CN115015478B

CN115015478B - Carbon emission monitoring equipment with diversified monitoring

Info

Publication number: CN115015478B
Application number: CN202210592747.5A
Authority: CN
Inventors: 陈军; 柏建华; 张瑞山; 芮文明; 刘杰; 冯林魁; 王平; 谢生璐; 刘吉祥; 冯垚飞; 卢可; 谷志德; 任艳男; 赵凯
Original assignee: Lanzhou Longneng Electic Power Science & Technology Co ltd
Current assignee: Lanzhou Longneng Electic Power Science & Technology Co ltd
Priority date: 2022-05-28
Filing date: 2022-05-28
Publication date: 2024-04-16
Anticipated expiration: 2042-05-28
Also published as: CN115015478A

Abstract

The application relates to the field of environmental monitoring and discloses carbon emission monitoring equipment with multi-azimuth monitoring, which comprises a plurality of monitors, wherein the monitoring equipment further comprises a cylindrical box, a driving device is arranged above the cylindrical box, the driving device comprises a mounting frame, a main shaft vertically rotating on the mounting frame, a middle frame arranged below the mounting frame, a spiral rod horizontally rotating on the middle frame, a first spiral gear and a second spiral gear which are arranged on two sides of the spiral rod and meshed with the spiral rod, the spiral gears are coaxially connected to the bottom of the main shaft, the second spiral gear is coaxially connected to a vertically arranged auxiliary shaft, the top of the cylindrical box is coaxially connected to the bottom of the auxiliary shaft, a first power component for driving the main shaft to rotate is arranged on the mounting frame, and a second power component for driving the auxiliary shaft to transversely move is arranged on the middle frame. The application realizes that the monitor can rotate 360 degrees, so that the monitor can monitor airflows in different directions in real time, and the monitoring accuracy of carbon emission is improved.

Description

Carbon emission monitoring equipment with diversified monitoring

Technical Field

The application relates to the field of environmental monitoring, in particular to carbon emission monitoring equipment with multidirectional monitoring.

Background

Carbon emissions are a generic term or short term for greenhouse gas emissions, and generally require monitoring and control of carbon emissions by monitoring equipment. Enterprises can monitor the discharged gas in real time through various types of gas monitoring equipment in the production process.

However, in the process of implementing the technical scheme in the embodiment of the application, the inventor discovers that at least the following technical problems exist: for more accurate monitoring carbon emission, can use a plurality of monitors to monitor the environment under the same space simultaneously, consequently can integrate a plurality of different grade type monitors on an equipment, and owing to have the air flow in the environment, and most monitors are fixed on a fixed position, and the monitor in different positions can produce the monitoring error because of the change of air current direction, consequently causes the carbon emission to monitor inaccurately.

Disclosure of Invention

The embodiment of the application solves the technical problem that the monitor in the prior art can generate monitoring errors due to the change of the airflow direction by providing the carbon emission monitoring equipment with multi-azimuth monitoring, and realizes the 360-degree rotation of the monitor, so that the monitor can monitor airflows in different directions in real time, and the monitoring accuracy of carbon emission is improved.

The embodiment of the application provides carbon emission monitoring equipment with multi-azimuth monitoring, which comprises a plurality of monitors, wherein the monitors also comprise a cylindrical box, the monitors are uniformly arranged along the circumferential surface of the cylindrical box, a driving device for driving the cylindrical box to rotate is arranged above the cylindrical box, the driving device comprises a mounting frame for mounting the monitors, a main shaft vertically and rotatably arranged on the mounting frame, a middle frame arranged below the mounting frame, a screw rod horizontally and rotatably arranged on the middle frame, a first screw gear and a second screw gear which are arranged on two sides of the screw rod and meshed with the screw rod, the screw gear is coaxially connected to the bottom of the main shaft, the second screw gear is coaxially connected to a secondary shaft which is vertically arranged, the top of the cylindrical box is coaxially connected to the bottom of the secondary shaft, a first power component for driving the main shaft to rotate is arranged on the mounting frame, and a second power component for driving the secondary shaft to horizontally move is arranged on the middle frame.

Further, the first power component comprises a first driving motor, a first synchronizing wheel, a second synchronizing wheel and a synchronous belt, wherein the first driving motor is installed on the installation frame, the output shaft of the first driving motor is vertically upwards, the first synchronizing wheel is coaxially connected to the output shaft of the first driving motor, the second synchronizing wheel is coaxially connected to the top end of the main shaft, and the synchronous belt is wound between the first synchronizing wheel and the second synchronizing wheel.

Further, the second power assembly comprises a guide bar horizontally fixedly connected to the middle frame, a moving block slidably arranged in the guide bar, and a screw rod rotatably arranged in the guide bar, the moving block is in threaded fit with the screw rod, a second driving motor for driving the screw rod to rotate is arranged at one end of the guide bar, and the auxiliary shaft is rotatably arranged on the moving block.

Furthermore, a dovetail groove is formed in the guide bar, a dovetail block matched with the dovetail groove is fixedly connected to the side wall of the moving block, and sealing plates are connected to the two ends of the guide bar through bolts.

Further, the middle frame is including the cover locate circle sleeve plate on the main shaft, level setting and integrated into one piece in horizontal pole on the circle sleeve plate edge, vertical rigid coupling in the riser at horizontal pole both ends, the hob rotates and sets up in both sides between the riser, the mounting bracket main shaft and be provided with between the circle sleeve plate and drive the rotatory power pack III of circle sleeve plate.

Further, the third power assembly comprises a shaft sleeve with an inner rotating ring nested on the main shaft, a worm wheel embedded on the outer rotating ring of the shaft sleeve, a connecting column fixedly connected between the worm wheel and the round sleeve plate, side plates symmetrically fixed on the mounting frame, and a worm arranged on two sides and between the side plates in a rotating mode, the worm is meshed with the worm wheel, and a driving motor third driving the worm to rotate is arranged on one side of the side plates.

Further, the mounting frame comprises a mounting plate which is horizontally arranged, and an adapter plate which is vertically and fixedly connected to the end face of one end of the mounting plate, wherein the adapter plate is used for being mounted at a position to be mounted, and the spindle is rotatably arranged at one end, away from the adapter plate, of the mounting plate.

Further, a supporting rib plate is fixedly connected between the bottom surface of the mounting plate and the adapter plate.

One or more technical solutions provided in the embodiments of the present application at least have the following technical effects or advantages:

1. Because the driving device is adopted, the first power component drives the main shaft to rotate, the main shaft drives the first spiral gear to rotate, the spiral gear drives the spiral rod to rotate, the spiral rod drives the second spiral gear to rotate, the second spiral gear drives the auxiliary shaft to rotate, and the auxiliary shaft drives the cylindrical box to rotate, so that various monitors can be driven to rotate around the auxiliary shaft axis, and the monitors can monitor air flows at different positions.

2. Due to the adoption of the driving assembly II, the driving motor II drives the screw rod to rotate, the screw rod drives the moving block to move, and the moving block drives the auxiliary shaft to move, so that the cylindrical box on the auxiliary shaft can move, and the monitoring range of the monitor on the cylindrical box can be further increased.

3. Because the driving component III is adopted, the driving motor III drives the worm to rotate, the worm drives the worm wheel to rotate, and the worm wheel drives the round sleeve plate to rotate, so that the middle frame can rotate around the main shaft, the cylindrical box can rotate around the main shaft, and the monitoring instrument on the cylindrical box can rotate around the main shaft while rotating around the auxiliary shaft, thereby further expanding the monitoring range.

Drawings

FIG. 1 is a schematic diagram of an overall structure of a carbon emission monitoring device with multi-directional monitoring in an embodiment of the present application;

FIG. 2 is a schematic diagram of the overall structure of a driving device according to an embodiment of the present application;

FIG. 3 is another view of FIG. 2, mainly illustrating a partial structure of the driving device;

FIG. 4 is a schematic structural view of a second power assembly according to an embodiment of the present application, mainly illustrating the internal structure of the guide bar;

FIG. 5 is a schematic diagram of an exploded view of a third power assembly in accordance with an embodiment of the present application;

In the figure: 100. a monitor; 1. a cylindrical box; 2. a driving device; 21. a mounting frame; 211. a mounting plate; 212. an adapter plate; 213. supporting rib plates; 22. a main shaft; 23. a middle frame; 231. a round sleeve plate; 232. a cross bar; 233. a riser; 24. a screw rod; 25. a first helical gear; 26. a spiral gear II; 27. a secondary shaft; 3. a first power assembly; 31. driving a first motor; 32. a first synchronous wheel; 33. a second synchronous wheel; 34. a synchronous belt; 4. a second power assembly; 41. a guide bar; 411. a dovetail groove; 412. a sealing plate; 42. a moving block; 421. dovetail blocks; 43. a screw rod; 44. a second driving motor; 5. a third power assembly; 51. a shaft sleeve; 52. a worm wheel; 53. a connecting column; 54. a side plate; 55. a worm; 56. and driving a motor III.

Detailed Description

The embodiment of the application discloses carbon emission monitoring equipment with multi-azimuth monitoring, which is characterized in that a main shaft 22 is driven to rotate by a power component I3, a spiral gear I25 is driven to rotate by the main shaft 22, a spiral rod 24 is driven to rotate by the spiral gear I25, a spiral gear II 26 is driven to rotate by the spiral gear II 26, a counter shaft 27 is driven to rotate by the counter shaft 27, various monitors 100 can be driven to rotate around the axis of the counter shaft 27, the cylindrical box 1 can be horizontally moved by a power component II 4, the monitoring range of the monitors 100 can be further increased, and in addition, the cylindrical box 1 can be driven to rotate around the main shaft 22 by a power component III 5, so that the cylindrical box 1 can also rotate around the circumference of the main shaft 22 while rotating, the monitoring of airflows in different directions and at different positions is further enlarged, and the monitoring accuracy of carbon emission is improved.

In order to better understand the above technical solutions, the following detailed description will refer to the accompanying drawings and specific embodiments.

Referring to fig. 1, a carbon emission monitoring device with diversified monitoring includes a cylindrical box 1, a driving device 2 and a monitor 100, the cylindrical box 1 is cylindrical, the monitor 100 is provided with a plurality of kinds, the plurality of kinds of monitors 100 are all installed on the outer peripheral surface of the cylindrical box 1 and evenly distributed along a circumference of the cylindrical box 1, and the driving device 2 is used for driving the cylindrical box 1 to rotate.

Referring to fig. 1, 2 and 3, the driving device 2 includes a mounting bracket 21, a main shaft 22, an intermediate bracket 23, a screw rod 24, a screw gear one 25, a screw gear two 26 and a sub shaft 27. The mounting frame 21 includes a mounting plate 211, an adapter plate 212, and a support rib 213; the mounting plate 211 is a strip-shaped plate and is horizontally arranged, the adapter plate 212 is a square plate, the adapter plate 212 is vertically welded to the end face of one end of the mounting plate 211, the mounting plate 211 penetrates through the middle of the adapter plate 212, and the adapter plate 212 is used for being mounted to the mounting position of the carbon emission monitoring equipment to be monitored through bolts; the supporting rib plates 213 are right triangle, and two straight edges of the supporting rib plates 213 are welded on the side wall of the adapter plate 212 and the bottom surface of the mounting plate 211 respectively.

Referring to fig. 2 and 3, the spindle 22 is vertically rotatably disposed at an end of the mounting plate 211 remote from the end of the adapter plate 212, and the mounting frame 21 is further provided with a first power assembly 3 for driving the spindle 22 to rotate. The first power component 3 comprises a first driving motor 31, a first synchronous wheel 32, a second synchronous wheel 33 and a synchronous belt 34; the first driving motor 31 is arranged on the top surface of the mounting plate 211, the driving motor is positioned between the adapter plate 212 and the main shaft 22, and the output shaft of the first driving motor 31 is vertically upwards; the first synchronous wheel 32 is coaxially connected to the output shaft of the first driving motor 31; the second synchronizing wheel 33 is coaxially connected to the top end of the main shaft 22; the synchronous belt 34 is wound between the first synchronous wheel 32 and the second synchronous wheel 33. The first driving motor 31 is started to drive the first synchronizing wheel 32 to rotate, the second synchronizing wheel 33 is driven to synchronously rotate under the action of the synchronous belt 34, and the second synchronizing wheel 33 drives the main shaft 22 to rotate.

With continued reference to fig. 2 and 3, the intermediate frame 23 includes a circular sheathing plate 231, a cross bar 232, and a riser 233. The circular sleeve plate 231 is sleeved on the main shaft 22, and the circular sleeve plate 231 is positioned below the mounting plate 211; the cross bar 232 is in a horizontal shape, and the middle part of the cross bar 232 and the edge of the round sleeve plate 231 are integrally formed; the number of the vertical plates 233 is two, the two vertical plates 233 are fixedly connected to two ends of the cross bar 232 respectively, and the vertical plates 233 are vertically downward. The screw 24 is rotatably provided between the risers 233 on both sides. The first spiral gear 25 and the second spiral gear 26 are respectively located at two sides of the spiral rod 24 and meshed with the spiral rod 24, the first spiral gear 25 is coaxially connected to the bottom of the main shaft 22, and the first spiral gear 25 is located below the circular sleeve plate 231. The auxiliary shaft 27 is vertically arranged and coaxially connected to the second spiral gear 26, the top of the cylindrical box 1 is coaxially connected to the bottom of the auxiliary shaft 27, and the intermediate frame 23 is provided with the second power assembly 4 for driving the auxiliary shaft 27 to transversely move.

The first power component 3 drives the main shaft 22 to rotate, the main shaft 22 drives the first spiral gear 25 to rotate, the first spiral gear 25 drives the spiral rod 24 to rotate, the spiral rod 24 drives the second spiral gear 26 to rotate, the second spiral gear 26 drives the auxiliary shaft 27 to rotate, and the auxiliary shaft 27 drives the cylindrical box 1 to rotate, so that various monitors 100 can be driven to rotate around the axis of the auxiliary shaft 27, and the various monitors 100 can monitor airflows at different positions.

Referring to fig. 2 and 4, the second power assembly 4 includes a guide bar 41, a moving block 42, a screw 43, and a second driving motor 44. The guide strip 41 is horizontal, the length direction of the guide strip 41 is consistent with the length direction of the screw rod 24, the guide strip 41 is fixedly connected between the side edges of the vertical plates 233 at the two sides, which are far away from the circular plate, dovetail slots 411 are formed in the guide strip 41, and sealing plates 412 are connected at the two ends of the guide strip 41 through bolts; the moving block 42 is positioned at one side of the guide bar 41 far away from the screw rod 24, and a dovetail block 421 matched with the dovetail slot 411 is fixedly connected on the side wall of the moving block 42; the screw rod 43 is rotatably arranged between the two side sealing plates 412, and the dovetail block 421 is in threaded connection with the screw rod 43; the second driving motor 44 is mounted on the outer side wall of the one end sealing plate 412, and the second driving motor 44 drives the screw 43 to rotate.

The second driving motor 44 is started, the second driving motor 44 drives the screw rod 43 to rotate, the screw rod 43 drives the moving block 42 to move, and the moving block 42 drives the auxiliary shaft 27 to move, so that the cylindrical box 1 on the auxiliary shaft 27 can move, and the monitoring range of the monitor 100 on the cylindrical box 1 can be further increased.

Referring to fig. 5, a third power assembly 5 for driving the circular sleeve plate 231 to rotate is provided between the mounting frame 21, the main shaft 22 and the circular sleeve plate 231. The third power assembly 5 includes a sleeve 51, a worm gear 52, a connecting post 53, a side plate 54, a worm 55, and a third drive motor 56. The inner rotating ring of the shaft sleeve 51 is nested on the main shaft 22, and the shaft sleeve 51 is positioned between the mounting plate 211 and the round sleeve plate 231; the worm gear 52 is embedded on the outer rotating ring of the shaft sleeve 51; the connecting columns 53 are fixedly connected between the worm wheel 52 and the round sleeve plate 231, and the connecting columns 53 are provided with a plurality of connecting columns and are uniformly distributed along the circumference of the main shaft 22; the two side plates 54 are symmetrically arranged and welded on the side wall of the mounting plate 211; the worm 55 is rotatably arranged between the side plates 54 on both sides; the third driving motor 56 is installed on the side plate 54 at one side, and the output shaft of the third driving motor 56 is coaxially connected with the worm 55.

The driving motor III 56 is started, the driving motor III 56 drives the worm 55 to rotate, the worm 55 drives the worm wheel 52 to rotate, and the worm wheel 52 drives the circular sleeve plate 231 to rotate, so that the middle frame 23 can rotate around the main shaft 22, the cylindrical box 1 can rotate around the main shaft 22, and the monitoring range is further enlarged when the monitor 100 on the cylindrical box 1 rotates around the auxiliary shaft 27 and also can rotate around the main shaft 22.

The application can explain its functional principle by the following modes of operation:

An operator can uniformly install various monitors 100 on the cylindrical box 1 along the circumference of the cylindrical box 1, then coaxially connect the cylindrical box 1 to the bottom of the auxiliary shaft 27, and then install the adapter plate 212 on the mounting frame 21 at the installation position of the carbon emission monitoring device to be installed, and ensure that the lower part of the installation position is clear. Then, the main shaft 22 is driven to rotate through the first power component 3, the main shaft 22 drives the first spiral gear 25 to rotate, the first spiral gear 25 drives the spiral rod 24 to rotate, the spiral rod 24 drives the second spiral gear 26 to rotate, the second spiral gear 26 drives the auxiliary shaft 27 to rotate, the auxiliary shaft 27 drives the cylindrical box 1 to rotate, and accordingly various monitors 100 can be driven to rotate around the axis of the auxiliary shaft 27, the second power component 4 can enable the cylindrical box 1 to horizontally move, the monitoring range of the monitors 100 can be further increased, in addition, the third power component 5 can also drive the cylindrical box 1 to rotate around the main shaft 22, and accordingly the cylindrical box 1 rotates around the circumference of the main shaft 22 while rotating, air flows in different directions and at different positions are further expanded to be monitored, and the monitoring accuracy of carbon emission is improved.

The foregoing is only a preferred embodiment of the present application, but the scope of the present application is not limited thereto, and any person skilled in the art should be able to apply equivalents and modifications according to the technical scheme and the concept of the present application within the scope of the present application.

Claims

1. The utility model provides a carbon emission monitoring equipment with diversified monitoring, includes a plurality of monitor (100), its characterized in that, monitor still includes cylinder box (1), a plurality of monitor (100) are followed cylinder box (1) global even installation, the top of cylinder box (1) is provided with and drives drive arrangement (2) of cylinder box (1) rotation, drive arrangement (2) including be used for installing monitor's mounting bracket (21), vertical rotation set up in main shaft (22) on mounting bracket (21), be located intermediate frame (23) of mounting bracket (21) below, horizontal rotation set up in screw rod (24) on intermediate frame (23), be located screw rod (24) both sides and with screw gear (25) and screw gear two (26) of screw rod (24) meshing, screw gear one (25) coaxial coupling in the bottom of main shaft (22), coaxial coupling is in countershaft (27) on screw gear two (26), cylinder box (1) top coaxial coupling in the bottom of countershaft (27) is provided with power pack (21) is provided with on the main shaft (21), the middle frame (23) is provided with a second power assembly (4) for driving the auxiliary shaft (27) to transversely move;

The middle frame (23) comprises a round sleeve plate (231) sleeved on the main shaft (22), a cross rod (232) horizontally arranged and integrally formed on the edge of the round sleeve plate (231), vertical plates (233) vertically fixedly connected to two ends of the cross rod (232), screw rods (24) are rotatably arranged between the vertical plates (233) at two sides, and a power assembly III (5) for driving the round sleeve plate (231) to rotate is arranged between the mounting frame (21), the main shaft (22) and the round sleeve plate (231);

The power assembly III (5) comprises a shaft sleeve (51) with an inner rotating ring nested on the main shaft (22), a worm wheel (52) embedded on an outer rotating ring of the shaft sleeve (51), a connecting column (53) fixedly connected between the worm wheel (52) and a round sleeve plate (231), side plates (54) symmetrically fixed on the mounting frame (21), and a worm (55) rotatably arranged at two sides between the side plates (54), wherein the worm (55) is meshed with the worm wheel (52), and a driving motor III (56) for driving the worm (55) to rotate is arranged on one side of the side plate (54).

2. A carbon emission monitoring device with multi-azimuth monitoring according to claim 1, characterized in that the first power assembly (3) comprises a first driving motor (31) installed on the installation frame (21) and with an output shaft vertically upwards, a first synchronizing wheel (32) coaxially connected to the output shaft of the first driving motor (31), a second synchronizing wheel (33) coaxially connected to the top end of the main shaft (22), and a synchronous belt (34) wound between the first synchronizing wheel (32) and the second synchronizing wheel (33).

3. A carbon emission monitoring device with multi-azimuth monitoring as claimed in claim 1, wherein the second power component (4) comprises a guide bar (41) horizontally fixedly connected to the middle frame (23), a moving block (42) slidingly arranged in the guide bar (41), a screw rod (43) rotatably arranged in the guide bar (41), the moving block (42) is in threaded fit with the screw rod (43), one end of the guide bar (41) is provided with a second driving motor (44) for driving the screw rod (43) to rotate, and the auxiliary shaft (27) is rotatably arranged on the moving block (42).

4. A carbon emission monitoring device with multi-azimuth monitoring as claimed in claim 3, wherein a dovetail groove (411) is formed in the guide bar (41), a dovetail block (421) matched with the dovetail groove (411) is fixedly connected to the side wall of the moving block (42), and sealing plates (412) are connected to the two ends of the guide bar (41) through bolts.

5. The carbon emission monitoring device with multi-azimuth monitoring according to claim 1, wherein the mounting frame (21) comprises a mounting plate (211) horizontally arranged and an adapter plate (212) vertically fixedly connected to an end face of one end of the mounting plate (211), the adapter plate (212) is used for being mounted at a position to be mounted, and the spindle (22) is rotatably arranged at one end, far away from the adapter plate (212), of the mounting plate (211).

6. The carbon emission monitoring device with multi-azimuth monitoring according to claim 5, wherein a supporting rib plate (213) is fixedly connected between the bottom surface of the mounting plate (211) and the adapter plate (212).