CN212875067U - Reactive power equipment monitoring control device based on thing networking - Google Patents

Abstract

The utility model discloses a reactive power equipment monitor control device based on thing networking, including the monitor control device casing, the up end of monitor control device casing evenly is provided with four and accomodates the draw-in groove, the preceding terminal surface fixed mounting of monitor control device casing has display screen, operating panel is installed to one side of display screen, the top movable mounting of monitor control device casing has movable roof, movable roof's bottom surface evenly is provided with four grafting spouts, the inboard movable mounting of grafting spout has L shape connecting block, the outside fixed mounting of L shape connecting block has the separation slider, the one end fixed mounting of L shape connecting block has the guide bar. The utility model discloses an install lift heat dissipation baffle, hidden louvre, lift ejector pin and screw thread stand and can increase the holistic radiating efficiency of device, avoid the device to break down because overheated when the operation, simple structure, convenient operation.

Description

Reactive power equipment monitoring control device based on thing networking

Technical Field

The utility model relates to a power grid safety monitoring technical field specifically is a reactive power equipment monitoring control device based on thing networking.

Background

With the rapid development of social economy, a power grid refers to a power grid, and a whole consisting of substations of various voltages and power transmission and distribution lines in a power system is called as a power grid and comprises three units of power transformation, power transmission and power distribution, the power grid is used for transmitting and distributing electric energy and changing voltage, 6, 10, 20, 35 and 66 kilovolts in the power transmission and distribution voltage class are medium voltages, 110 and 220 kilovolts are high voltages, 330, 500 and 750 kilovolts are ultrahigh voltages, and 800 and 1000 kilovolts of alternating current and more than 1000 kilovolts are ultrahigh voltages, and a reactive equipment monitoring and controlling device refers to an intelligent ammeter type device for carrying out intelligent monitoring and auxiliary control on reactive compensation equipment.

However, when the existing reactive power equipment monitoring and controlling device is used, heat dissipation can be performed only through the heat dissipation holes of the equipment, so that the heat dissipation effect is poor, and faults are easy to occur due to overheating; therefore, the existing requirements are not met, and the reactive power equipment monitoring and controlling device based on the Internet of things is provided for the requirements.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a reactive power equipment monitoring control device based on thing networking to solve the current reactive power equipment monitoring control device that provides in the above-mentioned background art and using, can only dispel the heat through the louvre of equipment from the area, the radiating effect is poor, easy because overheated breaking down scheduling problem.

In order to achieve the above object, the utility model provides a following technical scheme: a reactive power equipment monitoring control device based on the Internet of things comprises a monitoring control device shell, wherein four containing clamping grooves are uniformly formed in the upper end face of the monitoring control device shell, a display screen is fixedly mounted on the front end face of the monitoring control device shell, an operating panel is mounted on one side of the display screen, a movable top plate is movably mounted above the monitoring control device shell, four inserting sliding grooves are uniformly formed in the bottom face of the movable top plate, an L-shaped connecting block is movably mounted on the inner side of each inserting sliding groove, a separating sliding block is fixedly mounted on the outer side of each L-shaped connecting block, a guide rod is fixedly mounted at one end of each L-shaped connecting block, a separation-preventing spring is arranged on the outer side of each guide rod, a lifting motor is mounted inside the monitoring control device shell, and a lifting motor gear is fixedly, drive gear is installed to the top of elevator motor gear, drive gear's centre is run through fixed mounting and is had transmission worm, transmission worm's both ends are all installed transmission turbine with one side, transmission turbine's centre is run through fixed mounting and is had the screw thread stand, the upper end outside movable mounting of screw thread stand has the lift ejector pin, two the upper end fixed mounting of lift ejector pin has lift heat-radiating baffle, lift heat-radiating baffle's surface evenly is provided with the hidden louvre of a plurality of, four magnets are evenly installed to lift heat-radiating baffle's inside.

Preferably, the bottom of the lifting ejector rod is provided with a connecting through hole, the inner side of the connecting through hole and the outer surface of the threaded upright post are provided with threads with the same turning directions, and the threaded upright post is in threaded connection with the lifting ejector rod.

Preferably, the upper end face of the threaded upright post is fixedly provided with a limiting ring, the limiting ring is connected with the lifting ejector rod in a sliding manner, and the outer side of the bottom end of the threaded upright post is provided with a ball bearing.

Preferably, the magnetic attraction force of the magnet to the guide rod is greater than the elastic potential energy of the separation-preventing spring compressed by the L-shaped connecting block.

Preferably, one end of the separation sliding block is completely attached to one side of the L-shaped connecting block, and the L-shaped connecting block and the separation sliding block are integrally formed by injection molding.

Preferably, the upper end of the lifting ejector rod is completely attached to the lower surface of the lifting heat dissipation baffle, and the lifting ejector rod and the lifting heat dissipation baffle are fixed through welding.

Preferably, a guide sliding groove is formed in the middle of one end of the guide rod and the magnet, and the outer side of the end portion of the guide rod is completely attached to the inner side of the guide sliding groove.

Compared with the prior art, the beneficial effects of the utility model are that:

1. the utility model discloses a switch-on starts elevator motor, elevator motor can make drive gear and rotate with the drive gear fixed transmission worm through driving elevator motor gear rotation after starting, and can make the screw thread stand rotate synchronously through transferring the rotation of transmission turbine when rotating, can drive the lift ejector pin through the connection with the side screw thread in the lift ejector pin bottom connecting through-hole to jack up upwards when the screw thread stand rotates, make the lift ejector pin drive lift heat dissipation baffle and activity roof jack up upwards synchronously, make the hidden louvre of lift heat dissipation baffle surface expose in the air, can increase the heat transfer passageway of device and external environment, can distribute the large amount of heats that the device internal component length of operation produced fast, protect the device, avoid the device to break down because of overheated;

2. the utility model discloses a damage appears losing at the device, can drive L shape connecting block through the sliding separation slider and slide in grafting spout inside, make the tip of L shape connecting block separate from the link of grafting spout, L shape connecting block drives the guide bar simultaneously and makes L shape connecting block compress to preventing the separation spring to the magnet laminating, until guide bar and magnet laminating by magnet adsorption, once to four separation slider repetitive operation, can be quick separate movable roof and lift heat radiation baffle, show the device internal component completely, make things convenient for the staff to overhaul, maintain or change parts.

Drawings

Fig. 1 is a schematic overall structure diagram of the present invention;

FIG. 2 is a schematic view of the overall structure of the present invention;

fig. 3 is a sectional view of the housing of the monitoring and control device of the present invention;

fig. 4 is a schematic structural diagram of a point a in fig. 3 according to the present invention.

In the figure: 1. a monitoring control device housing; 2. a movable top plate; 3. a display screen; 4. an operation panel; 5. lifting the heat dissipation baffle; 6. hidden heat dissipation holes; 7. a storage slot; 8. separating the slide block; 9. lifting the ejector rod; 10. a threaded upright post; 11. a drive turbine; 12. a drive scroll bar; 13. a lifting motor; 14. a lift motor gear; 15. a transmission gear; 16. a magnet; 17. a guide bar; 18. an L-shaped connecting block; 19. inserting the chute; 20. and a separation prevention spring.

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.

Referring to fig. 1 to 4, the present invention provides an embodiment: a reactive power equipment monitoring control device based on the Internet of things comprises a monitoring control device shell 1, wherein four containing clamping grooves 7 are uniformly formed in the upper end face of the monitoring control device shell 1, a display screen 3 is fixedly installed on the front end face of the monitoring control device shell 1, an operation panel 4 is installed on one side of the display screen 3, a movable top plate 2 is movably installed above the monitoring control device shell 1 and can be quickly disassembled, and the device is convenient to overhaul, maintain or replace, four inserting and connecting chutes 19 are uniformly formed in the bottom face of the movable top plate 2, an L-shaped connecting block 18 is movably installed on the inner side of each inserting and connecting chute 19, a separating slide block 8 is fixedly installed on the outer side of each L-shaped connecting block 18, a guide rod 17 is fixedly installed at one end of each L-shaped connecting block 18, an anti-separating spring 20 is arranged on the outer side of each, lifting motor 13's front end fixed mounting has lifting motor gear 14, drive gear 15 is installed to lifting motor gear 14's top, drive gear 15's centre is run through fixed mounting and is had transmission worm 12, transmission worm 12's both ends are all installed with one side transmission worm 11, transmission worm 11's centre is run through fixed mounting and is had screw thread stand 10, screw thread stand 10's upper end outside movable mounting has lift ejector pin 9, two lift ejector pin 9's upper end fixed mounting has lift heat sink 5, lift heat sink 5's surface evenly is provided with the hidden louvre 6 of a plurality of, can be quick give off a large amount of heats that produce when installing interior component during operation, protect the device, avoid the device to break down because of overheated, four magnet 16 are evenly installed to the inside of lift heat sink 5. The lifting motor 13 (model number ncv28-400-60C) can be purchased from market or customized.

Furthermore, the bottom end of the lifting ejector rod 9 is provided with a connecting through hole, the inner side of the connecting through hole and the outer surface of the threaded upright post 10 are both provided with threads with the same turning direction, and the threaded upright post 10 is in threaded connection with the lifting ejector rod 9.

Through adopting above-mentioned technical scheme, threaded connection makes threaded column 10 can drive lift ejector pin 9 jack-up when rotating for inside lifting heat radiation baffle 5 stretches out monitoring control device casing 1, the speed-up heat dissipation.

Furthermore, the upper end face of the threaded upright post 10 is fixedly provided with a limiting ring, the limiting ring is connected with the lifting ejector rod 9 in a sliding manner, and the outer side of the bottom end of the threaded upright post 10 is provided with a ball bearing.

Through adopting above-mentioned technical scheme, the spacing ring can restrict the whole of lift ejector pin 9 and form, guarantees that the device can not break down in the use, and ball bearing is convenient for threaded column 10 and is carried out free rotation.

Further, the magnetic attraction force of the magnet 16 to the guide rod 17 is greater than the elastic potential energy of the separation preventing spring 20 compressed by the L-shaped connecting block 18.

Through adopting above-mentioned technical scheme, the elastic potential energy that magnetic adsorption power is greater than and prevents separating spring 20 makes L shape connecting block 18 can not reset after guide bar 17 and 16 contact of magnet, guarantees that the separation operation of activity roof 2 and lift heat radiation baffle 5 goes on smoothly.

Further, one end of the separating sliding block 8 is completely attached to one side of the L-shaped connecting block 18, and the L-shaped connecting block 18 and the separating sliding block 8 are integrally formed through injection molding.

By adopting the technical scheme, the integrated injection molded part has the advantages of intact integrity, high mechanical strength, no easy occurrence of fracture and damage, convenient manufacture and low cost.

Further, the upper end of the lifting ejector rod 9 is completely attached to the lower surface of the lifting heat dissipation baffle 5, and the lifting ejector rod 9 and the lifting heat dissipation baffle 5 are fixed through welding.

By adopting the technical scheme, the welding enhances the connection performance and the stability of the lifting ejector rod 9 and the lifting radiating baffle 5, has good mechanical strength, and cannot be easily separated in the use process.

Furthermore, a guide sliding groove is formed between one end of the guide rod 17 and the magnet 16, and the outer side of the end part of the guide rod 17 is completely attached to the inner side of the guide sliding groove.

Through adopting above-mentioned technical scheme, the tip of guide bar 17 is pegged graft inside the direction spout, can avoid L shape connecting block 18 to appear droing, and can lead and fix a position L shape connecting block 18's removal.

The working principle is as follows: when the device is used, when overheating occurs during operation of the device, the lifting motor 13 can be connected and started, after the lifting motor 13 is started, the transmission gear 15 and the transmission worm 12 fixed with the transmission gear 15 can be rotated by driving the lifting motor gear 14 to rotate, when the transmission worm 12 rotates, the transmission worm 11 can be moved to rotate so as to synchronously rotate the threaded upright post 10, when the threaded upright post 10 rotates, the lifting ejector 9 can be driven to jack up the lifting ejector 9 through the connection with the inner side threads of the connecting through hole at the bottom end of the lifting ejector 9, so that the lifting ejector 9 drives the lifting heat dissipation baffle 5 and the movable top plate 2 to jack up synchronously, the hidden heat dissipation holes 6 on the outer surface of the lifting heat dissipation baffle 5 are exposed in the air, the heat exchange channel between the device and the external environment can be increased, a large amount of heat generated during the operation of internal elements of the device can, avoid the device to break down because of overheated, damage loses appears in the device, can drive L shape connecting block 18 and slide in grafting spout 19 inside through sliding separation slider 8, make L shape connecting block 18's tip follow grafting spout 19 link separation, L shape connecting block 18 drives guide bar 17 and makes L shape connecting block 18 compress to preventing separation spring 20 to magnet 16 laminating simultaneously, until guide bar 17 and magnet 16 laminating are adsorbed by magnet 16, once to four separation sliders 8 repetitive operation, can be quick separate movable roof 2 and lift heat baffle 5, show device internal component completely, make things convenient for the staff to overhaul, maintain or change the part, moreover, the steam generator is simple in structure, and convenient for operation.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.

Claims (7)

1. The utility model provides a reactive power equipment monitoring control device based on thing networking, includes the monitoring control device casing, its characterized in that: the upper end face of the monitoring and control device shell is uniformly provided with four containing clamping grooves, the front end face of the monitoring and control device shell is fixedly provided with a display screen, one side of the display screen is provided with an operating panel, the upper part of the monitoring and control device shell is movably provided with a movable top plate, the bottom surface of the movable top plate is uniformly provided with four splicing chutes, the inner sides of the splicing chutes are movably provided with an L-shaped connecting block, the outer side of the L-shaped connecting block is fixedly provided with a separation sliding block, one end of the L-shaped connecting block is fixedly provided with a guide rod, the outer side of the guide rod is provided with a separation-preventing spring, the inside of the monitoring and control device shell is provided with a lifting motor, the front end of the lifting motor is fixedly provided with a lifting motor gear, a transmission gear is arranged above, the utility model discloses a lifting heat dissipation device, including transmission scroll bar, fixed mounting, lifting ejector pin, lifting heat dissipation baffle, four magnets, transmission worm rod, fixed mounting is run through to transmission worm rod's centre, the upper end outside movable mounting of screw thread stand has the lifting ejector pin, two the upper end fixed mounting of lifting ejector pin has the lifting heat dissipation baffle, the surface of lifting heat dissipation baffle evenly is provided with the hidden louvre of a plurality of, four magnets.

2. The reactive power equipment monitoring and controlling device based on the Internet of things according to claim 1, characterized in that: the bottom of lift ejector pin is provided with connect the via hole, connect the via hole's inboard and the surface of screw thread stand all be provided with the screw thread that turns to the same completely, screw thread stand passes through threaded connection with the lift ejector pin.

3. The reactive power equipment monitoring and controlling device based on the Internet of things according to claim 1, characterized in that: the upper end face of the threaded stand column is fixedly provided with a limiting ring, the limiting ring is connected with the lifting ejector rod in a sliding mode, and a ball bearing is arranged on the outer side of the bottom end of the threaded stand column.

4. The reactive power equipment monitoring and controlling device based on the Internet of things according to claim 1, characterized in that: the magnetic adsorption force of the magnet to the guide rod is larger than the elastic potential energy of the separation-preventing spring compressed by the L-shaped connecting block.

5. The reactive power equipment monitoring and controlling device based on the Internet of things according to claim 1, characterized in that: one end of the separation sliding block is completely attached to one side of the L-shaped connecting block, and the L-shaped connecting block and the separation sliding block are integrally formed through injection molding.

6. The reactive power equipment monitoring and controlling device based on the Internet of things according to claim 1, characterized in that: the upper end of the lifting ejector rod is completely attached to the lower surface of the lifting heat dissipation baffle, and the lifting ejector rod is fixed with the lifting heat dissipation baffle through welding.

7. The reactive power equipment monitoring and controlling device based on the Internet of things according to claim 1, characterized in that: the middle of the one end of guide bar and magnet is provided with the direction spout, the tip outside of guide bar and the inboard of direction spout laminate completely.

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