CN113031370B

CN113031370B - Real-time monitoring equipment based on big data

Info

Publication number: CN113031370B
Application number: CN202110299667.6A
Authority: CN
Inventors: 栾蓉
Original assignee: Jiangsu Institute of Economic and Trade Technology
Current assignee: Jiangsu Institute of Economic and Trade Technology
Priority date: 2021-03-22
Filing date: 2021-03-22
Publication date: 2022-06-14
Anticipated expiration: 2041-03-22
Also published as: CN113031370A

Abstract

The invention discloses real-time monitoring equipment based on big data, which belongs to the technical field of monitoring and comprises an equipment body, wherein a base is arranged at the middle position of one side in the equipment body, a camera body is arranged at the other end of an installation rod, the left end of a connecting pipe extends to the outer side of the equipment body and is fixedly provided with a glass cover used for wrapping the camera body, an ash removing cover is welded on the outer side surface of the equipment body right above the glass cover, and a grid and a cleaning cotton cloth are sequentially fixed at the bottom of an ash removing box. According to the invention, the outer surface of the glass cover is wiped by the wiping cotton cloth on the ash removal box through the rotation of the connecting pipe and the glass cover, meanwhile, under the continuous rotating action of the connecting pipe and the glass cover, air in the arc-shaped cylinder is compressed and enters the ash removal box to blow the wiping cotton cloth, so that dust on the wiping cotton cloth is removed, meanwhile, heat in the glass cover is sucked out through the heat absorption pipe, and the effect of synchronously radiating the inside of the glass cover is realized.

Description

Real-time monitoring equipment based on big data

Technical Field

The invention relates to the technical field of monitoring, in particular to real-time monitoring equipment based on big data.

Background

Big data refers to a data set which cannot be captured, managed and processed by a conventional software tool within a certain time range, is a massive, high-growth-rate and diversified information asset which can have stronger decision-making power, insight discovery power and flow optimization capability only by a new processing mode, can effectively extract information in camera shooting when being combined with monitoring equipment, provides powerful data support for crime prevention, social security, city management, traffic design and city planning, and helps to rapidly develop city health.

In current supervisory equipment, generally all be with the surveillance camera head exposed outside, produce a large amount of dusts easily in long-time use, thereby influence supervisory equipment's use, produce a large amount of heats easily in the use to supervisory equipment simultaneously, make supervisory equipment damage easily, it is inconvenient to use, can't realize simultaneously in the equipment to dust clearance under glass cover self with clean the cotton, clean cotton self and also produce the effect of making a round trip to clean, the synchronous clearance of realizing dust on cleaning the cotton simultaneously, it is inconvenient to use.

Disclosure of Invention

1. Technical problem to be solved

The invention provides real-time monitoring equipment based on big data, which utilizes the rotation of a connecting pipe and a glass cover, wipes the outer surface of the glass cover through wiping cotton cloth on an ash cleaning box to remove dust adsorbed on the outer surface of the glass cover, simultaneously drives arc air inlet pipes and piston plates on the left side and the right side of an air blowing pipe to reciprocate in arc cylinders on the left side and the right side under the continuous rotation action of the connecting pipe and the glass cover, compresses air in the arc cylinders to enter the interior of the ash cleaning box to blow the wiping cotton cloth, removes the dust on the wiping cotton cloth, is convenient to keep the cleaning on the wiping cotton cloth, and sucks out heat in the glass cover through a heat absorbing pipe during the reciprocating motion process to synchronously realize the effect of radiating the interior of the glass cover.

2. Technical scheme

In order to solve the problems, the invention adopts the following technical scheme:

a real-time monitoring device based on big data comprises a device body, wherein a base is installed at the middle position of one side inside the device body, an installation rod is transversely fixed at the middle position of one side of the base, a camera body is installed at the other end of the installation rod, a connecting pipe is rotatably connected inside the device body outside the installation rod through a bearing, the left end of the connecting pipe extends to the outer side of the device body and is fixedly provided with a glass cover used for wrapping the camera body, an ash removing cover is welded on the outer side surface of the device body right above the glass cover, an ash removing box is slidably connected inside the ash removing cover, a grid and a cleaning cotton cloth are sequentially fixed at the bottom of the ash removing box, a blowing pipe is connected at the middle position of one side of the ash removing cover, the other end of the blowing pipe extends to the inside of the device body and is connected with an arc-shaped connecting seat, and arc-shaped air inlet pipes are connected to the two sides of the blowing pipe inside the device body by taking the connecting pipe as the center of a circle, the glass cover is characterized in that one-way valves are mounted on the arc-shaped air inlet pipes, poking rods are fixed at the bottoms of the blowing pipes, arc-shaped cylinders are fixed inside the device body on two sides of the connecting pipe by taking the connecting pipe as a circle center, the other ends of the two arc-shaped air inlet pipes extend into the two arc-shaped cylinders respectively and are fixed with piston plates, one of the piston plates is connected with a first return spring, the bottom of one side of each of the two arc-shaped cylinders is connected with a heat absorbing pipe, the other end of the heat absorbing pipe penetrates through the connecting pipe and extends into the glass cover, a hinged plate is hinged to the side face of the connecting pipe at a position right below the other end of each poking rod, a second return spring is connected to the back face of the hinged plate, and the other end of the second return spring is connected with a supporting block fixed with the connecting pipe.

Preferably, driving motor is installed on the inside top of device body, and all overlaps on driving motor's the output and the inside connecting pipe of device body and be equipped with the belt pulley, two be connected with the belt between the belt pulley.

Preferably, the dust removing cover is of a semicircular spherical structure, and dust falling holes are uniformly formed in the bottom of the dust removing cover on the outer side of the glass cover.

Preferably, the inside of deashing box is hollow structure, and the outside of deashing box is the arc structure of mutually supporting with the glass cover.

Preferably, the two heat absorption pipes are provided with one-way valves.

3. Advantageous effects

(1) The outer surface of the glass cover positioned outside the dust removing cover is easy to adsorb a layer of dust along with long-time use in the using process, at the moment, an external power supply provides electric support for a driving motor, and a connecting pipe and the glass cover are driven by a belt to rotate, so that half of the glass cover positioned outside the dust removing cover enters the inner part of the dust removing cover, and half of the glass cover positioned inside the dust removing cover is replaced for use, the effect of replacing the glass cover is achieved, meanwhile, the dust adsorption is prevented from influencing the definition of a camera body, in the rotating process of the connecting pipe and the glass cover, the outer surface of half of the glass cover entering the inner side of the dust removing cover is wiped by wiping cotton cloth in contact with the outer surface of the glass cover through the dust removing box, the dust adsorbed on the outer surface of the glass cover is removed, meanwhile, the dust removing box slides left and right along the inner part of the dust removing cover along with an air blowing pipe, so that the dust removing box generates the wiping effect on the outer surface of the glass cover, the cleaning effect on the outer surface of the glass cover is improved, and the glass cover is convenient to use.

(2) According to the invention, under the rotating effect of the connecting pipe, the poke rod is poked through the hinged plate, so that the blowing pipe at the top end of the poke rod makes circular motion along the connecting pipe, the arc-shaped air inlet pipe on the left side of the blowing pipe slides along the inside of the arc-shaped cylinder on the left side and is communicated with the bottom of the piston plate through the arc-shaped air inlet pipe, air is pumped into the interior of the ash cleaning box through the arc-shaped air inlet pipe and the blowing pipe in the process of pressing down the piston plate, air is blown through the grid at the bottom of the ash cleaning box and the cleaning cotton cloth to remove dust adsorbed on the cleaning cotton cloth, the next use is convenient, meanwhile, when the left end of the arc-shaped connecting seat is contacted with the top of the arc-shaped cylinder on the left side, the connecting pipe is bent under the effect of continuous rotation of the connecting pipe, the blocking of the hinged plate is released, at the moment, the hinged plate is reset under the action of the first reset spring, and the continuous rotating process enables the blowing pipe to make the blowing pipe perform circular motion along the connecting pipe, Piston plate and arc intake pipe make a round trip to suck in the arc section of thick bamboo inside of the left and right sides for gas is not stopped and is dried to the inside of deashing box, improve and clean the effect to the dust that adsorbs on cleaning the cotton, simultaneously at the piston plate along the inside in-process that comes and goes of arc section of thick bamboo, through the inside of the inside steam suction arc section of thick bamboo of heat absorption pipe with glass cover, reduce the inside temperature of glass cover, prevent that the inside high temperature of glass cover, cause the damage to the camera body.

In conclusion, the outer surface of the glass cover is wiped by the wiping cotton cloth on the dust removal box through the rotation of the connecting pipe and the glass cover, so that dust adsorbed on the outer surface of the glass cover is removed, meanwhile, the arc-shaped air inlet pipes and the piston plates on the left side and the right side of the air blowing pipe are driven to move back and forth in the arc-shaped cylinders on the left side and the right side under the continuous rotating action of the connecting pipe and the glass cover, air in the arc-shaped cylinders is compressed to enter the dust removal box to blow the wiping cotton cloth, so that the dust on the wiping cotton cloth is removed, the cleaning on the wiping cotton cloth is convenient to maintain, and meanwhile, in the process of back and forth movement, heat in the glass cover is sucked out through the heat absorption pipe, so that the effect of heat dissipation in the glass cover is synchronously achieved.

Drawings

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

FIG. 2 is a schematic side view of the device body according to the present invention;

FIG. 3 is a schematic view of the internal structure of the device body according to the present invention;

fig. 4 is an enlarged schematic view of a portion a in fig. 3.

Reference numerals: 1. a camera body; 2. grid mesh; 3. wiping cotton cloth; 4. a dust removing cover; 5. cleaning the ash box; 6. a blowpipe; 7. a poke rod; 8. a belt; 9. a drive motor; 10. a base; 11. a device body; 12. a heat absorbing tube; 13. an arc-shaped cylinder; 14. mounting a rod; 15. a connecting pipe; 16. a glass cover; 17. ash falling holes; 18. a piston plate; 19. an arc-shaped air inlet pipe; 20. an arc-shaped connecting seat; 21. a one-way valve; 22. a first return spring; 23. a hinge plate; 24. a second return spring; 25. and (7) a supporting block.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and examples.

As shown in fig. 1-4, the real-time monitoring device based on big data comprises a device body 11, a base 10 is installed at the middle position of one side inside the device body 11, an installation rod 14 is transversely fixed at the middle position of one side of the base 10, a camera body 1 is installed at the other end of the installation rod 14, a connection pipe 15 is rotatably connected inside the device body 11 outside the installation rod 14 through a bearing, the left end of the connection pipe 15 extends to the outside of the device body 11 and is fixed with a glass cover 16 used for wrapping the camera body 1, an ash removing cover 4 is welded on the outer side surface of the device body 11 right above the glass cover 16, an ash removing box 5 is slidably connected inside the ash removing cover 4, a grid 2 and a wiping cotton cloth 3 are sequentially fixed at the bottom of the ash removing box 5, a blowing pipe 6 is connected at the middle position of one side of the ash removing cover 4, the other end of the blowpipe 6 extends into the device body 11 and is connected with an arc-shaped connecting seat 20, two sides of the blowpipe 6 in the device body 11 are both connected with arc-shaped air inlet pipes 19 by taking the connecting pipe 15 as a circle center, the arc-shaped air inlet pipes 19 are all provided with one-way valves 21, the bottom of the blowpipe 6 is fixed with a poking rod 7, the device body 11 on two sides of the connecting pipe 15 is both fixed with arc-shaped cylinders 13 by taking the connecting pipe 15 as a circle center, the other ends of the two arc-shaped air inlet pipes 19 respectively extend into the two arc-shaped cylinders 13 and are fixed with piston plates 18, the bottom of one of the piston plates 18 is connected with a first return spring 22, the bottom of one side of the two arc-shaped cylinders 13 is connected with a heat absorbing pipe 12, the other end of the heat absorbing pipe 12 passes through the connecting pipe 15 and extends into the glass cover 16, and the side surface of the connecting pipe 15 at the position right below the other end of the poking rod 7 is hinged with a hinged plate 23, and the back of the hinged plate 23 is connected with a second return spring 24, and the other end of the second return spring 24 is connected with a supporting block 25 fixed with the connecting pipe 15.

Further, driving motor 9 is installed on the inside top of device body 11, and all overlaps on driving motor 9's the output and the inside connecting pipe 15 of device body 11 and be equipped with the belt pulley, two be connected with belt 8 between the belt pulley, drive connecting pipe 15 and glass cover 16 through the cooperation between driving motor 9 and the belt 8 and rotate for be located the inside that the outside half glass cover 16 of deashing cover 4 got into deashing cover 4, be located the inside half glass cover 16 of deashing cover 4 and change the use.

Further, the dust removing cover 4 is of a semicircular spherical structure, and dust falling holes 17 are uniformly formed in the bottom of the dust removing cover 4 outside the glass cover 16, so that dust falling off from the wiping cotton cloth 3 can be conveniently discharged from the dust falling holes 17.

Further, the inside of deashing box 5 is hollow structure, and the outside of deashing box 5 is the arc structure of mutually supporting with glass cover 16, utilizes the convenient air inlet of the inside hollow structure of deashing box 5 to blow cleaning cotton 3, will deashing box 5 outside setting simultaneously be the arc structure of mutually supporting with glass cover 16, conveniently cleans glass cover 16's outward appearance.

Further, a one-way valve is installed on each of the two heat absorbing pipes 12.

The real-time monitoring equipment based on big data has the following specific action principle:

firstly, in the use process of the device body 11, the surrounding environment is monitored through the camera body 1, the inside camera body 1 is protected through the glass cover 16 in the monitoring process, on one hand, the damage to the camera body 1 is prevented, on the other hand, the dust is prevented from being adsorbed on the camera body 1 through the glass cover 16 to influence the normal use, meanwhile, along with the long-time use in the use process, a layer of dust is easily adsorbed on the outer surface of the glass cover 16 positioned outside the dust cover 4, at the moment, the external power supply provides electric support for the driving motor 9, and the belt 8 drives the connecting pipe 15 and the glass cover 16 to rotate, so that half of the glass cover 16 positioned outside the dust cover 4 enters the dust cover 4, and half of the glass cover 16 positioned inside the dust cover 4 is replaced for use, and the effect of replacing the glass cover 16 is achieved, meanwhile, the dust adsorption is prevented from influencing the definition of the camera body 1, in the rotating process of the connecting pipe 15 and the glass cover 16, half of the outer surface of the glass cover 16 entering the inner side of the dust removing cover 4 is cleaned through the cleaning cotton cloth 3 contacted with the outer surface of the glass cover 16 by the dust removing box 5, the dust adsorbed on the outer surface of the glass cover 16 is removed, meanwhile, under the rotating effect of the connecting pipe 15, the poking rod 7 is poked through the hinged plate 23, the blowing pipe 6 at the top end of the poking rod 7 makes a circular motion along the connecting pipe 15, the arc-shaped air inlet pipe 19 at the left side of the blowing pipe 6 slides along the inside of the arc-shaped cylinder 13 at the left side, and is communicated with the bottom of the piston plate 18 through the arc-shaped air inlet pipe 19 and the blowing pipe 6, the gas is pumped into the dust removing box 5 through the arc-shaped air inlet pipe 19 and the blowing pipe 6 in the process of pressing down of the piston plate 18, and the dust removing box 5 and the cleaning cotton cloth 3 are blown, get rid of the dust adsorbed on the cleaning cotton cloth 3, facilitate the next use, simultaneously when the left end of the arc connecting seat 20 contacts with the top of the arc cylinder 13 on the left, and under the effect of continuous rotation of the connecting pipe 15, the hinged plate 23 is bent, and the blocking of the poking rod 7 is removed, at this time, the reset is performed under the action of the reset spring one 22, the continuous rotation process enables the blowing pipe 6, the piston plate 18 and the arc air inlet pipe 19 to suck back and forth in the arc cylinder 13 on the left and right sides, so that the air can blow the inside of the dust cleaning box 5 ceaselessly, the dust cleaning effect on the cleaning cotton cloth 3 is improved, meanwhile, the dust cleaning box 5 slides left and right along the inside of the dust cleaning cover 4 along with the blowing pipe 6, the cleaning effect on the outer surface of the glass cover 16 is improved, the use is convenient, and simultaneously, in the process that the piston plate 18 reciprocates along the inside of the arc cylinder 13, through the inside of heat absorption pipe 12 with the inside steam suction arc section of thick bamboo 13 of glass cover 16, reduce the inside temperature of glass cover 16, prevent that the inside high temperature of glass cover 16 from causing the damage to camera body 1.

According to the invention, the outer surface of the glass cover 16 is wiped by the rotation of the connecting pipe 15 and the glass cover 16 and the wiping cotton cloth 3 on the dust removal box 5, so that dust adsorbed on the outer surface of the glass cover 16 is removed, meanwhile, the arc air inlet pipes 19 and the piston plates 18 on the left side and the right side of the air blowing pipe 6 are driven to reciprocate in the arc cylinders 13 on the left side and the right side under the continuous rotation action of the connecting pipe 15 and the glass cover 16, air in the arc cylinders 13 is compressed into the dust removal box 5 to blow the wiping cotton cloth 3, so that dust on the wiping cotton cloth 3 is removed, the cleaning on the wiping cotton cloth 3 is convenient to keep, and meanwhile, in the reciprocating motion process, heat in the glass cover 16 is sucked out through the heat absorption pipe 12, and the effect of heat dissipation in the glass cover 16 is synchronously realized.

It should be understood by those skilled in the art that the above embodiments are only for illustrating the present invention and are not to be used as a limitation of the present invention, and that changes and modifications to the above embodiments are within the scope of the claims of the present invention as long as they are within the spirit and scope of the present invention.

Claims

1. The utility model provides a real-time monitoring equipment based on big data which characterized in that: comprises a device body (11), a base (10) is installed at the middle position of one side inside the device body (11), an installation rod (14) is transversely fixed at the middle position of one side of the base (10), a camera body (1) is installed at the other end of the installation rod (14), a connecting pipe (15) is rotatably connected inside the device body (11) outside the installation rod (14) through a bearing, the left end of the connecting pipe (15) extends to the outside of the device body (11) and is fixed with a glass cover (16) used for wrapping the camera body (1), an ash removing cover (4) is welded on the outer side surface of the device body (11) right above the glass cover (16), an ash removing box (5) is connected inside the ash removing cover (4) in a sliding manner, a grid (2) and cotton cloth (3) are sequentially fixed at the bottom of the ash removing box (5), a blowing pipe (6) is connected at the middle position of one side of the ash removing cover (4), the other end of the blowing pipe (6) extends into the device body (11) and is connected with an arc-shaped connecting seat (20), the two sides of the blowing pipe (6) in the device body (11) are both connected with arc-shaped air inlet pipes (19) by taking the connecting pipe (15) as a circle center, the arc-shaped air inlet pipes (19) are both provided with check valves (21), the bottom of the blowing pipe (6) is fixed with a poking rod (7), the device body (11) on the two sides of the connecting pipe (15) is both fixed with arc-shaped cylinders (13) by taking the connecting pipe (15) as a circle center, the other ends of the two arc-shaped air inlet pipes (19) respectively extend into the two arc-shaped cylinders (13) and are fixed with piston plates (18), the bottom surface of one of the piston plates (18) is connected with a first reset spring (22), and the bottom of one side of the two arc-shaped cylinders (13) is both connected with a heat absorbing pipe (12), the other end of the heat absorption pipe (12) penetrates through the connecting pipe (15) and extends into the glass cover (16), a hinged plate (23) is hinged to the side face of the connecting pipe (15) at the position right below the other end of the poking rod (7), a return spring II (24) is connected to the back face of the hinged plate (23), a supporting block (25) fixed with the connecting pipe (15) is connected to the other end of the return spring II (24), a driving motor (9) is installed at the top end of the interior of the device body (11), belt pulleys are sleeved on the output end of the driving motor (9) and the connecting pipe (15) in the device body (11), a belt (8) is connected between the two belt pulleys, the ash removing cover (4) is of a semicircular spherical structure, ash removing holes (17) are uniformly formed in the bottom of the ash removing cover (4) on the outer side of the glass cover (16), and the interior of the ash removing box (5) is of a hollow structure, the outer side of the ash removal box (5) is of an arc structure matched with the glass cover (16), and one-way valves are arranged on the two heat absorption pipes (12).