CN220119050U

CN220119050U - Power grid real-time monitoring device with rotating structure

Info

Publication number: CN220119050U
Application number: CN202321449316.XU
Authority: CN
Inventors: 庞荣; 任武强; 周韬
Original assignee: Saifu Power Group Co ltd
Current assignee: Saifu Power Group Co ltd
Priority date: 2023-06-08
Filing date: 2023-06-08
Publication date: 2023-12-01
Anticipated expiration: 2033-06-08

Abstract

The utility model relates to the technical field of intelligent power monitoring systems, and discloses a power grid real-time monitoring device with a rotating structure, wherein a power monitor is arranged on an omnibearing rotating mechanism, a first motor on a horizontal rotating assembly drives a first worm to rotate, the first worm is meshed with a first worm wheel to drive a hollow sleeve to rotate, a U-shaped support plate is driven to horizontally rotate, a second motor on a turnover assembly drives a second worm to rotate, the second worm is meshed with a second worm wheel to drive a rotating shaft rod and a first bevel gear to rotate, the first bevel gear is meshed with a second bevel gear on the outer side surface of the rotating shaft rod to drive the rotating shaft rod to rotate, then a monitor fixing panel is driven to turn, the power monitor is fixed on the monitor fixing panel to drive the power monitor to turn, and the U-shaped support plate horizontally rotates with the rotating shaft on the inner side of the U-shaped support plate to drive the power monitor to turn mutually, so that the power monitor can turn in all directions, and the monitoring range can be effectively enlarged.

Description

Power grid real-time monitoring device with rotating structure

Technical Field

The utility model belongs to the technical field of intelligent power monitoring systems, and particularly relates to a power grid real-time monitoring device with a rotating structure.

Background

With the development of society, more and more people are focusing on the power industry. In particular, intelligent monitoring systems are now becoming an integral part of people's daily lives. The principle of the intelligent power monitoring system is to monitor the power consumption condition by monitoring and analyzing the electric energy; the intelligent power monitoring system is used for realizing real-time monitoring and control of the running state of the power grid by utilizing the technologies of sensors, networks and software. The power output level of the power supply can be automatically adjusted according to the changes of the ambient temperature, the voltage and the current, and the panoramic monitoring of the power transmission line is monitored in real time by the power monitor;

in the panoramic monitoring of the electric power monitor, the electric power monitor is installed through the installation frame, the installation frame of the electric power monitor is often composed of a rotating component and a lifting component, the lifting component pushes the electric power monitor to reciprocate and stretch, and the rotating component is used for driving the electric power monitor to horizontally rotate;

when the installation frame is used for installing and fixing the power monitor, the power monitor can only stretch out and draw back and horizontally rotate, and the power monitor cannot be realized in all-round monitoring conditions of the power monitor.

Disclosure of Invention

The utility model aims to provide a power grid real-time monitoring device with a rotating structure, so as to solve the problems in the background technology.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a power grid real-time monitoring device with revolution mechanic, includes the electric power monitor, the electric power monitor is fixed on all-round revolution mechanic;

the omnibearing rotating mechanism comprises a horizontal rotating assembly and a turnover assembly, and the horizontal rotating assembly and the turnover assembly are respectively arranged on the mounting frame;

the horizontal rotating assembly and the overturning assembly are matched with each other to drive the electric power monitor to overturn in horizontal rotation.

Specifically, the mounting frame comprises a base, two inverted L-shaped support plates which are symmetrically and fixedly arranged at the top of the base, a rectangular hollow cover which is fixed between the two inverted L-shaped support plates, two outer turning plates which are symmetrically arranged at the front side and the rear side of the two inverted L-shaped support plates respectively, and two mounting panels which are respectively arranged at the outer sides of the two outer turning plates;

the two mounting panels are both arranged vertically to the outer turning plate.

Preferably, the horizontal rotating assembly comprises a hollow sleeve, a first worm wheel and a first worm, wherein the hollow sleeve is arranged in a manner of penetrating through the rectangular hollow cover in a rotating mode, the first worm wheel and the first worm wheel are fixed at the bottom of the hollow sleeve and are provided with hollow penetrating holes, the first worm is meshed with the first worm wheel and the worm wheel, and a U-shaped support plate is fixed at the top of the hollow sleeve;

the U-shaped support plate is provided with a circular through hole communicated with the hollow sleeve and the hollow penetrating hole.

The first worm is rotationally arranged between the two mounting panels at the left side and driven by a first motor at the top of the base.

The first motor drives the first worm to rotate, the first worm is meshed with the first worm wheel and the worm wheel, the hollow sleeve is driven to rotate, and the U-shaped support plate is driven to horizontally rotate;

preferably, the overturning assembly comprises a second worm gear positioned below the first worm gear, a rotating shaft rod which is fixed at the top of the second worm gear and penetrates through the hollow insertion hole, the hollow sleeve and the circular through hole and is rotationally connected with the U-shaped support plate, a first bevel gear which is fixed at the top of the rotating shaft rod and is positioned at the inner side of the U-shaped support plate, a rotating rod which is rotationally arranged at the inner side of the U-shaped support plate, a second bevel gear which is fixedly arranged at the outer side surface of the rotating rod and is meshed with the first bevel gear, and a second worm which is meshed with the second worm gear;

the utility model discloses a power monitoring instrument, including the dwang, the dwang is last to be fixed to be equipped with the fixed block, the fixed block passes through connecting rod and monitor fixed panel fixed connection, the power monitoring instrument is fixed on monitor fixed panel.

The second worm is rotationally arranged between the two mounting panels positioned on the right side and driven by a second motor at the top of the base.

The second motor drives the second worm to rotate, the second worm is meshed with the second worm wheel and the worm wheel, the rotating shaft rod and the first bevel gear are driven to rotate, the first bevel gear is meshed with the second bevel gear on the outer side face of the rotating shaft, the rotating shaft is driven to rotate, the monitor fixing panel is driven to turn over, the power monitor is fixed on the monitor fixing panel, and the power monitor is driven to turn over.

When the U-shaped support plate on the horizontal rotating assembly horizontally rotates, the rotating rod on the overturning assembly is matched to rotate and overturn, so that the electric power monitor overturns in the horizontal rotation, and the electric power monitor can monitor the condition of the power transmission line in an omnibearing manner.

The utility model has the technical effects and advantages that:

the electric power monitor is arranged on the omnibearing rotary mechanism, and the horizontal rotary component and the overturning component on the omnibearing rotary mechanism are mutually matched to drive the electric power monitor to overturn in horizontal rotation, so that the omnibearing monitoring condition of the electric power monitor can be obtained according to the requirement, and compared with the monitor which can only stretch out and draw back and move horizontally in the prior art, the electric power monitor can effectively expand the monitoring range;

the first motor on the horizontal rotating assembly drives the first worm to rotate, the first worm is meshed with the first worm wheel and the worm wheel, the hollow sleeve is driven to rotate, the U-shaped support plate is driven to horizontally rotate, the second motor on the overturning assembly drives the second worm to rotate, the second worm is meshed with the second worm wheel and the worm wheel, the rotating shaft rod and the first bevel gear are driven to rotate, the first bevel gear is meshed with the second bevel gear on the outer side face of the rotating shaft, the rotating shaft is driven to rotate, the monitor fixing panel is driven to overturn, the electric monitor is fixed on the monitor fixing panel, the electric monitor is driven to overturn, and the U-shaped support plate horizontally rotates to drive the electric monitor to overturn mutually with the rotating shaft on the inner side of the U-shaped support plate, so that the electric monitor can overturn towards all directions.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a schematic view of the omni-directional rotating mechanism of the present utility model;

FIG. 3 is a schematic view of a horizontal rotation assembly according to a first view angle;

FIG. 4 is a schematic view of a horizontal rotation assembly according to a second view angle;

fig. 5 is a schematic structural view of the flipping assembly of the present utility model.

In the figure:

1. a power monitor;

2. an omnibearing rotary mechanism;

a mounting frame; 301. a base; 302. an inverted L-shaped support plate; 303. a rectangular hollow cover; 304. an outer turning plate; 305. installing a panel;

a hollow sleeve; 402. a hollow insertion hole; 403. a first worm wheel and worm wheel; 404. a first worm; 405. a U-shaped support plate; 406. a circular through hole; 407. a first motor;

501. a second worm wheel and worm wheel; 502. a rotating shaft lever; 503. a first bevel gear; 504. a rotating lever; 505. a second worm; 506. a fixed block; 507. a connecting rod; 508. a monitor fixing panel; 509. a second motor; 510. and a second bevel gear.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

The utility model provides a power grid real-time monitoring device with a rotating structure, as shown in figures 1-5, which comprises a power monitor 1, wherein the power monitor 1 is fixed on an all-direction rotating mechanism 2;

the omnibearing rotary mechanism 2 comprises a horizontal rotary component and a turnover component, wherein the horizontal rotary component and the turnover component are respectively arranged on the mounting frame 3;

the horizontal rotating assembly and the overturning assembly are matched with each other to drive the power monitor 1 to overturn in horizontal rotation.

The electric power monitor 1 is installed on all-round rotary mechanism 2, drives electric power monitor 1 through horizontal rotation subassembly and the upset subassembly on all-round rotary mechanism 2 mutually support and overturn in horizontal rotation, can acquire the monitoring situation of electric power monitor all-round as required, compares with the monitor that can only flexible and horizontal rotary motion of conventional art, can effectual expansion monitoring scope.

Specifically, the mounting rack 3 includes a base 301, two inverted L-shaped support plates 302 symmetrically and laterally fixed on the top of the base 301, a rectangular hollow cover 303 fixed between the two inverted L-shaped support plates 302, two outer turning plates 304 symmetrically and respectively arranged on the front and rear sides of the two inverted L-shaped support plates 302, and two mounting panels 305 respectively arranged on the outer sides of the two outer turning plates 304;

both mounting panels 305 are disposed perpendicular to the outer flap 304.

Specifically, the horizontal rotation assembly includes a hollow sleeve 401 rotatably penetrating through the rectangular hollow cover 303, a first worm wheel 403 fixed at the bottom of the hollow sleeve 401 and provided with a hollow insertion hole 402, a first worm 404 meshed with the first worm wheel 403, and a U-shaped support plate 405 fixed at the top of the hollow sleeve 401;

the U-shaped support plate 405 is provided with a circular through hole 406 which is communicated with the hollow sleeve 401 and the hollow penetrating hole 402.

The first worm 404 is rotatably disposed between the two mounting panels 305 positioned at the left side, and the first worm 404 is driven by a first motor 407 at the top of the base 301.

As shown in fig. 3-4, a first motor 407 on the horizontal rotating assembly drives a first worm 404 to rotate, and the first worm 404 is meshed with a first worm wheel and worm wheel 403 to drive a hollow sleeve 401 to rotate and drive a U-shaped support plate 405 to horizontally rotate;

specifically, the turnover assembly includes a second worm gear 501 located below the first worm gear 403, a rotating shaft rod 502 fixed on the top of the second worm gear 501 and penetrating through the hollow insertion hole 402, the hollow sleeve 401 and the circular through hole 406 and rotationally connected with the U-shaped support plate 405, a first bevel gear 503 fixed on the top of the rotating shaft rod 502 and located inside the U-shaped support plate 405, a rotating rod 504 rotationally located inside the U-shaped support plate 405, a second bevel gear 510 fixedly located on the outer side of the rotating rod 504 and meshed with the first bevel gear 503, and a second worm 505 meshed with the second worm gear 501;

the fixed block 506 is fixedly arranged on the rotating rod 504, the fixed block 506 is fixedly connected with the monitor fixing panel 508 through the connecting rod 507, and the power monitor 1 is fixed on the monitor fixing panel 508.

The second worm 505 is rotatably disposed between the two mounting panels 305 on the right side, and the second worm 505 is driven by a second motor 509 on top of the base 301.

As shown in fig. 5, a second motor 509 on the turnover assembly drives a second worm 505 to rotate, and after the second worm 505 is meshed with a second worm gear 501, the second worm 505 drives a rotating shaft rod 502 and a first bevel gear 503 to rotate, the first bevel gear 503 is meshed with a second bevel gear 510 on the outer side surface of a rotating rod 504, the rotating rod 504 is driven to rotate, then a monitor fixing panel 508 is driven to turn, and the power monitor 1 is fixed on the monitor fixing panel 508 to drive the power monitor 1 to turn.

When the U-shaped support plate 405 on the horizontal rotating assembly horizontally rotates, the turning rod 504 on the turning assembly is matched to rotate and turn, so that the electric power monitor 1 turns in the horizontal rotation, and the electric power monitor 1 can monitor the condition of the power transmission line in an omnibearing manner.

Finally, it should be noted that: the foregoing description is only illustrative of the preferred embodiments of the present utility model, and although the present utility model 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 described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements or changes may be made without departing from the spirit and principles of the present utility model.

Claims

1. The utility model provides a power grid real-time monitoring device with revolution mechanic, includes electric power monitor (1), its characterized in that: the power monitor (1) is fixed on the all-direction rotating mechanism (2);

the omnibearing rotary mechanism (2) comprises a horizontal rotary component and a turnover component, wherein the horizontal rotary component and the turnover component are respectively arranged on the mounting frame (3);

the horizontal rotating assembly and the overturning assembly are matched with each other to drive the electric power monitor (1) to overturn in horizontal rotation.

2. A power grid real-time monitoring device with a rotating structure according to claim 1, characterized in that: the mounting frame (3) comprises a base (301), two inverted L-shaped support plates (302) symmetrically and horizontally arranged at the top of the base (301), a rectangular hollow cover (303) fixed between the two inverted L-shaped support plates (302), two outer turning plates (304) symmetrically arranged at the front side and the rear side of the two inverted L-shaped support plates (302) respectively, and two mounting panels (305) arranged at the outer sides of the two outer turning plates (304) respectively;

both mounting panels (305) are arranged perpendicular to the outer flap (304).

3. A power grid real-time monitoring apparatus with a rotary structure according to claim 2, characterized in that: the horizontal rotating assembly comprises a hollow sleeve (401) which is arranged in a manner of penetrating through a rectangular hollow cover (303), a first worm wheel (403) which is fixed at the bottom of the hollow sleeve (401) and provided with a hollow penetrating hole (402), a first worm (404) meshed with the first worm wheel (403), and a U-shaped support plate (405) which is fixed at the top of the hollow sleeve (401);

the U-shaped support plate (405) is provided with a circular through hole (406) communicated with the hollow sleeve (401) and the hollow penetrating hole (402).

4. A power grid real-time monitoring device with a rotating structure according to claim 3, characterized in that: the overturning assembly comprises a second worm wheel (501) positioned below the first worm wheel (403), a rotating shaft rod (502) fixed at the top of the second worm wheel (501) and penetrating through the hollow insertion hole (402), the hollow sleeve (401) and the circular through hole (406) and rotationally connected with the U-shaped support plate (405), a first bevel gear (503) fixed at the top of the rotating shaft rod (502) and positioned at the inner side of the U-shaped support plate (405), a rotating rod (504) rotationally arranged at the inner side of the U-shaped support plate (405), a second bevel gear (510) fixedly arranged at the outer side surface of the rotating rod (504) and meshed with the first bevel gear (503) and a second worm (505) meshed with the second worm wheel (501);

the utility model discloses a power monitoring instrument, including power monitoring instrument, dwang (504) are fixed on, be equipped with fixed block (506) on dwang (504), fixed block (506) are through connecting rod (507) and monitor fixed panel (508) fixed connection, power monitoring instrument (1) is fixed on monitor fixed panel (508).

5. A power grid real-time monitoring device with a rotating structure according to claim 3, characterized in that: the first worm (404) is rotatably arranged between the two mounting panels (305) positioned on the left side, and the first worm (404) is driven by a first motor (407) at the top of the base (301).

6. The power grid real-time monitoring device with rotating structure according to claim 4, wherein: the second worm (505) is rotatably arranged between the two mounting panels (305) positioned on the right side, and the second worm (505) is driven by a second motor (509) arranged on the top of the base (301).