CN117630297A - Carbon emission monitoring equipment for building engineering construction - Google Patents

Abstract

The utility model provides carbon emission monitoring equipment for building engineering construction. The utility model relates to a building engineering technical field, the building engineering builds carbon emission monitoring equipment, includes: the novel carbon emission monitoring device comprises a ventilation pipe, wherein a fixed barrel is fixedly installed on the ventilation pipe, the fixed barrel is communicated with the ventilation pipe, a carbon emission monitor is fixedly installed in the fixed barrel, two L-shaped pipes are fixedly installed on the fixed barrel, dust screens are fixedly installed at two ends of the ventilation pipe respectively, two double-shaft motors are fixedly installed in the ventilation pipe, a wind guiding fan blade is fixedly installed on an output shaft, which is mutually close to the double-shaft motors, of each double-shaft motor, and a rotating rod is fixedly installed on an output shaft, which is mutually far away from the double-shaft motors, of each double-shaft motor. The carbon emission monitoring equipment for construction engineering provided by the utility model has the advantages of convenience in use, simplicity in operation, dust prevention function and improvement of accuracy of monitoring data.

Description

Carbon emission monitoring equipment for building engineering construction

Technical Field

The utility model relates to the technical field of constructional engineering, in particular to carbon emission monitoring equipment for constructional engineering construction.

Background

The building engineering refers to the collective name of various buildings and engineering facilities which provide material technology foundation for human life and production, at present, the requirement of reducing carbon emission is internationally or domestically met, in general, the total carbon emission is distributed for each unit for a certain period, if the total carbon emission exceeds the total carbon emission, a corresponding punishment mechanism is provided, and therefore, people generally monitor the carbon emission in the building engineering construction through carbon emission monitoring equipment at any time. The authorized publication number is a building carbon emission monitoring device, comprising a device body; according to the utility model, the motor drives the speed reducer to rotate, the speed reducer drives the connecting rotating shaft to rotate, the connecting rotating shaft drives the screw rod to rotate, and the screw rod rotates to enable the sliding block to move in the sliding groove, so that the height of the bottom plate can be adjusted, and the height of the monitoring mechanism can be adjusted.

However, the existing monitoring structure lacks a dustproof function, when the device is used for monitoring carbon emission on a construction site for a long time, the dust is large on the construction site, and the dust is often adhered to the monitoring mechanism on the device, so that the accuracy of a monitoring result is influenced.

Accordingly, there is a need to provide a carbon emission monitoring device for construction of a building engineering that solves the above-mentioned technical problems.

Disclosure of Invention

The utility model solves the technical problem of providing the carbon emission monitoring equipment for building engineering construction, which is convenient to use, simple to operate, has a dustproof function and improves the accuracy of monitoring data.

In order to solve the technical problems, the present utility model provides a carbon emission monitoring device for construction of a building engineering, comprising: the device comprises a ventilation pipe, wherein a fixed barrel is fixedly arranged on the ventilation pipe, the fixed barrel is communicated with the ventilation pipe, two L-shaped pipes are fixedly arranged in the fixed barrel, dust-proof nets are fixedly arranged at two ends of the ventilation pipe respectively, two double-shaft motors are fixedly arranged in the ventilation pipe, a fan guiding blade is fixedly arranged on output shafts, which are mutually close to each other, of the double-shaft motors, a rotating rod is fixedly arranged on output shafts, which are mutually far away from each other, of the double-shaft motors respectively, the rotating rod penetrates through the two dust-proof nets respectively and is movably connected with the two dust-proof nets respectively, cleaning brushes are sleeved on the two rotating rods in a sliding manner respectively, two sliding rods are respectively arranged on the cleaning brushes in a sliding manner, round plates are fixedly arranged at one ends of the sliding rods respectively, limiting rods are respectively and fixedly connected with the corresponding round plates, four pressing springs are respectively and movably sleeved on the four sliding rods, and the four ends of the four sliding rods are respectively and are correspondingly connected with one ends of the round plates, which are correspondingly pressed by the pressing springs.

Preferably, a circular partition plate is fixedly arranged in the ventilation pipe.

Preferably, one end of each of the four sliding rods is fixedly provided with a limiting plate.

Preferably, a bottom plate is arranged below the ventilation pipe, a rotating motor is fixedly arranged at the top of the bottom plate, a rotating circular plate is fixedly arranged on an output shaft of the rotating motor, two connecting rods are fixedly arranged at the top ends of the rotating circular plate, an arc-shaped plate is fixedly arranged at the top ends of the connecting rods, and the arc-shaped plate is fixedly connected with the ventilation pipe.

Preferably, the rotating circular plate is rotatably sleeved with an annular plate, two supporting rods are fixedly arranged at the bottom of the annular plate, and the two supporting rods are fixedly connected with the bottom plate.

Preferably, both the compression springs are tin plated springs.

Compared with the related art, the carbon emission monitoring equipment for construction engineering provided by the utility model has the following beneficial effects:

the utility model provides carbon emission monitoring equipment for building engineering, which is characterized in that an induced fan blade is driven to rotate through rotation of a double-shaft motor, external air is introduced into a fixed barrel to be in contact with a carbon emission monitor, carbon emission content in the air is detected through the carbon emission monitor, dust in the air is prevented from entering a ventilation pipe along with the air and finally adhering to the carbon emission monitor through a dust screen, the accuracy of overhaul detection of the carbon emission monitor is affected, meanwhile, the dust screen is cleaned through rotation of the double-shaft motor to drive a cleaning brush to rotate, the dust screen is prevented from being blocked, the external air cannot quickly enter the ventilation pipe and the fixed barrel, the working efficiency of the device is affected, the ventilation pipe is driven to rotate through rotation of the rotating motor, and then the air in different areas can be introduced into the ventilation pipe, and the monitoring area is effectively enlarged.

Drawings

FIG. 1 is a schematic diagram of a front view of a first embodiment of a carbon emission monitoring device for use in construction of a building project according to the present utility model;

FIG. 2 is an enlarged schematic view of portion A shown in FIG. 1;

FIG. 3 is a front view of a first embodiment of the carbon emission monitoring device for construction of a building project according to the present utility model;

FIG. 4 is a schematic diagram of a front view of a second embodiment of a carbon emission monitoring device for use in construction of a building project according to the present utility model;

FIG. 5 is an enlarged schematic view of portion B shown in FIG. 4;

fig. 6 is a front view of a second embodiment of the carbon emission monitoring device for construction engineering provided by the present utility model.

Reference numerals in the drawings: 1. a ventilation pipe; 2. a biaxial motor; 3. induced air fan blades; 4. a rotating lever; 5. a dust screen; 6. cleaning a hairbrush; 7. a slide bar; 8. a circular plate; 9. a limit rod; 10. extruding a spring; 11. a limiting plate; 12. a circular partition; 13. a fixed barrel; 14. a carbon emission monitor; 15. an L-shaped pipe; 16. an arc-shaped plate; 17. a connecting rod; 18. an annular plate; 19. a support rod; 20. a rotating motor; 21. a bottom plate; 22. rotating the circular plate; 23. a through hole; 24. a fixing plate; 25. a splice plate; 26. a tension spring; 27. a straight rod; 28. a clamping plate; 29. friction plate.

Detailed Description

The utility model will be further described with reference to the drawings and embodiments.

First embodiment

Referring to fig. 1 to 3 in combination, in a first embodiment of the present utility model, a construction carbon emission monitoring apparatus for construction engineering includes: in order to separate the ventilation pipe 1 into two parts, and further, when the two induced air fan blades 3 rotate, two external air is introduced into the ventilation pipe 1, so that no influence is caused, a round partition plate 12 is fixedly arranged in the ventilation pipe 1, a fixed barrel 13 is fixedly arranged on the ventilation pipe 1, the fixed barrel 13 is communicated with the ventilation pipe 1, a carbon emission monitor 14 is fixedly arranged in the fixed barrel 13, two L-shaped pipes 15 are fixedly arranged on the fixed barrel 13, two ends of the ventilation pipe 1 are respectively fixedly provided with a dustproof net 5, two double-shaft motors 2 are fixedly arranged in the ventilation pipe 1, induced air fan blades 3 are respectively fixedly arranged on output shafts, which are mutually close, of the two double-shaft motors 2 rotate to drive the induced air fan blades 3 to rotate, and the external air is introduced into the ventilation pipe 1 and finally enters the fixed barrel 13 to be in contact with the carbon emission monitor 14, the carbon emission content in the air is further detected by the carbon emission monitor 14, the rotating rods 4 are fixedly installed on the output shafts of the two double-shaft motors 2 which are far away from each other respectively, the two rotating rods 4 penetrate through the two dustproof nets 5 respectively and are movably connected with the two dustproof nets 5 respectively, dust entering into the ventilation pipe 1 is filtered by the dustproof nets 5, the dust in the air is prevented from entering into the ventilation pipe 1 together with the air and finally adhering to the carbon emission monitor 14, the accuracy of overhaul and detection of the carbon emission monitor 14 is affected, cleaning hairbrushes 6 are sleeved on the two rotating rods 4 in a sliding manner respectively, two sliding rods 7 are slidably installed on the two cleaning hairbrushes 6 respectively, in order to limit the sliding rods 7, the sliding rods 7 are slidably installed on the cleaning hairbrushes 6 all the time, one ends of the four sliding rods 7 are fixedly installed with limiting plates 11 respectively, one end of four slide bars 7 is fixed mounting respectively has circular plate 8, slidable mounting has gag lever post 9 respectively on two dwang 4, and the both ends of two gag lever posts 9 respectively with corresponding circular plate 8 fixed connection, movable sleeve is equipped with extrusion spring 10 respectively on four slide bars 7, in order to improve extrusion spring 10's life, two extrusion springs 10 are tinned spring, and four extrusion spring 10's one end respectively with corresponding circular plate 8 fixed connection, four extrusion spring 10's the other end respectively with corresponding clearance brush 6 fixed connection, extrusion spring 10 is in compressed state under the initial condition, make the brush hair on the clearance brush 6 inseparable all the time and dust screen 5 contact through extrusion spring 10 extrusion clearance brush 6, drive dwang 4 rotation through biax motor 2, dwang 4 rotates and drives gag lever post 9 rotation, gag lever post 9 rotates and drives circular plate 8 rotation, circular plate 8 rotates and drives the slide bar 7 and rotate and finally drive clearance brush 6 and clear up dust screen 5, prevent that dust screen 5 from blocking, and then the unable entering of external air to get into 1 and fixed barrel 13 in the work efficiency of this device fast.

In order to enable the device to introduce air in different areas into the ventilation pipe 1, the monitoring area is effectively enlarged, a bottom plate 21 is arranged below the ventilation pipe 1, a rotating motor 20 is fixedly arranged at the top of the bottom plate 21, a rotating circular plate 22 is fixedly arranged on an output shaft of the rotating motor 20, two connecting rods 17 are fixedly arranged at the top ends of the rotating circular plate 22, arc plates 16 are fixedly arranged at the top ends of the two connecting rods 17, the arc plates 16 are fixedly connected with the ventilation pipe 1, the rotating circular plate 22 is driven by the rotation of the rotating motor 20, the rotating circular plate 22 drives the two connecting rods 17 to rotate, the arc plates 16 are driven by the rotation of the arc plates 16 to rotate, and then the device can introduce air in different areas into the ventilation pipe 1 to effectively enlarge the monitoring area.

In order to support the ventilation pipe 1, the rotating motor 20 is shared for bearing, the weight of the ventilation pipe 1 is prevented from being concentrated on the rotating motor 20 completely, the rotating motor 20 is in a heavy state for a long time, the service life is influenced, the rotating circular plate 22 is sleeved with the annular plate 18 in a rotating mode, two supporting rods 19 are fixedly arranged at the bottom of the annular plate 18, and the two supporting rods 19 are fixedly connected with the bottom plate 21.

The working principle of the carbon emission monitoring equipment for building engineering provided by the utility model is as follows; the extrusion spring 10 is in compression state under initial condition, pass through extrusion spring 10 extrusion clearance brush 6 and make the brush hair on the clearance brush 6 inseparable and contact with dust screen 5 all the time, when needs use this device, start two biax motors 2, two biax motors 2 rotate and drive induced air flabellum 3 rotation, introduce ventilation pipe 1 with external air in, finally enter into in the fixed bucket 13 with carbon emission monitor 14 contact, and then detect carbon emission content in the air through carbon emission monitor 14, filter the dust that enters into in the ventilation pipe 1 through dust screen 5, prevent the dust in the air to enter into on the carbon emission monitor 14 together with the air on final adhesion to carbon emission monitor 14, influence carbon emission monitor 14 maintenance detection's accuracy, simultaneously drive dwang 4 through biax motor 2 rotation, dwang 4 rotates and drives gag lever 9 rotation, gag lever 9 rotation drives circular plate 8 rotation, circular plate 8 rotation drives slide bar 7 rotation and finally drive clearance brush 6 rotation and clear up dust screen 5, and prevent that the dust screen 5 from blocking up, and then the air drum that leads to get into in the air drum 1 fast and drive the fixed device that the inside of two circular plates 1 rotate through the fixed disk plate 17, and drive the inside of the rotatable region of the rotatable 15, and the rotatable region 16 can's of the rotatable region 16 is rotated by the rotatable region 16, and the rotatable region is 16 can's of the rotatable region is driven by the rotatable region 16, and the rotatable region is 16 is driven by the rotatable region is 16.

Compared with the related art, the carbon emission monitoring equipment for construction engineering provided by the utility model has the following beneficial effects:

the utility model provides carbon emission monitoring equipment for construction engineering, which is characterized in that a double-shaft motor 2 rotates to drive a induced air fan blade 3 to rotate, external air is introduced into a fixed barrel 13 to be in contact with a carbon emission monitor 14, carbon emission content in the air is detected by the carbon emission monitor 14, dust in the air is prevented from entering a ventilation pipe 1 along with the air and finally adhering to the carbon emission monitor 14 by a dust screen 5, the accuracy of overhaul detection of the carbon emission monitor 14 is affected, meanwhile, a cleaning brush 6 is driven to rotate by the rotation of the double-shaft motor 2 to clean the dust screen 5, the dust screen 5 is prevented from being blocked, the external air cannot enter the ventilation pipe 1 and the fixed barrel 13 quickly, the working efficiency of the device is affected, the ventilation pipe 1 is driven to rotate by the rotation of a rotating motor 20, and the air in different areas can be introduced into the ventilation pipe 1, and the monitoring area is effectively enlarged.

Second embodiment:

based on the construction carbon emission monitoring device provided in the first embodiment of the present application, the second embodiment of the present application proposes another construction carbon emission monitoring device. The second embodiment is merely a preferred manner of the first embodiment, and implementation of the second embodiment does not affect the implementation of the first embodiment alone.

A second embodiment of the present utility model will be further described with reference to the drawings and embodiments.

Referring to fig. 4-6, the carbon emission monitoring device for construction of constructional engineering further includes a through hole 23, the through hole 23 is formed in the bottom plate 21, a fixing plate 24 is fixedly installed in the through hole 23, extension springs 26 are fixedly installed on outer walls of two sides of the fixing plate 24 respectively, connection plates 25 are fixedly installed at ends of the two extension springs 26, which are far away from each other, straight rods 27 are rotatably installed on the two connection plates 25 respectively, rotating grooves are formed on outer walls of one sides of the two connection plates 25, one ends of the two straight rods 27, which are far away from each other, extend into the two rotating grooves respectively and are fixedly sleeved with bearings respectively, outer rings of the two bearings are fixedly connected with inner walls of the two rotating grooves respectively, one ends of the two straight rods 27, which are far away from each other, extend out of the through hole 23, and clamping plates 28 are fixedly installed at one ends of the two straight rods 27, which are far away from each other.

In order to increase the friction between the clamping plates 28 and the workbench and further enable the device to be clamped on the workbench more stably, friction plates 29 are fixedly arranged on the outer walls of the two clamping plates 28 on the side close to each other.

The extension spring 26 is in the tensile state under the initial condition, make splint 28 be in vertical upward state centre gripping on bottom plate 21 through extension spring 26, when people place this device on the workstation use this device, pull two splint 28 each other away from earlier, the tensile more serious of extension spring 26 now rotates two splint 28, make two splint 28 rotate to vertical downward state by vertical upward state, then release two splint 28 and make two splint 28 be located the both sides on the workstation, finally make two splint 28 firmly centre gripping on the workstation under the effect of extension spring 26, and then make this device stably install on the workstation, prevent to appear and drop subaerial from the workstation under the effect that receives the external force, cause this device to damage, influence life.

The foregoing description is only illustrative of the present utility model and is not intended to limit the scope of the utility model, and all equivalent structures or equivalent processes or direct or indirect application in other related technical fields are included in the scope of the present utility model.

Claims (8)

1. The utility model provides a building engineering builds carbon emission monitoring equipment, includes ventilation pipe, its characterized in that: the fixed barrel is fixedly installed on the ventilation pipe and is communicated with the ventilation pipe, the carbon emission monitor is fixedly installed in the fixed barrel, two L-shaped pipes are fixedly installed on the fixed barrel, dust-proof nets are fixedly installed at two ends of the ventilation pipe respectively, two double-shaft motors are fixedly installed in the ventilation pipe, air guiding blades are fixedly installed on output shafts, which are mutually close to each other, of the double-shaft motors respectively, rotating rods are fixedly installed on output shafts, which are mutually far away from each other, of the double-shaft motors respectively, the rotating rods respectively penetrate through the two dust-proof nets and are respectively and movably connected with the two dust-proof nets, cleaning brushes are respectively and slidably installed on the two cleaning brushes, two limiting rods are respectively and fixedly installed at one ends of the sliding rods, two circular plates are respectively and slidably installed on the rotating rods, two ends of the limiting rods are respectively and fixedly connected with the corresponding circular plates, four pressing springs are respectively and movably sleeved on the four sliding rods, and the four ends of the four pressing springs are respectively and correspondingly connected with the other ends of the pressing springs.

2. The carbon emission monitoring device as recited in claim 1, wherein a circular partition is fixedly installed in the ventilation duct.

3. The construction carbon emission monitoring device as recited in claim 2, wherein one end of each of the four sliding bars is fixedly provided with a limiting plate.

4. The carbon emission monitoring device for construction engineering construction according to claim 3, wherein a bottom plate is arranged below the ventilation pipe, a rotating motor is fixedly arranged at the top of the bottom plate, a rotating circular plate is fixedly arranged on an output shaft of the rotating motor, two connecting rods are fixedly arranged at the top ends of the rotating circular plate, arc-shaped plates are fixedly arranged at the top ends of the two connecting rods, and the arc-shaped plates are fixedly connected with the ventilation pipe.

5. The carbon emission monitoring device for construction engineering according to claim 4, wherein an annular plate is rotatably sleeved on the rotary circular plate, two support rods are fixedly installed at the bottom of the annular plate, and the two support rods are fixedly connected with the bottom plate.

6. The construction carbon emission monitoring device of claim 1, wherein both of the compression springs are tin plated springs.

7. The carbon emission monitoring device for construction engineering construction according to claim 5, wherein a through hole is formed in the bottom plate, a fixing plate is fixedly installed in the through hole, extension springs are fixedly installed on outer walls of two sides of the fixing plate respectively, a connecting plate is fixedly installed at one end, away from each other, of each of the two extension springs, a straight rod is rotatably installed on each of the two connecting plates, one ends, away from each other, of the two straight rods extend out of the through hole, and a clamping plate is fixedly installed at one end, away from each other, of each of the two straight rods.

8. The carbon emission monitoring device as recited in claim 7, wherein friction plates are fixedly installed on outer walls of the two clamping plates on one side, which are adjacent to each other, respectively.