CN210469568U - Based on building energy-saving three-dimensional visual material consumption monitoring device - Google Patents

Abstract

The utility model discloses a based on building energy-conserving three-dimensional visual material consumption monitoring device, including device shell, fixed plate and data transmission ware, be fixed with the mount on the device shell, install first circular gear on the driving shaft, be fixed with first conical gear on the driven shaft, and be connected with second conical gear on the first conical gear, be fixed with second circular gear under the second conical gear, and be connected with third circular gear on the second circular gear, third circular gear fixes on the fixed axle, and is connected with the camera under the fixed axle. This based on three-dimensional visual material consumption monitoring device of building energy conservation is provided with first conical gear, and first conical gear can drive second conical gear and rotate, and then drives the circular gear of second and rotate, and under the effect of third circular gear, the fixed axle can drive the camera and rotate, can effectively avoid the monitoring dead angle of camera.

Description

Based on building energy-saving three-dimensional visual material consumption monitoring device

Technical Field

The utility model relates to a building energy conservation technical field specifically is a based on building energy conservation three-dimensional visual material consumption monitoring device.

Background

With the increasing development of social economy, energy consumed in daily life of people also increases year by year, the current shortage of energy and low energy recording rate become main problems of social development, energy conservation and emission reduction gradually become mainstream of social development, and in social development and construction, energy consumed by buildings is huge, so that the energy conservation can be realized by detecting the energy consumption of the buildings in real time through a monitoring device, and then analyzing and predicting the energy consumption of the buildings to provide help for building energy conservation.

Most monitoring devices now have several problems:

firstly, in the building energy consumption detection process, the data acquisition and analysis of weather data such as temperature, wind power and the like are inconvenient, so that the use efficiency of the monitoring device is reduced;

secondly, in the building energy consumption detection process, when the detection area is large, the dead angle of the detection area is inconvenient to be monitored in real time.

Therefore, we propose a material consumption monitoring device based on building energy-saving three-dimensional visualization so as to solve the problems proposed in the above.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a based on building energy-conserving three-dimensional visual material consumption monitoring device to solve the problem that monitoring device exists the dead angle and inconvenient a plurality of regional data of gathering on the existing market that above-mentioned background art provided.

In order to achieve the above object, the utility model provides a following technical scheme: a three-dimensional visual material consumption monitoring device based on building energy conservation comprises a device shell, a fixing plate and a data transmitter, wherein a fixing frame is fixed on the device shell, a small remote control motor is installed on the fixing frame, a driving shaft is connected onto the small remote control motor and is fixed on the fixing frame, a roller is installed on the driving shaft, a clamping thorn is arranged on the roller, a cable is fixed on the roller, a first circular gear is installed on the driving shaft, a second circular gear is connected onto the first circular gear, the second circular gear is arranged on a driven shaft, the driven shaft is fixed on the fixing frame, the roller is arranged on the driven shaft, a first conical gear is fixed on the driven shaft, a second conical gear is connected onto the first conical gear, a second circular gear is fixed under the second conical gear, and a third circular gear is connected onto the second circular gear, the third circular gear is fixed on the fixed shaft, the camera is connected below the fixed shaft, a data transmitter is fixed on the device shell, the wind power detector is installed on the data transmitter, the temperature detector is fixed on the data transmitter, and the temperature detector is installed on the device shell.

Preferably, the rollers are symmetrically distributed on the fixing frame, the clamping thorns are equidistantly distributed on the rollers, and the distance between the rollers is equal to the diameter of the cable.

Preferably, the first bevel gear and the second bevel gear are in meshed connection, the second bevel gear and the fixed plate are in shaft connection, and the diameter of the fixed plate is equal to that of the device shell.

Preferably, the second circular gear and the third circular gear have the same structure, and the height of the third circular gear is greater than that of the data transmitter.

Preferably, the fixed shaft is fixed at the central part of the device shell, and the fixed shaft and the camera are in an integrated structure.

Preferably, the inner diameter of the data transmitter is larger than the outer diameter of the fixed shaft, and the height of the data transmitter is smaller than the length of the fixed shaft.

Compared with the prior art, the beneficial effects of the utility model are that: the building energy-saving-based three-dimensional visual material consumption monitoring device;

(1) the monitoring device is provided with the idler wheels, the idler wheels can be driven by the driving shaft to rotate through the rotation of the remote control motor, the idler wheels on the upper side and the lower side can be driven by the driven shaft to simultaneously rotate in opposite directions under the action of the first circular gear, and the idler wheels can drive the monitoring device to move on a cable under the action of the bayonet, so that the monitoring range of the monitoring device is enlarged, and the use efficiency of the monitoring device is improved;

(2) the monitoring device is provided with a first bevel gear, the first bevel gear can drive a second bevel gear to rotate under the action of a driven shaft so as to drive a second circular gear to rotate, and a fixed shaft can drive a camera to rotate under the action of a third circular gear, so that the monitoring range of the camera can be increased, and the monitoring dead angle of the camera can be effectively avoided;

(3) the monitoring device is provided with the data transmitter, in the movement process of the monitoring device, under the action of the wind power detector and the temperature detector, the data detection can be carried out on wind power and temperature in different areas, and then under the action of the data transmitter, the monitored data are transmitted to the working chamber to be analyzed and predicted, so that the use diversity of the monitoring device is increased.

Drawings

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

FIG. 2 is a schematic side view of the roller of the present invention;

fig. 3 is a schematic top view of the second circular gear of the present invention;

fig. 4 is a schematic diagram of a top view structure of the data transmitter of the present invention.

In the figure: 1. a device housing; 2. a fixed mount; 3. a small remote control motor; 4. a drive shaft; 5. a roller; 6. sticking a thorn; 7. a cable; 8. a first circular gear; 9. a driven shaft; 10. a first bevel gear; 11. a second bevel gear; 12. a fixing plate; 13. a second circular gear; 14. a third circular gear; 15. a fixed shaft; 16. a data transmitter; 17. a wind detector; 18. a temperature detector; 19. a camera is provided.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-4, the present invention provides a technical solution: a three-dimensional visual material consumption monitoring device based on building energy conservation comprises a device shell 1, a fixing frame 2, a small-sized remote control motor 3, a driving shaft 4, a roller 5, a bayonet 6, a cable 7, a first circular gear 8, a driven shaft 9, a first conical gear 10, a second conical gear 11, a fixing plate 12, a second circular gear 13, a third circular gear 14, a fixing shaft 15, a data transmitter 16, a wind power detector 17, a temperature detector 18 and a camera 19, wherein the fixing frame 2 is fixed on the device shell 1, the small-sized remote control motor 3 is installed on the fixing frame 2, the driving shaft 4 is connected onto the small-sized remote control motor 3, the driving shaft 4 is fixed onto the fixing frame 2, the roller 5 is installed onto the driving shaft 4, the bayonet 6 is arranged on the roller 5, the cable 7 is fixed onto the roller 5, the first circular gear 8 is installed onto the driving shaft 4, and the second circular gear 13 is connected onto the first circular gear 8, the second circular gear 13 is arranged on the driven shaft 9, the driven shaft 9 is fixed on the fixing frame 2, the idler wheels 5 are arranged on the driven shaft 9, the first conical gear 10 is fixed on the driven shaft 9, the second conical gear 11 is connected to the first conical gear 10, the second circular gear 13 is fixed below the second conical gear 11, the third circular gear 14 is connected to the second circular gear 13, the third circular gear 14 is fixed on the fixing shaft 15, the camera 19 is connected to the lower portion of the fixing shaft 15, the data transmitter 16 is fixed on the device shell 1, the wind power detector 17 is installed on the data transmitter 16, the temperature detector 18 is fixed on the data transmitter 16, and the temperature detector 18 is installed on the device shell 1.

The gyro wheel 5 symmetric distribution is on mount 2, and blocks thorn 6 equidistance and distribute on gyro wheel 5 to the distance between the gyro wheel 5 equals with the diameter of cable 7, can guarantee the stable working effect of gyro wheel 5 on cable 7.

The first bevel gear 10 and the second bevel gear 11 are in meshed connection, the second bevel gear 11 and the fixing plate 12 are in shaft connection, the diameter of the fixing plate 12 is equal to that of the device shell 1, the stable working effect of the second bevel gear 11 on the fixing plate 12 can be guaranteed, and the use diversity of the monitoring device is increased.

The structure between the second circular gear 13 and the third circular gear 14 is the same, and the height of the third circular gear 14 is greater than the height of the data transmitter 16, so that the adverse effect of the third circular gear 14 on the data transmitter 16 can be effectively avoided.

The fixed shaft 15 is fixed at the central part of the device shell 1, and the fixed shaft 15 and the camera 19 are of an integrated structure, so that the stability of the connection state between the fixed shaft 15 and the camera 19 can be ensured, and the use safety of the monitoring device is improved.

The inner diameter of the data transmitter 16 is larger than the outer diameter of the fixing shaft 15, and the height of the data transmitter 16 is smaller than the length of the fixing shaft 15, so that the stable working state of the fixing shaft 15 on the fixing plate 12 can be ensured, and the use efficiency of the monitoring device is improved.

The working principle is as follows: before the building energy-saving three-dimensional visualization material consumption monitoring device is used, the overall situation of the device needs to be checked firstly, and normal work can be determined;

before the monitoring device starts to work, with reference to fig. 1 and 2, firstly, a cable 7 penetrates through a roller 5 and then is fixed above a monitoring area, then the small remote control motor 3 can be remotely controlled to rotate, a driving shaft 4 can drive the roller 5 to rotate, under the action of a first circular gear 8, the rollers 5 on the upper side and the lower side can simultaneously rotate in opposite directions through a driven shaft 9, under the action of a bayonet 6, the roller 5 can drive the monitoring device to move back and forth on the cable 7, and the monitoring range of the monitoring device is enlarged;

when the monitoring device moves back and forth, referring to fig. 3, the driven shaft 9 can drive the second bevel gear 11 to rotate through the first bevel gear 10, and further drive the second circular gear 13 to rotate, and the fixed shaft 15 can drive the camera 19 to rotate under the action of the third circular gear 14, so that the monitoring range of the camera 19 can be increased, and the monitoring dead angle of the camera 19 can be effectively avoided;

during the movement of the monitoring device, with reference to fig. 4, under the action of the wind detector 17 and the temperature detector 18, the wind power and the temperature in different areas can be detected, and then under the action of the data transmitter 16, the monitored data can be transmitted to the studio for analysis and prediction, which is the working process of the whole device, and the details which are not described in detail in this specification, such as the small remote control motor 3, the data transmitter 16, the wind power detector 17, the temperature detector 18 and the camera 19, are well known to those skilled in the art.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments or portions thereof without departing from the spirit and scope of the invention.

Claims (6)

1. A three-dimensional visualization material consumption monitoring device based on building energy conservation comprises a device shell (1), a fixing plate (12) and a data transmitter (16), and is characterized in that: the device comprises a device shell (1), a fixing frame (2) is fixed on the device shell (1), a small remote control motor (3) is installed on the fixing frame (2), a driving shaft (4) is connected onto the small remote control motor (3), the driving shaft (4) is fixed onto the fixing frame (2), a roller (5) is installed on the driving shaft (4), a clamping thorn (6) is arranged on the roller (5), a cable (7) is fixed onto the roller (5), a first circular gear (8) is installed on the driving shaft (4), a second circular gear (13) is connected onto the first circular gear (8), the second circular gear (13) is arranged on a driven shaft (9), the driven shaft (9) is fixed onto the fixing frame (2), the roller (5) is arranged on the driven shaft (9), a first conical gear (10) is fixed onto the driven shaft (9), and be connected with second bevel gear (11) on first bevel gear (10), second bevel gear (11) is fixed with second circular gear (13) down, and is connected with third circular gear (14) on second circular gear (13), third circular gear (14) are fixed on fixed axle (15), and are connected with camera (19) under fixed axle (15), be fixed with data transmission ware (16) on device shell (1), and install wind detector (17) on data transmission ware (16), be fixed with thermodetector (18) on data transmission ware (16), and thermodetector (18) install on device shell (1).

2. The building energy-saving three-dimensional visualization material consumption monitoring device as claimed in claim 1, wherein: the rollers (5) are symmetrically distributed on the fixing frame (2), the clamping thorns (6) are equidistantly distributed on the rollers (5), and the distance between the rollers (5) is equal to the diameter of the cable (7).

3. The building energy-saving three-dimensional visualization material consumption monitoring device as claimed in claim 1, wherein: the first bevel gear (10) and the second bevel gear (11) are in meshed connection, the second bevel gear (11) and the fixing plate (12) are in shaft connection, and the diameter of the fixing plate (12) is equal to that of the device shell (1).

4. The building energy-saving three-dimensional visualization material consumption monitoring device as claimed in claim 1, wherein: the structure between the second circular gear (13) and the third circular gear (14) is the same, and the height of the third circular gear (14) is larger than that of the data transmitter (16).

5. The building energy-saving three-dimensional visualization material consumption monitoring device as claimed in claim 1, wherein: the fixed shaft (15) is fixed at the central part of the device shell (1), and the fixed shaft (15) and the camera (19) are of an integrated structure.

6. The building energy-saving three-dimensional visualization material consumption monitoring device as claimed in claim 1, wherein: the inner diameter of the data transmitter (16) is larger than the outer diameter of the fixed shaft (15), and the height of the data transmitter (16) is smaller than the length of the fixed shaft (15).

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