece 19, the outside cover of connecting axle is equipped with second torsional spring 18, the both ends of second torsional spring 18 respectively with link plate and connecting axle fixed connection, drive T shape pole 13 and bump plate 14 with it when body 7 corotation, thereby drive L shape pole 16 and move thereupon, after L shape pole 16 moves to contradicting with arc 17, it produces effort to drive arc 17 along with the connecting axle corotation, the separation of arc 17 with arc 17, second torsional spring 18 release effort drives connecting axle and arc 17 reset, when body 7 is in reverse rotation, same drive L shape pole 16 moves thereupon with arc 17, the existence of conflict piece 19 makes L shape pole 16 carry out the extrusion effort to bump plate 14, and make the outside bump plate 14 produce the impact 15 to separate effort, and make the outside impact plate 14 can's the impact 15 to make it produce the impact, and make the outside of bump plate 14 to separate the impact 15 and make it produce the impact.

As shown in fig. 5-6, the abutting piece 19 is specifically configured as a block-shaped member with an arc surface near one side of the tube body 7, the abutting piece 19 is attached to the tube body 7, the abutting piece 19 is fixedly connected to one side of the arc plate 17 near the tube body 7, and when the arc plate 17 is about to rotate reversely, the abutting piece 19 abuts against the outer side of the tube body 7, so that the arc plate 17 cannot rotate reversely, limiting is achieved, and the arc plate 17 can rotate positively and cannot rotate reversely.

As shown in fig. 1 and 4, the driving assembly includes a first tooth 20 surrounding the upper portion of the outer side of the tube 7, an annular frame 21 is fixedly installed at the top end of the fixing rod 8, a plurality of groups of second teeth 22 matched with the first tooth 20 are arranged at intervals on the inner side of the annular frame 21, the width of the second teeth 22 is larger than that of the first teeth 20, when the first teeth 20 and the second teeth 22 are meshed and ascend, the first teeth 20 and the second teeth 22 can keep a meshed state, the number of the groups of the second teeth 22 corresponds to that of the pushing structure 11, when the tube 7 moves along with the circumference of the upright post 3, the first teeth 20 and the second teeth 22 on the outer side of the tube 7 are meshed and then can drive the tube 7 to rotate positively, and meanwhile, the first torsion spring 25 is pulled to deform to generate acting force, when the first teeth 20 and the second teeth 22 are separated, the first torsion spring 25 releases the acting force to drive the tube 7 to rotate reversely.

As shown in fig. 1, a falling opening 23 is formed at the top of the monitoring device 1 and between two adjacent pushing structures 11, so that the falling impurity falling out from the bottom of the pipe body 7 can fall out along the falling opening 23, guiding of the impurity is realized, and the impurity leaves the surface of the monitoring device 1.

As shown in fig. 5, the top end opening area of the tube body 7 is larger than the bottom end opening area thereof, so that the bottom of the tube body 7 has an arc, so that the tube body can be extruded and lifted when being in contact with the inner wall or the outer side of the suction inlet 2, and can be more tightly combined with the suction inlet 2.

As shown in fig. 5, a first baffle 26 is fixedly installed at the bottom of the annular plate 6, a second baffle 27 matched with the first baffle 26 is fixedly installed at the outer side of the pipe body 7, the pipe body 7 rotates forward to drive the second baffle 27 to rotate, the second baffle 27 is separated from the first baffle 26, and when the pipe body 7 rotates reversely to drive the second baffle 27 to move and collide with the first baffle 26, the pipe body 7 can stop rotating, and the first torsion spring 25 is prevented from being pulled reversely to protect the pipe body.

Working principle: when in use, the monitoring device 1 sucks the outside air into the interior of the air suction inlet 2 and the pipe body 7 to analyze the carbon emission, the analyzed data is displayed through the display screen 24, the first motor 10 can be started to drive the output shaft of the first motor to rotate so as to drive the upright post 3 to rotate, the sliding block 4, the connecting rod 5 and the annular plate 6 to rotate through the sliding groove, the pipe body 7 is further driven to rotate, the pipe body 7 is further driven to switch, when the pipe body 7 combined with the air suction inlet 2 moves, the pipe body 7 is extruded by the inner wall of the air suction inlet 2 so as to move upwards to drive the annular plate 6, the connecting rod 5 and the sliding block 4 to move along with the air suction inlet 2, the first spring is compressed to deform to generate acting force, when the pipe body 7 leaves the air suction inlet 2, the first spring releases the acting force to drive the sliding block 4, the connecting rod 5 and the annular plate 6 to descend and reset, the pipe body 7 is further reset, and after the pipe body 7 moves to the bottom and the pushing structure 11 are in conflict, the first spring can be compressed and deformed by the same way when the pushing structure 11 slides and is pressed up, when the pipe body 7 moves to be separated from the pushing structure 11, the first spring releases acting force to drive the sliding block 4, the connecting rod 5 and the annular plate 6 to descend and reset, so that the pipe body 7 resets, and meanwhile, the sliding block 4 collides with the bottom wall of the sliding groove to generate vibration, so that impurities attached to the inner wall of the pipe body 7 are vibrated to fall out through the bottom end opening of the pipe body 7, the cleaning of the inner wall of the pipe body 7 is realized, the phenomenon that the impurities in the air are attached to the inner wall of the pipe body 7 too much to influence the air inlet effect is avoided, and the pipe body 7 after cleaning moves to collide with the outer wall of the suction inlet 2 and then ascends, so that the pipe body 7 enters into the suction inlet 2 to be combined with the inner wall of the suction inlet 2, the switching and cleaning of the pipe body 7 are completed, the second motor 28 can be started to drive the movable shaft to rotate in the forward direction, so that the cover plate 12 is driven to rotate and open the top of the pipe body 7, the pipe body 7 to be used is opened, on the contrary, the reverse rotation of the output shaft of the second motor 28 can realize the closing of the cover plate 12, so that the top of the pipe body 7 is closed, the unused pipe body 7 is closed, impurities are prevented from entering, when the pipe body 7 moves along with the upright post 3 in a circular manner, the first teeth 20 and the second teeth 22 on the outer side of the pipe body are meshed, then the pipe body 7 is driven to rotate in the forward direction, the first torsion spring 25 is pulled to deform the pipe body to generate acting force, the pipe body 7 moves upwards along the pushing structure 11, the T-shaped rod 13 and the collision plate 14 are driven to move along when the pipe body 7 rotates in the forward direction, the L-shaped rod 16 is driven to move along with the L-shaped rod 16 to collide with the arc plate 17, the arc plate 17 is driven to rotate in the forward direction along the connecting shaft to pull the second torsion spring 18 to deform to generate acting force, when the L-shaped rod 16 moves to be separated from the arc-shaped plate 17, the second torsion spring 18 releases the acting force to drive the connecting shaft and the arc-shaped plate 17 to reset, after the pipe body 7 leaves the pushing structure 11, the first tooth 20 is separated from the second tooth 22, at the moment, the first torsion spring 25 releases the acting force to drive the pipe body 7 to rotate reversely, when the pipe body 7 rotates reversely, the L-shaped rod 16 is driven to move along with the L-shaped rod 16 to collide with the arc-shaped plate 17, at the moment, the arc-shaped plate 17 can not rotate reversely due to the existence of the collision piece 19, the L-shaped rod 16 is extruded to move outwards, the collision plate 14 is pulled to move outwards to compress the second spring 15 to deform to generate the acting force, when the L-shaped rod 16 is separated from the arc-shaped plate 17, at the moment, the second spring 15 releases the acting force to drive the collision plate 14 to reset to collide with the outer side of the pipe body 7 to generate vibration, and impurities attached to the inner wall of the pipe body 7 can be vibrated down, promote the cleaning effect to impurity.

Although the invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present invention.

Claims (2)

1. The utility model provides a carbon emission on-line monitoring system of marginal information fusion, includes monitoring devices (1), its characterized in that: the front side of the monitoring device (1) is provided with a display screen (24), the top of the monitoring device (1) is provided with a suction inlet (2) for sucking air, a stand column (3) is rotatably arranged in the middle of the top end of the monitoring device (1), a sliding groove is formed in the outer side of the stand column (3) in an equidistant surrounding mode, a sliding block (4) is arranged in the sliding groove in a sliding mode, the top of the sliding block (4) is fixedly connected with the top wall of the sliding groove through a first spring, the outer side of the sliding block (4) is fixedly connected with a ring plate (6) through a connecting rod (5), a pipe body (7) is sleeved in the ring plate (6), a sealing component is arranged at the top of the pipe body (7) above the suction inlet (2), a fixing rod (8) is fixedly arranged at the outer side of the monitoring device (1), a supporting plate is fixedly arranged at the top of the fixing rod (8) through a limiting rod (9), a first motor (10) is fixedly arranged at the top of the supporting plate, and the first output shaft motor (10) is fixedly connected with the top of the stand column (3) in a penetrating mode, and the monitoring device (11) is fixedly connected with the top of the lifting device in a penetrating mode;

the pushing structure (11) is specifically arranged as a block-shaped member with one side provided with an arc surface;

the sealing assembly comprises mounting plates symmetrically and fixedly mounted at the top of the pipe body (7), a movable shaft is rotatably mounted between the two mounting plates, a cover plate (12) is fixedly sleeved outside the movable shaft, the cover plate (12) is matched with the top of the pipe body (7), a second motor (28) is fixedly mounted at the outer side of the mounting plates, and an output shaft of the second motor (28) penetrates through the mounting plates and is fixedly connected with one end of the movable shaft;

the outer side of the pipe body (7) is fixedly provided with a plurality of pairs of T-shaped rods (13) in an equidistance surrounding manner, collision plates (14) are sleeved between each pair of T-shaped rods (13) in a sliding manner, the outer sides of the T-shaped rods (13) are sleeved with second springs (15), the second springs (15) are positioned on one side, far away from the pipe body (7), of the collision plates (14), L-shaped rods (16) are fixedly arranged on the outer sides of the collision plates (14), the pipe body (7) is rotatably sleeved in the ring plate (6), an extrusion assembly used for driving the L-shaped rods (16) to move outwards is arranged on the outer sides of the ring plate (6), first torsion springs (25) are sleeved on the upper parts of the outer sides of the pipe body (7), and two ends of each first torsion spring (25) are fixedly connected with the ring plate (6) and the outer sides of the pipe body (7) respectively;

the extrusion assembly comprises connecting plates which are fixedly arranged on the outer side of the annular plate (6) in an equidistance surrounding manner, a connecting shaft is rotatably arranged at the top of the connecting plate, an arc plate (17) is fixedly arranged below the connecting plate, an abutting piece (19) is fixedly arranged on one side, close to the pipe body (7), of the arc plate (17), a second torsion spring (18) is sleeved on the outer portion of the connecting shaft, and two ends of the second torsion spring (18) are fixedly connected with the connecting plate and the connecting shaft respectively;

the abutting piece (19) is specifically a block-shaped component with an arc surface arranged on one side close to the pipe body (7), and the abutting piece (19) is attached to the pipe body (7);

the driving assembly comprises first teeth (20) which are arranged on the upper part of the outer side of the pipe body (7) in a surrounding mode, an annular frame (21) is fixedly arranged at the top end of the fixing rod (8), a plurality of groups of second teeth (22) which are matched with the first teeth (20) are arranged on the inner side of the annular frame (21) at intervals, and the number of the groups of second teeth (22) corresponds to the number of pushing structures (11);

a falling opening (23) is formed in the top of the monitoring device (1) and between two adjacent pushing structures (11);

the bottom of the annular plate (6) is fixedly provided with a first baffle (26), and the outer side of the pipe body (7) is fixedly provided with a second baffle (27) matched with the first baffle (26).

2. The carbon emission online monitoring system for edge information fusion according to claim 1, wherein: the top end opening area of the pipe body (7) is larger than the bottom end opening area of the pipe body.