CN116183311B

CN116183311B - Monitoring and collecting device for carbon dioxide sealed by forsterite

Info

Publication number: CN116183311B
Application number: CN202211098765.4A
Authority: CN
Inventors: 汪盛明; 祝道全; 胡莹; 余超; 董博; 邓承继; 魏建国; 程厚睿
Original assignee: Wuhan Lichan Environmental Protection Technology Co ltd
Current assignee: Wuhan Lichan Environmental Protection Technology Co ltd
Priority date: 2022-09-07
Filing date: 2022-09-07
Publication date: 2023-09-26
Anticipated expiration: 2042-09-07
Also published as: CN116183311A

Abstract

The invention relates to the technical field of carbon dioxide sealing and discloses a monitoring and collecting device for sealing and collecting carbon dioxide by forsterite, which solves the problems that the permeability of gas inside and outside the monitoring and collecting device is low, an electronic element inside the monitoring and collecting device can break down due to damp and a filter plate on the monitoring and collecting device is easy to be blocked by dust, and the permeability inside and outside the monitoring and collecting device is further reduced; impurities on the filter plate can be shaken off, the permeability inside and outside the shell is increased, and the air flow in the shell can be quickened, so that all positions in the shell are heated uniformly.

Description

Monitoring and collecting device for carbon dioxide sealed by forsterite

Technical Field

The invention belongs to the technical field of carbon dioxide sealing and storage, and particularly relates to a monitoring and collecting device for sealing and storing carbon dioxide by forsterite for carbon sealing and storage.

Background

Carbon dioxide sequestration methods currently being studied mainly in the world mainly include geological sequestration, marine sequestration and mineral sequestration. The raw materials for mineral sealing include forsterite, serpentine, talcum, brucite and the like, and when the forsterite seals carbon dioxide, the carbon dioxide needs to be monitored and collected.

The permeability of the gas inside and outside the monitoring and collecting device is lower, the electronic element inside the monitoring and collecting device can break down due to damp, and the filter plate on the monitoring and collecting device is also easy to be blocked by dust, so that the permeability inside and outside the monitoring and collecting device is further reduced.

Disclosure of Invention

Aiming at the situation, in order to overcome the defects of the prior art, the invention provides a monitoring and collecting device for carbon dioxide sequestration of forsterite, which effectively solves the problems in the background art.

In order to achieve the above purpose, the present invention provides the following technical solutions: a monitor collection system for carbon is sealed up to forsterite and is stored up carbon dioxide, including casing and carbon dioxide concentration collector, carbon dioxide concentration collector sets up on the casing, the bottom of casing is equipped with a plurality of supporting shoe, the bleeder vent has been seted up to the bottom inner wall of casing, the bottom inner wall fixedly connected with solid fixed ring of casing, and gu fixed ring and bleeder vent cooperate, be equipped with the filter in the bleeder vent, be equipped with first backup pad in the casing, filter and first backup pad are connected through two first connecting plates, first connecting plate and casing pass through elastic stretching unit and connect, the below of first backup pad is equipped with two fly leaves, the top fixedly connected with striking piece of fly leaf, the top and the casing of fly leaf are connected through elastic compression unit, be equipped with on the inner wall of casing with the fly leaf matched with magnetic absorber, the below of fly leaf is equipped with the cam, one side fixedly connected with first pivot of cam, first pivot and casing are connected through first rotating member, be equipped with one of them first pivot matched with rotary driving mechanism in the casing, be equipped with worm and casing pass through the second rotating member and connect, first and be connected through the worm through gear engagement unit, be equipped with the second pivot and be equipped with the second pivot through the synchronous both sides.

Preferably, the synchronous transmission assembly comprises a first fixing plate arranged below a second rotating shaft, the second rotating shaft penetrates through the first fixing plate, a first bearing is arranged at the penetrating position of the second rotating shaft and the first fixing plate, the first fixing plate is connected with the inner wall of the shell through a second connecting plate, a third rotating shaft is arranged in the shell, the bottom end of the third rotating shaft is connected with the bottom inner wall of the shell through a second bearing, a worm wheel fixedly connected is sleeved outside the third rotating shaft, the worm is meshed with the worm wheel, and the third rotating shaft is connected with the second rotating shaft through a transmission unit.

Preferably, the transmission unit comprises a first sprocket arranged at the bottom end of the second rotating shaft, the first sprocket is fixedly connected with the second rotating shaft, the top end of the third rotating shaft is fixedly connected with a second sprocket, and the first sprocket is connected with the second sprocket through a first chain.

Preferably, the first rotating member comprises a second fixing plate arranged at one side of the first rotating shaft, the second fixing plate is fixedly connected with the inner wall of the shell, the first rotating shaft penetrates through the second fixing plate, and a third bearing is arranged at the penetrating position of the first rotating shaft and the second fixing plate.

Preferably, the gear meshing unit comprises a first conical gear arranged at one end, far away from the cam, of the first rotating shaft, the first conical gear is fixedly connected with the first rotating shaft, the two ends of the worm are fixedly connected with second conical gears, and the two first conical gears are meshed with the two second conical gears respectively.

Preferably, the second rotating member comprises third fixing plates symmetrically arranged at two ends of the worm, the third fixing plates are fixedly connected with the inner wall of the shell, the worm penetrates through the two third fixing plates, and a fourth bearing is arranged at the penetrating position of the worm and the third fixing plates.

Preferably, the rotary driving mechanism comprises a third sprocket sleeved outside one of the first rotating shafts, the third sprocket is fixedly connected with the first rotating shaft, a motor seat is fixedly connected with the inner wall of one side of the shell, a motor is arranged on one side of the motor seat, a fourth sprocket is arranged at the output end of the motor, and the fourth sprocket is connected with the third sprocket through a second chain.

Preferably, the magnetic absorber comprises electromagnets symmetrically arranged on the inner walls of the two sides of the shell, the electromagnets are fixedly connected with the inner walls of the shell, an iron plate is arranged below the electromagnets, and the two iron plates are fixedly connected with the two movable plates respectively.

Preferably, the elastic compression unit comprises a second supporting plate arranged above the movable plate, the first supporting plate is located between the second supporting plate and the impact block, the second supporting plate is fixedly connected with the inner wall of the shell, the top of the movable plate is fixedly connected with two first fixing columns, the top ends of the first fixing columns penetrate through the second supporting plate, compression springs are sleeved outside the first fixing columns, and two ends of each compression spring are fixedly connected with the second supporting plate and the movable plate respectively.

Preferably, the elastic stretching unit comprises two third connecting plates arranged below the first supporting plate, the two first connecting plates respectively penetrate through the two third connecting plates, the first connecting plates are fixedly connected with the third connecting plates, two second fixing columns are arranged below the third connecting plates, the bottom ends of the second fixing columns are fixedly connected with the bottom inner wall of the shell, the second fixing columns penetrate through the third connecting plates, stretching springs are sleeved outside the second fixing columns, the two ends of each stretching spring are respectively fixedly connected with the inner wall of the shell and the third connecting plates, sealing rings are sleeved outside the filter plates, and the sealing rings are contacted with the inner wall of the air holes.

Compared with the prior art, the invention has the beneficial effects that:

(1) One of the first rotating shafts can be driven to rotate through the design of the rotary driving mechanism, one of the first rotating shafts can be driven to synchronously rotate through the worm when the gear meshing unit is designed, so that the two cams synchronously rotate, the movable plate is driven to vertically move by the cams when the cams rotate, the impact block impacts the first supporting plate, the first connecting plate and the filter plate are further impacted upwards, impurities on the filter plate are enabled to shake down, the permeability inside and outside the shell is increased, the inside of the shell can be heated through the design of the heater, the air in the shell is enabled to be dried, and the electronic elements are prevented from being affected with damp, through the design of the synchronous transmission assembly, when the worm rotates, the second rotating shaft can synchronously rotate, so that the fan blades rotate, air flow in the shell is quickened, all positions in the shell are heated uniformly, through the design of the magnetic absorber, when the second rotating shaft is only required to be driven to rotate, the movable plate is driven to move upwards through the magnetic absorber, the distance between the movable plate and the cam is increased, when the cam rotates, the cam is not contacted with the movable plate, the filter plate can not shake any more, when the impurities on the filter plate do not need to be cleaned, and when the impurities on the filter plate are only heated in the shell, the worm can only drive the second rotating shaft to rotate;

(2) The motor drives the fourth sprocket wheel to rotate through the design of the rotary driving mechanism, and then drives the third sprocket wheel to rotate through the second chain, so that the first rotating shaft can rotate, and the first rotating shaft can stably rotate relative to the shell through the design of the second fixing plate and the third bearing;

(3) The worm is enabled to rotate stably relative to the shell through the design of the third fixing plate and the fourth bearing, when one first rotating shaft rotates, the second conical gear is driven to rotate through the first conical gear, the worm is further enabled to rotate, the other first rotating shaft is enabled to rotate through the cooperation of the other group of first conical gears and the second conical gears, and therefore the two cams can be enabled to rotate synchronously;

(4) The design of the second supporting plate, the first fixed column and the compression spring enables the movable plate to be elastically connected with the shell, the compression spring is in a compression state, the compression spring applies downward force to the movable plate, the movable plate can be tightly attached to the cam, the electromagnet is electrified, the electromagnet applies upward magnetic force to the iron plate, the iron plate and the movable plate move upwards, the iron plate and the electromagnet are attracted together, the distance between the movable plate and the cam is increased, the cam cannot contact with the movable plate when the cam rotates, the third connecting plate is elastically connected with the first connecting plate through the design of the third connecting plate, the second fixed column and the tension spring, after the first supporting plate is impacted and moved upwards, the filter plate moves into the fixed ring, the tension spring is in a tension state, the impact block is not contacted with the first supporting plate any more, the tension spring can drive the first supporting plate to reset to an initial position, and the filter plate is further moved to the vent hole again;

(5) When the worm rotates, the worm wheel is driven to rotate through the worm, the worm wheel is further driven to rotate through the third rotating shaft, the second sprocket is driven to rotate through the third rotating shaft, the first sprocket is further driven to rotate through the first chain, the second rotating shaft is further driven to rotate, and when the worm rotates, the second rotating shaft can be driven to synchronously rotate.

Drawings

The accompanying drawings are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate the invention and together with the embodiments of the invention, serve to explain the invention.

In the drawings:

FIG. 1 is a schematic diagram of the overall structure of the present invention;

FIG. 2 is a schematic view of the structure of the inside of the housing of the present invention;

FIG. 3 is a schematic view of a partial enlarged structure at A in FIG. 2;

FIG. 4 is a schematic structural view of a first fixing plate according to the present invention;

FIG. 5 is a schematic diagram of a synchronous drive assembly according to the present invention;

FIG. 6 is a schematic structural view of an elastic stretching unit according to the present invention;

FIG. 7 is a schematic view of a rotary drive mechanism according to the present invention;

fig. 8 is a schematic structural view of the elastic compressing unit of the present invention.

In the figure: 1. a housing; 2. a carbon dioxide concentration collector; 3. a support block; 4. a fixing ring; 5. a filter plate; 6. a first support plate; 7. a first connection plate; 8. a movable plate; 9. an impact block; 10. a first rotating shaft; 11. a cam; 12. a worm; 13. a second rotating shaft; 14. a fan blade; 15. a heater; 16. a first fixing plate; 17. a first bearing; 18. a second connecting plate; 19. a first sprocket; 20. a third rotating shaft; 21. a worm wheel; 22. a second bearing; 23. a second sprocket; 24. a first chain; 25. a second fixing plate; 26. a third bearing; 27. a first bevel gear; 28. a second bevel gear; 29. a third fixing plate; 30. a fourth bearing; 31. a third sprocket; 32. a motor base; 33. a motor; 34. a fourth sprocket; 35. a second chain; 36. an electromagnet; 37. an iron plate; 38. a second support plate; 39. a first fixing column; 40. a compression spring; 41. a seal ring; 42. a third connecting plate; 43. a second fixing column; 44. and (5) stretching the spring.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the 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 first embodiment, as shown in fig. 1 to 8, the invention comprises a shell 1 and a carbon dioxide concentration collector 2, the carbon dioxide concentration collector 2 is arranged on the shell 1, a plurality of supporting blocks 3 are arranged at the bottom of the shell 1, ventilation holes are formed in the inner wall of the bottom of the shell 1, a fixed ring 4 is fixedly connected to the inner wall of the bottom of the shell 1, the fixed ring 4 is matched with the ventilation holes, a filter plate 5 is arranged in the ventilation holes, a first supporting plate 6 is arranged in the shell 1, the filter plate 5 is connected with the first supporting plate 6 through two first connecting plates 7, the first connecting plates 7 are connected with the shell 1 through an elastic stretching unit, two movable plates 8 are arranged below the first supporting plate 6, an impact block 9 is fixedly connected to the top of the movable plates 8, the top of the movable plates 8 are connected with the shell 1 through an elastic compression unit, a magnetic absorber matched with the movable plates 8 is arranged on the inner wall of the shell 1, a cam 11 is arranged below the movable plates 8, one side of the cam 11 is fixedly connected with a first rotating shaft 10, the first rotating shaft 10 is connected with the shell 1 through a first rotating member, a rotary driving mechanism matched with one of the first rotating shafts 10 is arranged in the shell 1, a worm 12 is arranged in the shell 1, the worm 12 is connected with the shell 1 through a second rotating member, the first rotating shaft 10 is connected with the worm 12 through a gear meshing unit, a second rotating shaft 13 is arranged above the first supporting plate 6, a plurality of fan blades 14 are arranged on the second rotating shaft 13, heaters 15 are arranged on the inner walls of two sides of the shell 1, the second rotating shaft 13 is connected with the worm 12 through a synchronous transmission assembly, one of the first rotating shafts 10 can be driven to rotate through the design of the rotary driving mechanism, and when one of the first rotating shafts 10 rotates through the design of the gear meshing unit, the other first rotating shaft 10 can be driven to synchronously rotate through the worm 12, and then make two cams 11 synchronous rotation, when the cam 11 rotates, cam 11 drives fly leaf 8 vertical direction and removes, striking piece 9 strikes first backup pad 6, and then make first connecting plate 7 and filter 5 receive ascending impact force, thereby make impurity on the filter plate 5 shake down, the inside and outside permeability of casing 1 has been increased, through the design of heater 15, can heat in the casing 1, make the air drying in the casing 1, prevent electronic component from being wet, through synchronous drive assembly's design, worm 12 rotatory time, can make the synchronous rotation of second pivot 13, and then make flabellum 14 rotatory, accelerate the air flow in the casing 1, make each position in the casing 1 be heated evenly, through the design of magnetic absorber, when impurity on the filter plate 5 need not be cleared up, only need drive second pivot 13 rotatory, through the upper shift of magnetic absorber drive fly leaf 8, distance between increase fly leaf 8 and the cam 11, make cam 11 can not contact with fly leaf 8, can make the filter plate 5 can not shake again, when the filter plate 5 need not carry out the rotation only to heat the second pivot 13 when the filter plate 5, when need not be cleared up to rotate to the impurity in the casing 12, can only be cleared up when the second pivot 13 rotates.

Based on the first embodiment, as shown in fig. 4 and fig. 5, the synchronous transmission assembly includes a first fixing plate 16 disposed below a second rotating shaft 13, the second rotating shaft 13 penetrates through the first fixing plate 16, a first bearing 17 is disposed at the penetrating position of the second rotating shaft 13 and the first fixing plate 16, the first fixing plate 16 is connected with the inner wall of the casing 1 through a second connecting plate 18, a third rotating shaft 20 is disposed in the casing 1, the bottom end of the third rotating shaft 20 is connected with the bottom inner wall of the casing 1 through a second bearing 22, a fixedly connected worm wheel 21 is sleeved outside the third rotating shaft 20, the worm 12 is meshed with the worm wheel 21, the third rotating shaft 20 is connected with the second rotating shaft 13 through a transmission unit, the transmission unit includes a first sprocket 19 disposed at the bottom end of the second rotating shaft 13, the first sprocket 19 is fixedly connected with the second sprocket 23, the first sprocket 19 is connected with the second sprocket 23 through a first chain 24, when the worm 12 rotates, the worm wheel 21 is driven to rotate through the worm 12, and then the worm wheel 21 is driven to rotate, the worm wheel 21 is further, the worm wheel 12 is driven to rotate, and the worm wheel 20 is further driven to rotate through the second sprocket 23, namely, the second sprocket 13 is driven to rotate through the second sprocket 23, and then the second sprocket 13 rotates.

In the third embodiment, as shown in fig. 5 and 7, the first rotating member includes a second fixing plate 25 disposed on one side of the first rotating shaft 10, the second fixing plate 25 is fixedly connected with the inner wall of the housing 1, the first rotating shaft 10 penetrates through the second fixing plate 25, a third bearing 26 is disposed at the penetrating position of the first rotating shaft 10 and the second fixing plate 25, the rotation driving mechanism includes a third sprocket 31 sleeved outside one of the first rotating shafts 10, the third sprocket 31 is fixedly connected with the first rotating shaft 10, a motor base 32 is fixedly connected with one side of the housing 1, a motor 33 is disposed on one side of the motor base 32, a fourth sprocket 34 is disposed at the output end of the motor 33, the fourth sprocket 34 is connected with the third sprocket 31 through a second chain 35, the motor 33 drives the fourth sprocket 34 to rotate through the design of the rotation driving mechanism, and then the third sprocket 31 is driven to rotate through the second chain 35, so that the first rotating shaft 10 rotates smoothly relative to the housing 1 through the design of the second fixing plate 25 and the third bearing 26.

In the fourth embodiment, as shown in fig. 5, the gear engagement unit includes a first bevel gear 27 disposed at one end of the first rotating shaft 10 far from the cam 11, the first bevel gear 27 is fixedly connected with the first rotating shaft 10, two ends of the worm 12 are fixedly connected with a second bevel gear 28, the two first bevel gears 27 are respectively engaged with the two second bevel gears 28, the second rotating member includes a third fixing plate 29 symmetrically disposed at two ends of the worm 12, the third fixing plate 29 is fixedly connected with the inner wall of the housing 1, the worm 12 penetrates through the two third fixing plates 29, and a fourth bearing 30 is disposed at the penetration position of the worm 12 and the third fixing plate 29;

through the design of third fixed plate 29 and fourth bearing 30 for worm 12 is steady rotation relative to casing 1, through the design of first bevel gear 27 and second bevel gear 28, when one of them first pivot 10 is rotatory, through first bevel gear 27 drive second bevel gear 28 rotation, and then make worm 12 rotate, through the cooperation of another group of first bevel gear 27 and second bevel gear 28, make worm 12 drive another first pivot 10 rotation, thereby can make two cams 11 synchronous rotation.

Based on the first embodiment, the magnetic absorber comprises electromagnets 36 symmetrically arranged on the inner walls of two sides of a shell 1, the electromagnets 36 are fixedly connected with the inner walls of the shell 1, iron plates 37 are arranged below the electromagnets 36, the two iron plates 37 are respectively and fixedly connected with the two movable plates 8, an elastic compression unit comprises a second supporting plate 38 arranged above the movable plates 8, the first supporting plate 6 is positioned between the second supporting plate 38 and an impact block 9, the second supporting plate 38 is fixedly connected with the inner wall of the shell 1, the top of the movable plate 8 is fixedly connected with two first fixing columns 39, the top ends of the first fixing columns 39 penetrate through the second supporting plate 38, compression springs 40 are sleeved outside the first fixing columns 39, two ends of the compression springs 40 are respectively and fixedly connected with the second supporting plate 38 and the movable plates 8, an elastic stretching unit comprises two third connecting plates 42 arranged below the first supporting plate 6, the two first connecting plates 7 respectively penetrate through the two third connecting plates 42, the first connecting plates 7 and the third connecting plates 42 are fixedly connected with the second connecting plates 42, two ends of the second fixing columns 43 are fixedly connected with the second connecting plates 43 and the bottom ends of the outer walls of the shell 1, the second fixing columns 43 are fixedly connected with the second connecting plates 43 are fixedly connected with the outer walls of the second fixing columns 43, and the outer ends of the extension columns 43 are fixedly connected with the outer walls of the filter plates 43 are fixedly connected with the second connecting columns 43;

the second support plate 38, the first fixing column 39 and the compression spring 40 are designed, so that the movable plate 8 is elastically connected with the shell 1, the compression spring 40 is in a compressed state, the compression spring 40 applies downward force to the movable plate 8, the movable plate 8 can be tightly attached to the cam 11, the electromagnet 36 is electrified, the electromagnet 36 applies upward magnetic force to the iron plate 37, the iron plate 37 and the movable plate 8 are further moved upwards, the iron plate 37 and the electromagnet 36 are magnetically attracted together, the distance between the movable plate 8 and the cam 11 is increased, the cam 11 is not contacted with the movable plate 8 when the cam 11 rotates, the third connection plate 42 is elastically connected with the first connection plate 7 through the design of the third connection plate 42, the second fixing column 43 and the tension spring 44, after the first support plate 6 is impacted and moved upwards, the filter plate 5 is moved into the fixed ring 4, the tension spring 44 is in a tension state, the impact block 9 is no longer contacted with the first support plate 6, and the tension spring 44 can drive the first support plate 6 to reset to an initial position, and further the filter plate 5 is moved to an air vent again.

Working principle: during operation, one of the first rotating shafts 10 can be driven to rotate through the design of the rotary driving mechanism, one of the first rotating shafts 10 can be driven to synchronously rotate through the worm 12 when the other first rotating shaft 10 rotates through the design of the gear meshing unit, so that the two cams 11 synchronously rotate, the movable plate 8 is driven to vertically move through the cams 11 when the cams 11 rotate, the impact block 9 impacts the first supporting plate 6, the first connecting plate 7 and the filter plate 5 are subjected to upward impact force, impurities on the filter plate 5 are enabled to shake down, the permeability inside and outside the shell 1 is increased, the inside of the shell 1 can be heated through the design of the heater 15, the air in the shell 1 is dried, electronic elements are prevented from being wetted, the second rotating shaft 13 can be enabled to synchronously rotate through the design of the synchronous transmission assembly when the worm 12 rotates, the fan blades 14 are further rotated to accelerate the air flow in the shell 1, the air flow in the shell 1 is heated uniformly, when the impurities on the filter plate 5 are not required to be cleaned, only the second rotating shaft 13 is required to be driven to rotate, the movable plate 8 is driven to move upwards by the magnetic absorber, the distance between the movable plate 8 and the cam 11 is increased, the cam 11 is not contacted with the movable plate 8 when the cam 11 rotates, the filter plate 5 can not shake any more, when the impurities on the filter plate 5 are not required to be cleaned, only the second rotating shaft 13 is driven to rotate when the worm 12 is only heated in the shell 1, the motor 33 drives the fourth sprocket 34 to rotate by the design of the rotary driving mechanism, and then the third sprocket 31 is driven to rotate by the second chain 35, so that the first rotating shaft 10 can rotate, the first rotating shaft 10 is stably rotated relative to the housing 1 through the design of the second fixing plate 25 and the third bearing 26, the worm 12 is stably rotated relative to the housing 1 through the design of the third fixing plate 29 and the fourth bearing 30, the second bevel gear 28 is driven to rotate through the first bevel gear 27 when one of the first rotating shafts 10 rotates through the design of the first bevel gear 27, the worm 12 is further rotated, the worm 12 is driven to rotate through the cooperation of the other group of the first bevel gear 27 and the second bevel gear 28, the other first rotating shaft 10 is further rotated through the cooperation of the other group of the first bevel gear 27 and the second bevel gear 28, so that the two cams 11 can be synchronously rotated, the second supporting plate 38, the first fixing post 39 and the compression spring 40 are designed, the movable plate 8 is elastically connected relative to the housing 1, the compression spring 40 is in a compressed state, the compression spring 40 applies downward force to the movable plate 8, the movable plate 8 can be tightly attached to the cam 11, the electromagnet 36 is electrified, the electromagnet 36 applies upward magnetic force to the iron plate 37, so that the iron plate 37 and the movable plate 8 move upwards, the iron plate 37 and the electromagnet 36 are magnetically attracted together, the distance between the movable plate 8 and the cam 11 is increased, the cam 11 cannot contact with the movable plate 8 when the cam 11 rotates, the third connecting plate 42, the second fixed column 43 and the tension spring 44 are designed, the third connecting plate 42 and the first connecting plate 7 are elastically connected relative to the shell 1, when the first supporting plate 6 is impacted and moved upwards, the filter plate 5 moves into the fixed ring 4, the tension spring 44 is in a tension state, the impact block 9 is not contacted with the first supporting plate 6 any more, the tension spring 44 can drive the first supporting plate 6 to reset to an initial position, and the filter plate 5 can be moved to an air vent again, when the worm 12 rotates, the worm wheel 21 is driven to rotate by the worm 12, the worm wheel 21 is further driven to rotate by the third rotating shaft 20, the second sprocket 23 is driven to rotate by the third rotating shaft 20, the first sprocket 19 is further driven to rotate by the first chain 24, the second rotating shaft 13 is further driven to rotate, and when the worm 12 rotates, the second rotating shaft 13 can be synchronously rotated.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

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

Claims

1. A monitoring collection system for carbon is sealed up to forsterite seals up carbon dioxide, includes casing (1) and carbon dioxide concentration collector (2), its characterized in that: the carbon dioxide concentration collector (2) is arranged on the shell (1), the bottom of the shell (1) is provided with a plurality of supporting blocks (3), the bottom inner wall of the shell (1) is provided with ventilation holes, the bottom inner wall of the shell (1) is fixedly connected with a fixed ring (4), the fixed ring (4) is matched with the ventilation holes, a filter plate (5) is arranged in the ventilation holes, a first supporting plate (6) is arranged in the shell (1), the filter plate (5) and the first supporting plate (6) are connected through two first connecting plates (7), the first connecting plates (7) and the shell (1) are connected through elastic stretching units, two movable plates (8) are arranged below the first supporting plate (6), the top of the movable plates (8) is fixedly connected with an impact block (9), the top of the movable plates (8) and the shell (1) are connected through elastic compression units, a magnetic absorber matched with the movable plates (8) is arranged on the inner wall of the shell (1), one side of the cam (11) is fixedly connected with a first rotating shaft (10), the first rotating shaft (10) and the first rotating shaft (1) is connected with the first rotating mechanism (1) through one rotating shaft (12), the worm (12) is connected with the shell (1) through a second rotating piece, the first rotating shaft (10) is connected with the worm (12) through a gear meshing unit, a second rotating shaft (13) is arranged above the first supporting plate (6), a plurality of fan blades (14) are arranged on the second rotating shaft (13), heaters (15) are arranged on the inner walls of the two sides of the shell (1), and the second rotating shaft (13) is connected with the worm (12) through a synchronous transmission assembly.

2. The monitoring and collecting device for carbon sequestration of forsterite according to claim 1, wherein: the synchronous transmission assembly comprises a first fixing plate (16) arranged below a second rotating shaft (13), the second rotating shaft (13) penetrates through the first fixing plate (16), a first bearing (17) is arranged at the penetrating position of the second rotating shaft (13) and the first fixing plate (16), the first fixing plate (16) is connected with the inner wall of the shell (1) through a second connecting plate (18), a third rotating shaft (20) is arranged in the shell (1), the bottom end of the third rotating shaft (20) is connected with the bottom inner wall of the shell (1) through a second bearing (22), a worm wheel (21) fixedly connected with the outer sleeve of the third rotating shaft (20) is meshed with the worm wheel (21), and the third rotating shaft (20) is connected with the second rotating shaft (13) through a transmission unit.

3. The monitoring and collecting device for carbon sequestration of forsterite according to claim 2, wherein: the transmission unit comprises a first sprocket (19) arranged at the bottom end of the second rotating shaft (13), the first sprocket (19) is fixedly connected with the second rotating shaft (13), the top end of the third rotating shaft (20) is fixedly connected with a second sprocket (23), and the first sprocket (19) is connected with the second sprocket (23) through a first chain (24).

4. The monitoring and collecting device for carbon sequestration of forsterite according to claim 1, wherein: the first rotating piece comprises a second fixing plate (25) arranged on one side of the first rotating shaft (10), the second fixing plate (25) is fixedly connected with the inner wall of the shell (1), the first rotating shaft (10) penetrates through the second fixing plate (25), and a third bearing (26) is arranged at the penetrating position of the first rotating shaft (10) and the second fixing plate (25).

5. The monitoring and collecting device for carbon sequestration of forsterite according to claim 1, wherein: the gear meshing unit comprises a first conical gear (27) arranged at one end, far away from the cam (11), of the first rotating shaft (10), the first conical gear (27) is fixedly connected with the first rotating shaft (10), the two ends of the worm (12) are fixedly connected with second conical gears (28), and the two first conical gears (27) are meshed with the two second conical gears (28) respectively.

6. The monitoring and collecting device for carbon sequestration of forsterite according to claim 1, wherein: the second rotating piece comprises third fixing plates (29) symmetrically arranged at two ends of the worm (12), the third fixing plates (29) are fixedly connected with the inner wall of the shell (1), the worm (12) penetrates through the two third fixing plates (29), and a fourth bearing (30) is arranged at the penetrating position of the worm (12) and the third fixing plates (29).

7. The monitoring and collecting device for carbon sequestration of forsterite according to claim 1, wherein: the rotary driving mechanism comprises a third sprocket (31) sleeved outside one of the first rotating shafts (10), the third sprocket (31) is fixedly connected with the first rotating shaft (10), a motor seat (32) is fixedly connected to the inner wall of one side of the shell (1), a motor (33) is arranged on one side of the motor seat (32), a fourth sprocket (34) is arranged at the output end of the motor (33), and the fourth sprocket (34) is connected with the third sprocket (31) through a second chain (35).

8. The monitoring and collecting device for carbon sequestration of forsterite according to claim 1, wherein: the magnetic absorber comprises electromagnets (36) symmetrically arranged on the inner walls of the two sides of the shell (1), the electromagnets (36) are fixedly connected with the inner walls of the shell (1), an iron plate (37) is arranged below the electromagnets (36), and the two iron plates (37) are fixedly connected with the two movable plates (8) respectively.

9. The monitoring and collecting device for carbon sequestration of forsterite according to claim 1, wherein: the elastic compression unit comprises a second supporting plate (38) arranged above the movable plate (8), the first supporting plate (6) is located between the second supporting plate (38) and the impact block (9), the second supporting plate (38) is fixedly connected with the inner wall of the shell (1), two first fixing columns (39) are fixedly connected to the top of the movable plate (8), the top ends of the first fixing columns (39) penetrate through the second supporting plate (38), compression springs (40) are sleeved outside the first fixing columns (39), and two ends of each compression spring (40) are fixedly connected with the second supporting plate (38) and the movable plate (8) respectively.

10. The monitoring and collecting device for carbon sequestration of forsterite according to claim 1, wherein: the elastic stretching unit comprises two third connecting plates (42) arranged below the first supporting plate (6), the two first connecting plates (7) penetrate through the two third connecting plates (42) respectively, the first connecting plates (7) are fixedly connected with the third connecting plates (42), two second fixing columns (43) are arranged below the third connecting plates (42), the bottom ends of the second fixing columns (43) are fixedly connected with the bottom inner wall of the shell (1), the second fixing columns (43) penetrate through the third connecting plates (42), stretching springs (44) are sleeved outside the second fixing columns (43), two ends of each stretching spring (44) are fixedly connected with the inner wall of the shell (1) and the inner wall of each third connecting plate (42), sealing rings (41) are sleeved outside the filter plates (5), and the sealing rings (41) are in contact with the inner walls of the corresponding ventilation holes.