CN117554563B

CN117554563B - Carbon emission measurement data acquisition device and acquisition method

Info

Publication number: CN117554563B
Application number: CN202311505840.9A
Authority: CN
Inventors: 王清; 李贵民; 夏晓东; 荆臻; 张志�; 王平欣; 李琮琮; 朱红霞; 张峰; 张义龙; 朱元元
Original assignee: Nanjing Xinda Electronic Equipment Co ltd; State Grid Shandong Electric Power Co Ltd; Marketing Service Center of State Grid Shandong Electric Power Co Ltd
Current assignee: Nanjing Xinda Electronic Equipment Co ltd; State Grid Shandong Electric Power Co Ltd; Marketing Service Center of State Grid Shandong Electric Power Co Ltd
Priority date: 2023-11-13
Filing date: 2023-11-13
Publication date: 2024-03-26
Anticipated expiration: 2043-11-13
Also published as: CN117554563A

Abstract

A carbon emission measurement data acquisition device and an acquisition method belong to the field of carbon emission acquisition equipment. The pipeline I and the pipeline III are fixedly connected to the upper end of the bracket, and the pipeline II is positioned between the pipeline I and the pipeline III; the lower part of one side of the pipe I is fixedly connected with a fixed shaft; the inner wall of the pipe II is fixedly connected with two fixed clapboards and a carbon emission measuring instrument positioned between the fixed clapboards, and a movable baffle plate sleeved on the fixed shaft through a bearing is also arranged between the two fixed clapboards; a tooth slot is arranged on the inner wall of one side of the pipe II away from the pipe I; the lower end of the pipeline III is fixedly connected with a motor, and the transmission assembly is meshed with the tooth slot. When the device is used, the device is only required to be placed in a region to be tested to collect sample data by oneself, and after collection, workers collect the device, so that the labor is saved, and meanwhile, when the device is in operation, moisture can be reduced from entering the device, and the influence on the service life of electronic elements in the device is reduced.

Description

Carbon emission measurement data acquisition device and acquisition method

Technical Field

The invention relates to a carbon emission measurement data acquisition device and an acquisition method, and belongs to the field of carbon emission acquisition equipment.

Background

The method for detecting the carbon emission comprises the following steps: direct measurement: carbon emissions are determined by in-situ measurements of the emissions sources, but require the use of specialized measurement equipment.

And (3) counting: the carbon emission is estimated by carrying out statistical analysis on production, consumption, transportation and other data of the emission source, and the method is suitable for large-scale emission sources.

In addition, there are also on-line actual measurement method, satellite remote sensing monitoring method, etc

When the direct measurement method is used, a carbon emission measuring instrument is required to be used, and the obtained data error is small; when the instrument is used, the working environment is complex, and a plurality of sample data are required to be collected at intervals, so that a large amount of manpower is required to be consumed, and therefore, improvement is needed.

Disclosure of Invention

The invention aims to solve the problems in the background art and provides a carbon emission measurement data acquisition device and an acquisition method.

The invention achieves the above purpose, adopts the following technical scheme:

a carbon emission measurement data acquisition device comprises a pipeline I, a bracket, a pipeline II and a pipeline III; the pipeline I and the pipeline III are fixedly connected to the upper end of the bracket, and the pipeline II is positioned between the pipeline I and the pipeline III; the pipeline I comprises a pipe I; the lower part of one side of the pipe I is fixedly connected with a fixed shaft, and a connecting rod is sleeved on the fixed shaft; the connecting rod is fixedly connected to the inner wall of a pipe II on the pipeline II; the inner wall of the pipe II is fixedly connected with two fixed clapboards and a carbon emission measuring instrument positioned between the fixed clapboards, and a movable baffle plate sleeved on the fixed shaft through a bearing is arranged between the two fixed clapboards; a tooth slot is arranged on the inner wall of one side of the pipe II away from the pipe I; the lower end of the pipeline III is fixedly connected with a motor, and an output shaft of the motor is connected with an input shaft of the transmission; the transmission assembly is connected with an output shaft of the transmission in a key way and meshed with the tooth groove; and the connecting part of the pipeline I, the pipeline III and the pipeline II is fixedly connected with a side plate.

A method of collecting a carbon emission measurement data collection device, the method comprising the steps of:

step one: starting a motor, driving a transmission assembly to rotate by the motor, further driving a pipe II to rotate, and driving a carbon emission measuring instrument to be separated from a fixed partition plate and communicated with the outside by the pipe II to measure;

step two: the transmission component also drives the fan blade to rotate, so that air in the pipe I, the pipe II and the pipe III circulate, and the service life of the equipment is prevented from being influenced by moisture;

step three: when raining, the water tank drives the baffle to seal the pipe I and the pipe III, so that rainwater is prevented from entering the inside of the pipe I and the pipe III.

Compared with the prior art, the invention has the beneficial effects that: when the device is used, the device is only required to be placed in a region to be tested to collect sample data by oneself, and after collection, workers collect the device, so that the labor is saved, and meanwhile, when the device is in operation, moisture can be reduced from entering the device, and the influence on the service life of electronic elements in the device is reduced.

Drawings

FIG. 1 is a front view of a carbon emission measurement data collection device of the present invention;

FIG. 2 is a front view of a storage device of a carbon emission measurement data acquisition device of the present invention;

FIG. 3 is a front view of a conduit I of a carbon emission measurement data acquisition device of the present invention;

FIG. 4 is a front view of a conduit II of a carbon emission measurement data acquisition device of the present invention;

FIG. 5 is a front view of a tube II of the carbon emission measurement data acquisition device of the present invention;

FIG. 6 is a schematic side view of a tube II of the carbon emission measurement data acquisition device of the present invention;

FIG. 7 is a schematic illustration of the position of a flapper of a carbon emission measurement data collection device of the present invention;

FIG. 8 is a schematic view of a stop collar of a carbon emission measurement data acquisition device according to the present invention;

FIG. 9 is a schematic diagram of the transmission assembly of a carbon emission measurement data acquisition device according to the present invention;

FIG. 10 is a front view of a gear of a carbon emission measurement data acquisition device of the present invention;

FIG. 11 is a schematic side view of a gear of a carbon emission measurement data acquisition device of the present invention;

FIG. 12 is a front view of a drive wheel of a carbon emission measurement data acquisition device of the present invention;

FIG. 13 is a schematic side view of a drive wheel of a carbon emission measurement data acquisition device of the present invention;

FIG. 14 is a front view of a conduit III of a carbon emission measurement data acquisition device of the present invention;

fig. 15 is a schematic side view of a pipe iii of a carbon emission measurement data collection device according to the present invention.

Detailed Description

The technical solutions 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 only some embodiments of the invention, but not all embodiments, and all other embodiments obtained by those skilled in the art without making creative efforts based on the embodiments of the present invention are all within the protection scope of the present invention.

The first embodiment is as follows: as shown in fig. 1-15, this embodiment describes a carbon emission measurement data acquisition device including a pipe i 2, a bracket 3, a pipe ii 4, and a pipe iii 5; the pipeline I2 and the pipeline III 5 are fixedly connected to the upper end of the bracket 3, and the pipeline II 4 is positioned between the pipeline I2 and the pipeline III 5; the pipeline I2 comprises a pipe I21; the lower part of one side of the pipe I21 is fixedly connected with a fixed shaft 22, and a connecting rod 23 is sleeved on the fixed shaft 22; the connecting rod 23 is fixedly connected to the inner wall of a pipe II 41 on the pipeline II 4; the inner wall of the pipe II 41 is fixedly connected with two fixed partition boards 44 and a carbon emission measuring instrument 45 positioned between the fixed partition boards 44, and a movable baffle 410 sleeved on the fixed shaft 22 through a bearing is also arranged between the two fixed partition boards 44; a tooth slot 42 is arranged on the inner wall of one side of the pipe II 41 away from the pipe I21; the lower end of the pipeline III 5 is fixedly connected with a motor 47, and an output shaft of the motor 47 is connected with an input shaft of a transmission 48; the output shaft of the speed changer 48 is connected with a transmission assembly 49 by a key, and the transmission assembly 49 is meshed with the tooth groove 42; the connection part of the pipeline I2, the pipeline III 5 and the pipeline II 4 is fixedly connected with a side plate 43. The fixed shaft 22 is in interference fit with the connecting rod 23, so that the tube II 41 cannot rotate after being pushed by the sliding block 4913.

The central axis of the spline 42 is located below the central axis of the tube II 41, and the cross section of the spline 42 is tangential to the cross section of the tube II 41 at a position away from the carbon emission measuring instrument 45.

The transmission assembly 49 includes a gear 491; the gear 491 includes a gear body 4911; the gear body 4911 is connected with an output shaft of the transmission 48, a groove 4912 is arranged on the top circle of one tooth of the gear body 4911, and a sliding block 4913 in sliding fit with the groove 4912 is arranged in the groove; a spring 4914 is fixedly connected between the sliding block 4913 and the groove 4912; when the carbon emission measuring instrument 45 is closest to the gear body 4911, the sliding block 4913 on the gear body 4911 is matched with the tooth groove 42 and drives the tube II 41 to rotate, the distance between the gear body 4911 and the tooth groove 42 is gradually shortened in the process of rotation of the tube II 41, and finally the gear body 4911 is meshed with the tooth groove 42, so that the carbon emission measuring instrument 45 intermittently measures data, the carbon emission measuring instrument 45 is prevented from being exposed to the environment in contact with the outside for a long time, and the service life of the carbon emission measuring instrument 45 is reduced.

The drive assembly 49 also includes a drive wheel 492; the driving wheel 492 comprises a circular ring 4921, a fixing rod 4922 and a shaft 54; one end of the shaft 54 is connected to a support assembly fixed on the inner wall of the tube III 51, and the shaft 54 is fixedly connected with a fan blade 56; the other end of the shaft lever 54 is fixedly connected with a fixing rod 4922; the other end of the fixing rod 4922 is fixedly connected with a circular ring 4921; the outer circumferential surface of the circular ring 4921 is provided with a groove body meshed with the gear body 4911. The gear body 4911 also drives the fan blade 56 to rotate in the rotating process, so that the air flow in the device is increased, the accuracy of a measurement result is ensured, and meanwhile, the moisture in the device is reduced.

A connecting ring 4923 is fixedly connected to one side of the circular ring 4921 far away from the shaft rod 54, a rotating ring 4924 is connected to the outer circular surface of the connecting ring 4923 through a bearing, and a limiting rod 4925 is fixedly connected to the bottom end of the outer circular surface of the rotating ring 4924; a round rod 4915 is inserted into the center of the side surface of the gear body 4911 through a bearing; the limiting rod 4925 vertically penetrates through the round rod 4915; a limiting ring 411 is fixedly connected to the inner wall of the pipe II 41; the limiting ring 411 comprises an arc rod I fixedly connected to the inner wall of the pipe II 41 and having the same inner diameter as the arc rod I, and an arc rod II fixedly connected with the arc rod I, wherein the protruding direction faces to the direction of the circle center of the arc rod I; and the limiting rod 4925 is contacted with the inner walls of the arc-shaped rods I and II. The carbon emission measuring instrument 45 reduces air flow during measurement and ensures accuracy of measurement results.

A supporting rod 57 is fixedly connected to the inner wall of the pipe III 51; the top end of the supporting rod 57 is rotatably connected with a bidirectional elastic telescopic rod 58, one end of the bidirectional elastic telescopic rod 58 is connected with the supporting component, and the other end of the bidirectional elastic telescopic rod 58 is connected with the sliding rod 53; the outer side of the sliding rod 53 is provided with a sleeve 52 in sliding fit with the sliding rod; the sleeve 52 penetrates the top wall of the tube III 51; the support assembly comprises an elastic telescopic rod I55; the fixed end of the elastic telescopic rod I55 is fixedly connected to the inner wall of the pipe III 51, and the free end of the elastic telescopic rod I55 is connected with the bidirectional elastic telescopic rod 58.

Also comprises a storage device 1; the storage device 1 comprises a water tank 11, a water outlet pipe 12, an elastic telescopic rod II 13 and a baffle 14; the fixed end of the elastic telescopic rod II 13 is fixedly connected to the upper ends of the pipe I21 and the pipe III 51, and the upper part of the free end of the elastic telescopic rod II 13 is fixedly connected with the water tank 11; the bottom end of the water tank 11 is provided with a perforation above the sleeve 52, and the water outlet pipe 12 is fixedly connected above the perforation; baffle plates 14 are fixedly connected to two sides of the bottom end of the water tank 11.

The outer wall of the pipe II 41 is fixedly connected with a convex block 46.

When the water tank 11 stores rainwater and the carbon emission measuring instrument 45 rotates to the upper side along with the pipe II 41, the bump 46 jacks up the water tank 11, so that the water tank 11 drives the baffle 14 to move upwards, and the pipe I21 and the pipe III 51 are communicated with the outside.

step one: starting the motor 47, driving the transmission assembly 49 to rotate by the motor 47, further driving the pipe II 41 to rotate, and driving the carbon emission measuring instrument 45 to be separated from the fixed partition 44 and communicated with the outside by the pipe II 41 to perform measurement;

step two: the transmission assembly 49 also drives the fan blade 56 to rotate, so that air in the pipe I21, the pipe II 41 and the pipe III 51 circulates, and the influence of moisture on the service life of the equipment is avoided;

step three: when raining, the water tank 11 drives the baffle 14 to seal the pipe I21 and the pipe III 51, so that rainwater is prevented from entering the inside of the pipe I21 and the pipe III.

The working principle of the invention is as follows: when the device is used, the bracket 3 is placed in a region to be tested, then the motor 47 is started, the motor 47 drives the gear body 4911 to rotate through the transmission 48, the gear body 4911 drives the tube II 41 to rotate through the tooth groove 42 in the process of rotating the gear body 4911, the tube II 41 and the tooth groove 42 rotate, the tube II 21 and the tooth groove 42 are not coaxial, the gear body 4911 is tangential to the tube II 41, the situation that the gear body 4911 is not contacted with the tooth groove 42 can occur in the process of rotating the gear body 4911, the sliding block 4913 is driven to rotate together in the process of rotating the gear body 4911, the sliding block 4913 is in sliding fit with the tooth groove 42, so when the carbon emission measuring instrument 45 is in the closest distance with the gear body 4911 (namely in the state shown in figure 1), the sliding block 4913 on the gear body 4911 is matched with the tooth groove 42 and drives the tube II 41 to rotate, the distance between the gear body 4911 and the tooth groove 42 is gradually shortened in the process of rotating the tube II 41, finally, the gear body 4911 is meshed with the tooth groove 42 and drives the tube II 41 to rotate, when the sliding block 4913 is matched with the tooth groove 42, the gear body 4911 rotates for one circle, the tube II 41 rotates, and then the carbon emission measuring instrument 45 fixed on the inner wall of the tube II 41 rotates along with the rotation, when the carbon emission measuring instrument 45 rotates to be contacted with the movable baffle 410, the movable baffle 410 is pushed to rotate along with the fixed shaft 22, the carbon emission measuring instrument 45 is communicated with the outside for measurement, and simultaneously the gear body 4911 is meshed with the tooth groove 42, so that the gear body 4911 drives the tube II 21 to rotate through the tooth groove 42, the rotation speed of the tube II 21 is accelerated, the outdoor time of the carbon emission measuring instrument 45 is shortened, when the carbon emission measuring instrument 45 rotates to a position of the gear body 4911 which is separated from the tooth groove 42, the carbon emission measuring instrument 45 is between the fixed partitions 44 that are moved again, and the movable barrier 410 seals the carbon emission measuring instrument 45 between the fixed partitions 44 from moisture;

in the process of rotating the gear body 4911, the gear body 4911 is meshed with the circular ring 4921 to drive the circular ring 4921 to rotate, the circular ring 4921 drives the fixed rod 4922 and the shaft rod 54 to rotate, and then drives the fan blade 56 to rotate, so that air in the pipeline I2, the pipeline II 4 and the pipeline III 5 is driven to flow, the outside air can enter the device, the measurement result of the carbon emission measuring instrument 45 is more accurate, inaccurate measurement result caused by no flow of air in the device is avoided, and meanwhile, moisture in the device is reduced;

meanwhile, the connecting ring 4923 is driven to rotate in the rotating process of the circular ring 4921, because the gear body 4911 rotates to drive the pipe II 41 to rotate, the limiting ring 411 fixedly connected to the inner wall of the pipe II 41 also rotates along with the pipe II, when the carbon emission measuring instrument 45 is positioned in a space between the two fixed partition plates 44 and the movable baffle 410, the limiting rod 4925 is contacted with the inner wall of the arc rod I on the limiting ring 411, when the carbon emission measuring instrument 45 is communicated with the outside, the limiting rod 4925 is contacted with the inner wall of the arc rod II on the limiting ring 411, as the arc rod II protrudes towards the center of the arc rod I, when the limiting rod 4925 is contacted with the inner wall of the arc rod II, the limiting rod 4925 pushes the limiting rod 4925 to move upwards, the limiting rod 4924, the connecting ring 4923 and the circular ring 4921 together, the connecting ring 4923 drives the fixing rod 4922 and the shaft rod 54 to move upwards, the free end of the elastic telescopic rod I55 moves upwards, after the circular ring 4921 is separated from the gear body 491, the circular ring 4921 is prevented from rotating, and when the two blades 4921 are not rotated, and the carbon emission measuring instrument is prevented from being meshed with the inner wall of the arc rod 4945, and the detecting blade 45 is prevented from being rotated again, and the detecting the space between the two measuring instruments is not to be meshed with the arc rod 4945 when the inner wall of the fixed ring 45 is rotated, and the measuring instrument is not rotated;

when rainy days are met, rainwater falls into the water tank 11, part of rainwater passes through the water outlet pipe 12 and falls into the sleeve 52, the water tank 11 moves downwards along with the increase of water quantity, the elastic telescopic rod II 13 is compressed, the baffle 14 shields the pipe I21 and the pipe III 51, rainwater is reduced, meanwhile, after the water quantity in the sleeve 52 is increased, the sliding rod 53 is driven to slide downwards, the free end of the elastic telescopic rod I55 is driven to move upwards through the bidirectional elastic telescopic rod 58, the shaft rod 54 is further driven to move upwards, the ring 4921 is driven by the shaft rod 54 to be separated from the gear body 4911, rotation is not generated any more, and the fan blade 56 is prevented from rotating any more, so that the fan blade 56 drives air to flow, and more moisture in the air in the rainy days is prevented from entering the device;

when the water level in the water tank 11 is higher than the water outlet pipe 12, water can be discharged through the water outlet pipe 12, so that excessive water stored in the water tank 11 is avoided;

after sunny days, rainwater evaporates, the water tank 11 moves to the original position under the action of the elastic telescopic rod II 13, and then the baffle 14 is driven to move to the original position, and along with the evaporation of water in the sleeve 52, the elastic telescopic rod I55 drives the shaft rod 54 to move to the original position, so that the fan blades 56 continue to rotate;

when the carbon emission measuring instrument 45 is communicated with the outside in a rainy day, as the convex block 46 is fixedly connected to the outer circular surface of the pipe II 41, when the convex block 46 contacts with the lower end surface of the water tank 11 which moves downwards under the gravity, the convex block 46 can push the water tank 11 and rainwater in the water tank to move upwards, so that part of gaps between the baffle 14 and the pipes I21 and III 51 leak out, the carbon emission measuring instrument 45 can detect the gaps, and the rainwater is prevented from falling into the pipes I21 and III 51 due to overlarge gaps.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims

1. The utility model provides a carbon emission measures and calculates data acquisition device which characterized in that: comprises a pipeline I (2), a bracket (3), a pipeline II (4) and a pipeline III (5); the pipeline I (2) and the pipeline III (5) are fixedly connected to the upper end of the bracket (3), and the pipeline II (4) is positioned between the pipeline I (2) and the pipeline III (5); the pipeline I (2) comprises a pipe I (21); a fixed shaft (22) is fixedly connected to the lower part of one side of the pipe I (21), and a connecting rod (23) is sleeved on the fixed shaft (22); the connecting rod (23) is fixedly connected to the inner wall of a pipe II (41) on the pipeline II (4); the inner wall of the pipe II (41) is fixedly connected with two fixed clapboards (44) and a carbon emission measuring instrument (45) positioned between the fixed clapboards (44), and a movable baffle (410) sleeved on the fixed shaft (22) through a bearing is also arranged between the two fixed clapboards (44); a tooth slot (42) is arranged on the inner wall of one side of the pipe II (41) far away from the pipe I (21); the lower end of the pipeline III (5) is fixedly connected with a motor (47), and an output shaft of the motor (47) is connected with an input shaft of a transmission (48); a transmission assembly (49) is connected to an output shaft of the speed changer (48) in a key way, and the transmission assembly (49) is meshed with the tooth groove (42); the connection parts of the pipeline I (2), the pipeline III (5) and the pipeline II (4) are fixedly connected with side plates (43);

the central axis of the tooth groove (42) is positioned below the central axis of the pipe II (41), and the section of the tooth groove (42) is tangential to the section of the pipe II (41) at a position far away from the carbon emission measuring instrument (45);

the transmission assembly (49) comprises a gear (491); the gear (491) comprises a gear body (4911); the gear body (4911) is connected with an output shaft of the transmission (48), a groove (4912) is formed in the tooth top circle of one tooth of the gear body (4911), and a sliding block (4913) in sliding fit with the groove (4912) is arranged in the groove; a spring (4914) is fixedly connected between the sliding block (4913) and the groove (4912); when the carbon emission measuring instrument (45) is closest to the gear body (4911), a sliding block (4913) on the gear body (4911) is matched with the tooth groove (42) and drives the tube II (41) to rotate, the distance between the gear body (4911) and the tooth groove (42) is gradually shortened in the process of rotating the tube II (41), and finally the gear body (4911) is meshed with the tooth groove (42).

2. A carbon emission measurement data collection device according to claim 1, wherein: the transmission assembly (49) further comprises a transmission wheel (492); the driving wheel (492) comprises a circular ring (4921), a fixed rod (4922) and a shaft lever (54); one end of the shaft lever (54) is connected to a supporting component fixed on the inner wall of the pipe III (51), and the shaft lever (54) is fixedly connected with a fan blade (56); the other end of the shaft lever (54) is fixedly connected with a fixed lever (4922); the other end of the fixed rod (4922) is fixedly connected with a circular ring (4921); the outer circular surface of the circular ring (4921) is provided with a groove body meshed with the gear body (4911);

a connecting ring (4923) is fixedly connected to one side, far away from the shaft rod (54), of the circular ring (4921), a rotating ring (4924) is connected to the outer circular surface of the connecting ring (4923) through a bearing, and a limiting rod (4925) is fixedly connected to the bottom end of the outer circular surface of the rotating ring (4924); the center of the side surface of the gear body (4911) is inserted with a round rod (4915) through a bearing; the limiting rod (4925) vertically penetrates through the round rod (4915); a limiting ring (411) is fixedly connected to the inner wall of the pipe II (41); the limiting ring (411) comprises an arc rod I fixedly connected to the inner wall of the pipe II (41) and having the same inner diameter as the pipe II, and an arc rod II fixedly connected with the arc rod I, wherein the protruding direction faces to the direction of the circle center of the arc rod I; and the limiting rod (4925) is contacted with the inner wall of the arc-shaped rod I and the inner wall of the arc-shaped rod II.

3. A carbon emission measurement data collection device according to claim 2, wherein: a supporting rod (57) is fixedly connected to the inner wall of the pipe III (51); the top end of the supporting rod (57) is rotationally connected with a bidirectional elastic telescopic rod (58), one end of the bidirectional elastic telescopic rod (58) is connected with the supporting component, and the other end of the bidirectional elastic telescopic rod (58) is connected with the sliding rod (53); the outer side of the sliding rod (53) is provided with a sleeve (52) which is in sliding fit with the sliding rod; the sleeve (52) penetrates the top wall of the tube III (51); the support assembly comprises an elastic telescopic rod I (55); the fixed end of the elastic telescopic rod I (55) is fixedly connected to the inner wall of the pipe III (51), and the free end of the elastic telescopic rod I (55) is connected with the bidirectional elastic telescopic rod (58).

4. A carbon emission measurement data collection device according to claim 3, wherein: also comprises a storage device (1); the storage device (1) comprises a water tank (11), a water outlet pipe (12), an elastic telescopic rod II (13) and a baffle plate (14); the fixed end of the elastic telescopic rod II (13) is fixedly connected to the upper ends of the pipe I (21) and the pipe III (51), and a water tank (11) is fixedly connected above the free end of the elastic telescopic rod II (13); the bottom end of the water tank (11) is provided with a perforation above the sleeve (52), and the water outlet pipe (12) is fixedly connected above the perforation; baffle (14) are fixedly connected to two sides of the bottom end of the water tank (11).

5. The carbon emission measurement data collection device of claim 4, wherein: the outer wall of the pipe II (41) is fixedly connected with a bump (46).

6. A carbon emission measurement data collection device according to claim 5, wherein: when the water tank (11) stores rainwater and the carbon emission measuring instrument (45) rotates to the upper side along with the pipe II (41), the water tank (11) is jacked up by the lug (46), so that the water tank (11) drives the baffle (14) to move upwards, and the pipe I (21) and the pipe III (51) are communicated with the outside.

7. The method for collecting the carbon emission measurement data collecting device according to claim 6, wherein: the acquisition method comprises the following steps:

step one: starting a motor (47), wherein the motor (47) drives a transmission assembly (49) to rotate so as to drive a pipe II (41) to rotate, and the pipe II (41) drives a carbon emission measuring instrument (45) to be separated from a fixed partition plate (44) and communicated with the outside for measurement;

step two: the transmission assembly (49) also drives the fan blades (56) to rotate, so that air in the pipe I (21), the pipe II (41) and the pipe III (51) circulates, and the service life of the equipment is prevented from being influenced by moisture;

step three: when raining, the water tank (11) drives the baffle (14) to seal the pipe I (21) and the pipe III (51), so that rainwater is prevented from entering the inside of the pipe I (21).