CN113203442A

CN113203442A - Flow monitoring equipment based on electric automation

Info

Publication number: CN113203442A
Application number: CN202110537832.7A
Authority: CN
Inventors: 南钰; 郝婧; 秦泽华; 王方苏; 张迎春
Original assignee: State Grid Corp of China SGCC; Kaifeng Power Supply Co of State Grid Henan Electric Power Co Ltd
Current assignee: State Grid Corp of China SGCC; Kaifeng Power Supply Co of State Grid Henan Electric Power Co Ltd
Priority date: 2021-05-18
Filing date: 2021-05-18
Publication date: 2021-08-03
Anticipated expiration: 2041-05-18
Also published as: CN113203442B

Abstract

The invention discloses a flow monitoring device based on electric automation, which comprises: the box body is arranged on the ground as a main device, one end of the box body is connected with a cover plate through a connecting shaft, a heat dissipation plate is arranged on the outer side of the cover plate, and a monitoring device body is arranged in the box body; the air blower is used as an air conveying device and is arranged on one side of the box body, a vent pipe is connected to one side of the air blower, and a floating ball is arranged on one side inside the vent pipe. This flow monitoring equipment based on electric automatization is provided with first supporting rod, carries out the in-process of work through the air-blower, will make inside gaseous through the ventilation pipe transportation that produces to the inside of ventilation pipe is provided with the floater, thereby makes the one end of dysmorphism wheel extrude the gasbag, thereby makes the inside gas of gasbag, thereby carries out the centre gripping to the inside cable of the device effectively, and then prevents the purpose that the inside cable of the device is in disorder.

Description

Flow monitoring equipment based on electric automation

Technical Field

The invention relates to the technical field of electrical automation, in particular to flow monitoring equipment based on electrical automation.

Background

Electric automatization includes various check out test set, communication equipment, safety arrangement, automatic control device and control automation, consequently, need use flow monitoring equipment at the in-process to control automation, flow monitoring equipment based on electric automatization guarantees on advanced technical equipment and high economic benefits's basis, realizes the monitoring devices of the reasonable coordination of electric energy production and consumption, but electric automatization's flow monitoring equipment still has certain weak point in the market:

the publication No. CN112399737A discloses a flow monitoring device based on an electric power automation system, which comprises a box body, a guide wheel, a screw rod, a bearing, a first driving motor, a driving shaft, mounting plates, a first connecting rod and a placing box … …, wherein a second driving motor drives a driving rod to rotate, the driving rod drives a driving shaft to rotate, the driving shaft drives a driving rod to rotate, the driving rod drives a fan blade to rotate, the placing box is ventilated, and simultaneously two blast boxes can be driven to move to radiate heat of a monitor above the placing plate, the use is very convenient, the service life of the monitor is effectively prolonged, the box body, the guide wheel, the screw rod, the bearing, the first driving motor, the ventilating box and the ventilating opening … … are arranged, the driving shaft can be driven to rotate by the first driving motor, the driving shaft drives the screw rod to rotate, the screw rod drives the two mounting plates to move, the two mounting plates drive the placing box to move, thereby reach the purpose of adjusting whole monitoring devices height, it is convenient to use, but flow monitoring device on the market is at the in-process that uses, and the inside cable of the device is more mixed and disorderly, and then inconvenient centralized processing carries out, and simultaneously at the in-process that uses, the inside of the device can not dispel the heat fast.

We propose a flow monitoring device based on electrical automation in order to solve the problems set forth above.

Disclosure of Invention

The invention aims to provide flow monitoring equipment based on electrical automation, and the flow monitoring equipment is used for solving the problems that cables in the flow monitoring equipment in the current market are messy and inconvenient to perform centralized processing in the use process of the flow monitoring equipment in the background technology, and meanwhile, the inside of the flow monitoring equipment cannot be rapidly cooled in the use process.

In order to achieve the purpose, the invention provides the following technical scheme: an electrical automation based flow monitoring device comprising:

the box body is arranged on the ground as a main device, one end of the box body is connected with a cover plate through a connecting shaft, a heat dissipation plate is arranged on the outer side of the cover plate, and a monitoring device body is arranged in the box body;

the air blower is installed on one side of the box body as an air conveying device, a ventilation pipe is connected to one side of the air blower, a floating ball is arranged on one side inside the ventilation pipe and connected with a rotating rod through a pull rope, the bottom of the rotating rod is connected with the inner wall of the box body through a torsion spring, a special-shaped wheel is fixed to the top end of the rotating rod, an air bag is arranged on one side of the special-shaped wheel, a ventilation pipe is arranged at one end of the air bag, the other end of the ventilation pipe is arranged at the bottom of the placing groove, the bottom of the placing groove is connected with the piston plate through a return spring, and a first magnet is fixed to the top of the piston plate;

the clamping device comprises a first clamping rod, a second clamping rod and a connecting rod, wherein the first clamping rod is connected with the second clamping rod through a movable shaft, the second magnet is arranged on one side of the first clamping rod and one side of the second clamping rod, the connecting rod is arranged at the tops of the first clamping rod and the second clamping rod, the connecting rod stretches into the inside of a sliding groove through a sliding block, and one end of the sliding groove is connected with the sliding block through a connecting spring.

Preferably, the one end setting of ventilation pipe is in the inside of box, just the right side that the ventilation pipe is close to the floater is provided with the wind wheel, the inboard nestification of wind wheel is in the outside of montant, the one end of montant stretches out the outside of ventilation pipe is connected with box bearing, and then conveniently drives the montant through the wind wheel and rotates.

Preferably, the air bag is arranged on the inner wall of the box body and made of elastic materials, the distance from the air bag to the circle center of the rotating rod is smaller than the maximum radius of the special-shaped wheel, so that the air bag is conveniently extruded at one end of the special-shaped wheel, and the air in the air bag flows to the inside of the placing groove through the vent pipe.

Preferably, first supporting rod and second supporting rod all set up the top at first magnet, just first supporting rod passes through to constitute swing joint between loose axle and the second supporting rod, and then makes things convenient for first magnet to drive first supporting rod and second supporting rod through second magnet and rotate.

Preferably, the outside diameter of floater and the inner wall diameter phase-match of ventilation pipe, the floater passes through the stay cord and drives the bull stick and rotate to set up for the integration between the top of bull stick and the special-shaped wheel, and then make things convenient for the floater to drive the bull stick through the stay cord and rotate.

Preferably, the wind wheel is connected with the worm through the transmission assembly, just one side of worm is connected with the worm wheel, the inboard nestification of worm wheel is in the outside of air diffusing pipe, just the gas vent has been seted up to the equidistant gas vent in the outside of air diffusing pipe, the spacing groove has been seted up to one side of air diffusing pipe, and the outside of ventilation pipe one end is fixed with the stopper, through above setting, and then makes things convenient for the air diffusing pipe to rotate to conveniently dispel the heat to inside.

Preferably, the outer side of the limiting block is matched with the inner side of the limiting groove, and the air diffusing pipe forms a rotating structure through the limiting block and the limiting groove, so that the air diffusing pipe can rotate stably.

Preferably, the wind wheel forms a linkage structure with the worm through the transmission device assembly, and the worm drives the air dispersing pipe to rotate through the worm wheel, so that the worm drives the worm wheel to rotate.

Preferably, the outer side of the sliding block in the shape of the T is in clearance fit with the inner wall of the sliding groove, and the sliding block forms an elastic sliding structure with the sliding groove through a connecting spring, so that the sliding block can stably slide in the sliding groove.

Compared with the prior art, the invention has the beneficial effects that: this flow monitoring equipment based on electric automatization is provided with:

(1) the air blower is provided with a first clamping rod, gas generated inside the air blower can be transported through the ventilation pipe in the working process of the air blower, a floating ball is arranged inside the ventilation pipe, one end of the floating ball is connected with the outer side of the rotating rod through a pull rope, so that the rotating rod drives the special-shaped wheel to rotate, one end of the special-shaped wheel extrudes the air bag, the gas inside the air bag is transported into the placing groove through the ventilation pipe, the gas drives the first magnet to move through the piston plate, the second magnet is arranged on one side of each of the first clamping rod and the second clamping rod, the connecting rods are arranged on the tops of the first clamping rod and the second clamping rod, the connecting rods stably slide inside the sliding groove through the sliding blocks, and the first clamping rod and the second clamping rod rotate through the movable shaft, therefore, the cable in the device is effectively clamped, and the cable in the device is prevented from being disordered;

(2) be provided with the trachea that looses, it rotates to drive the wind wheel through wind-force, the wind wheel will drive the montant simultaneously and rotate, thereby make the montant pass through the transmission subassembly and drive the worm and rotate, because one side of worm is provided with the worm wheel, the worm wheel sets up in the outside of the trachea that looses simultaneously, because be connected for the bearing between the inner wall of the one end of trachea that looses and the box, and the trachea that looses the other end with seted up the spacing groove, the inner wall at the spacing groove is connected through the limiting block in the outside of ventilation pipe simultaneously, and then make the trachea that looses rotate, thereby make the inside to the device carry out diversified heat dissipation, thereby reach the purpose of carrying out quick heat dissipation to the device inside.

Drawings

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

FIG. 2 is a schematic cross-sectional front view of the present invention;

FIG. 3 is an enlarged view of a portion a of FIG. 2 according to the present invention;

FIG. 4 is a schematic left sectional view of the piston plate and the first magnet of the present invention;

FIG. 5 is a schematic top sectional view of the first clamping rod and the movable shaft connection according to the present invention;

FIG. 6 is a schematic top sectional view of the connection between the rotating rod and the box body according to the present invention;

FIG. 7 is a schematic left side sectional view of the worm and worm wheel connection of the present invention;

fig. 8 is an enlarged view of the structure at b in fig. 2 according to the present invention.

In the figure: 1. a box body; 2. a cover plate; 3. a heat dissipation plate; 4. a blower; 5. a vent pipe; 501. a wind wheel; 502. a vertical rod; 6. a floating ball; 7. pulling a rope; 8. a rotating rod; 801. a torsion spring; 9. a special-shaped wheel; 10. an air bag; 11. a breather pipe; 12. a placement groove; 13. a return spring; 14. a piston plate; 15. a first magnet; 16. a first clamping rod; 17. a movable shaft; 18. a second clamping rod; 19. a second magnet; 20. a connecting rod; 21. a slider; 22. a chute; 23. a connecting spring; 24. a monitoring device body; 25. a transmission assembly; 26. a worm; 27. a worm gear; 28. an air diffusing pipe; 29. an air diffuser; 30. a limiting groove; 31. and a limiting block.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-8, the present invention provides a technical solution: a flow monitoring device based on electric automation comprises a box body 1, a cover plate 2, a heat dissipation plate 3, an air blower 4, a ventilation pipe 5, a wind wheel 501, a vertical rod 502, a floating ball 6, a pull rope 7, a rotating rod 8, a torsion spring 801, a special-shaped wheel 9, an air bag 10, a ventilation pipe 11, a placing groove 12, a reset spring 13, a piston plate 14, a first magnet 15, a first clamping rod 16, a movable shaft 17, a second clamping rod 18, a second magnet 19, a connecting rod 20, a sliding block 21, a sliding groove 22, a connecting spring 23, a monitoring device body 24, a transmission device assembly 25, a worm 26, a worm wheel 27, an air dispersing pipe 28, an air dispersing port 29, a limiting groove 30 and a limiting block 31;

the method comprises the following steps:

the box body 1 is arranged on the ground as a main device, one end of the box body 1 is connected with a cover plate 2 through a connecting shaft, a heat dissipation plate 3 is arranged on the outer side of the cover plate 2, and a monitoring device body 24 is arranged in the box body 1;

the air blower 4 is installed on one side of the box body 1 as an air conveying device, one side of the air blower 4 is connected with a vent pipe 5, one side inside the vent pipe 5 is provided with a floating ball 6, the floating ball 6 is connected with a rotating rod 8 through a pull rope 7, the bottom of the rotating rod 8 is connected with the inner wall of the box body 1 through a torsion spring 801, the top end of the rotating rod 8 is fixedly provided with a special-shaped wheel 9, one side of the special-shaped wheel 9 is provided with an air bag 10, one end of the air bag 10 is provided with a vent pipe 11, the other end of the vent pipe 11 is arranged at the bottom of a placement groove 12, the bottom of the placement groove 12 is connected with a piston plate 14 through a return spring 13, and the top of the piston plate 14 is fixedly provided with a first magnet 15;

first clamping rod 16, it is connected with second clamping rod 18 through loose axle 17, and one side of first clamping rod 16 and second clamping rod 18 all is provided with second magnet 19, and connecting rod 20 is all installed with the top of second clamping rod 18 to first clamping rod 16 simultaneously, and connecting rod 20 stretches into the inside of spout 22 through slider 21, and the one end of spout 22 is connected with slider 21 through connecting spring 23.

One end of the ventilation pipe 5 is arranged inside the box body 1, a wind wheel 501 is arranged on the right side, close to the floating ball 6, of the ventilation pipe 5, the inner side of the wind wheel 501 is nested on the outer side of the vertical rod 502, and one end of the vertical rod 502 extends out of the outer side of the ventilation pipe 5 and is connected with a bearing of the box body 1.

The air bag 10 made of elastic materials is arranged on the inner wall of the box body 1, and the distance from the air bag 10 to the circle center of the rotating rod 8 is smaller than the maximum radius of the special-shaped wheel 9.

The first clamping rod 16 and the second clamping rod 18 are both arranged above the first magnet 15, and the first clamping rod 16 and the second clamping rod 18 are movably connected through a movable shaft 17.

Then, with reference to fig. 1-6, firstly, the blower 4 is started, and further the blower 4 is rotated, and further the floating ball 6 disposed inside the ventilation pipe 5 is moved to a certain extent, so that the floating ball 6 drives the rotating rod 8 to rotate through the pulling rope 7, because the top of the rotating rod 8 is provided with the special-shaped wheel 9, and further the special-shaped wheel 9 extrudes one side of the airbag 10, so that the gas inside the airbag 10 flows into the placing groove 12 through the ventilation pipe 11, and further the piston plate 14 disposed inside the placing groove 12 drives the return spring 13 to move, so that the piston plate 14 drives the first magnet 15 to move, because the second magnets 19 are disposed on one side of the first clamping rod 16 and one side of the second clamping rod 18, and the top of the first clamping rod 16 and the top of the second clamping rod 18 are fixed with the connecting rod 20, because the top of the connecting rod 20 extends into the sliding groove 22 through the slider 21, and then the first clamping rod 16 and the second clamping rod 18 rotate through the movable shaft 17, so that the other ends of the first clamping rod 16 and the second clamping rod 18 bundle cables inside the device, and the cables are prevented from being disordered.

The outside diameter of floater 6 and the inner wall diameter phase-match of ventilation pipe 5, floater 6 passes through stay cord 7 and drives bull stick 8 and rotate to for integrated the setting between the top of bull stick 8 and the dysmorphism wheel 9.

The wind wheel 501 is connected with the worm 26 through the transmission device assembly 25, one side of the worm 26 is connected with the worm wheel 27, the inner side of the worm wheel 27 is embedded at the outer side of the air diffusion pipe 28, the outer side of the air diffusion pipe 28 is provided with air diffusion ports 29 at equal intervals, one side of the air diffusion pipe 28 is provided with a limiting groove 30, and the outer side of one end of the ventilation pipe 5 is fixed with a limiting block 31.

The outer side of the limiting block 31 is matched with the inner side of the limiting groove 30, and the air dispersing pipe 28 forms a rotating structure through the limiting block 31 and the limiting groove 30.

The wind wheel 501 and the worm 26 form a linkage structure through the transmission assembly 25, and the worm 26 drives the air dispersing pipe 28 to rotate through the worm wheel 27.

The outer side of the slide block 21 in the shape of the T is in clearance fit with the inner wall of the slide groove 22, and the slide block 21 and the slide groove 22 form an elastic sliding structure through a connecting spring 23.

In order to dissipate heat inside the device, firstly, with reference to fig. 1, fig. 2 and fig. 6-8, firstly, because the wind wheel 501 is arranged inside the ventilation pipe 5, the wind power inside the ventilation pipe 5 drives the wind wheel 501 to rotate, so that the wind wheel 501 drives the vertical rod 502 to rotate effectively, and the floating ball 6 is arranged inside the ventilation pipe 5, when the floating ball 6 moves into the air dissipation pipe 28, the vertical rod 502 will drive the worm 26 to rotate through the transmission device assembly 25, and one side of the worm 26 is provided with the worm wheel 27, because the worm wheel 27 drives the air dissipation pipe 28 to rotate, and the air dissipation ports 29 are arranged at equal intervals outside the air dissipation pipe 28, so that the wind power inside the ventilation pipe 5 dissipates heat to the inside through the air dissipation ports 29, meanwhile, one end of the ventilation pipe 5 is connected with the box body 1 as a bearing, and the other end of the ventilation pipe 5 is connected with the limiting block 31 through the limiting groove 30, the ventilation pipe 5 can stably rotate, and the device can dissipate heat through the heat dissipation plate 3 arranged on the cover plate 2, so that the aim of quickly dissipating heat inside the device can be fulfilled; through the above operations, a series of works are completed.

The working principle of the embodiment is as follows: when the flow monitoring device based on the electric automation is used, firstly, the device is placed at a specified position, firstly, the air blower 4 is started, and then the floating ball 6 arranged in the ventilation pipe 5 is enabled to move to a certain extent, so that the floating ball 6 drives the rotating rod 8 to rotate through the pull rope 7, because the top of the rotating rod 8 is provided with the special-shaped wheel 9, the special-shaped wheel 9 is enabled to extrude one side of the air bag 10, so that the gas in the air bag 10 flows into the placing groove 12 through the ventilation pipe 11, and further the piston plate 14 arranged in the placing groove 12 drives the reset spring 13 to move, so that the piston plate 14 drives the first magnet 15 to move, and further the first clamping rod 16 and the second clamping rod 18 rotate through the movable shaft 17, and therefore the cable is prevented from being disordered; in order to dispel the heat to the device inside, at first, because ventilation pipe 5 is inside to be provided with wind wheel 501, and then make ventilation pipe 5 inside wind-force drive wind wheel 501 rotate, montant 502 will drive worm 26 through transmission assembly 25 and rotate, because worm wheel 27 drives scattered trachea 28 and rotates, the other end of ventilation pipe 5 is connected with stopper 31 through spacing groove 30, and then make the device dispel the heat through the heating panel 3 that apron 2 was seted up, and then reach the inside purpose of dispelling the heat fast, through above operation, thereby accomplish a series of works.

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 various changes in the embodiments and/or modifications of the invention can be made, and equivalents and modifications of some features of the invention can be made without departing from the spirit and scope of the invention.

Claims

1. An electrical automation-based flow monitoring device, comprising:

2. An electrical automation based flow monitoring device as claimed in claim 1 wherein: one end of the ventilation pipe is arranged in the box body, a wind wheel is arranged on the right side, close to the floating ball, of the ventilation pipe, the inner side of the wind wheel is nested in the outer side of the vertical rod, and one end of the vertical rod extends out of the outer side of the ventilation pipe and is connected with a box body bearing.

3. An electrical automation based flow monitoring device as claimed in claim 1 wherein: the air bag made of elastic materials is arranged on the inner wall of the box body, and the distance from the air bag to the circle center of the rotating rod is smaller than the maximum radius of the special-shaped wheel.

4. An electrical automation based flow monitoring device as claimed in claim 1 wherein: the first clamping rod and the second clamping rod are both arranged above the first magnet, and the first clamping rod is movably connected with the second clamping rod through a movable shaft.

5. An electrical automation based flow monitoring device as claimed in claim 1 wherein: the outside diameter of floater and the inner wall diameter phase-match of ventilation pipe, the floater passes through the stay cord and drives the bull stick and rotate to set up as an organic whole between the top of bull stick and the dysmorphism wheel.

6. An electrical automation based flow monitoring device as claimed in claim 2 wherein: the wind wheel is connected with the worm through the transmission device assembly, one side of the worm is connected with the worm wheel, the inner side of the worm wheel is embedded in the outer side of the air diffusion pipe, air diffusion ports are formed in the outer side of the air diffusion pipe at equal intervals, a limiting groove is formed in one side of the air diffusion pipe, and a limiting block is fixed to the outer side of one end of the ventilation pipe.

7. An electrical automation based flow monitoring device as claimed in claim 6 wherein: the outer side of the limiting block is matched with the inner side of the limiting groove, and the air dispersing pipe forms a rotating structure through the limiting block and the limiting groove.

8. An electrical automation based flow monitoring device as claimed in claim 6 wherein: the wind wheel and the worm form a linkage structure through the transmission device assembly, and the worm drives the air dispersing pipe to rotate through the worm wheel.

9. An electrical automation based flow monitoring device as claimed in claim 1 wherein: the outer side of the sliding block is in clearance fit with the inner wall of the sliding groove, and the sliding block forms an elastic sliding structure with the sliding groove through a connecting spring.