CN218449608U - Integrated overhead monitoring platform for overhead transmission line - Google Patents

Abstract

The utility model provides an overhead transmission line integration high altitude monitoring platform, include: the box body and the built-in integrated box are integrated; the box body is fastened on the cross arm of the angle steel tower of the power transmission line; the built-in integrated box is arranged inside the box body; the built-in integrated box is used for integrated installation of all data monitoring components to realize integration; the utility model discloses a thereby will not see and the module is all integrated as an organic whole has satisfied the operating mode demand of each module, can carry out the unified integrated processing to the data that the monitoring obtained, has reduced high altitude construction's complexity, effectual reduction safety risk.

Description

Integrated overhead monitoring platform for overhead transmission line

Technical Field

The utility model belongs to the technical field of the electric wire netting control, concretely relates to overhead transmission line integration high altitude monitoring platform.

Background

With the rapid development of high-voltage power grid construction, power is transmitted to thousands of households through a power grid, and conductor laying is normalized. However, in the process of laying the wires, there are many factors that influence the smooth completion of the laying of the wires, and in order to ensure the normal operation of the whole laying process, a monitoring system is usually needed to monitor the data of the tractor, the tensioner, the monitoring pulley, the traction plate and the centralized control center. However, most of the traditional traction fields and tension fields adopt a plurality of independent monitoring systems, the fields, the running boards and the pulleys for paying off are respectively monitored, the functions are dispersed, operators need to manage a plurality of running backgrounds simultaneously, and the monitoring management difficulty is high.

SUMMERY OF THE UTILITY MODEL

For overcoming the not enough of above-mentioned prior art, the utility model provides an overhead transmission line integration high altitude monitoring platform, include: the box body and the built-in integrated box are integrated;

the box body is fastened on the cross arm of the angle steel tower of the power transmission line;

the built-in integrated box is arranged inside the box body; the built-in integrated box is used for integrated installation of all data monitoring components to realize integration;

the built-in data monitoring part that establishes in integrated integrative case includes: the system comprises an industrial AP, an 8-port exchanger, an equipment management module, a micro gateway and a centralized control center;

the industrial AP is used for receiving the video monitoring of the stretching machine and the data of the pulley camera and transmitting the data to the 8-port exchanger through a network cable;

the 8-port switch is used for sending and receiving instructions;

the micro gateway is used for receiving data of monitoring a traction plate, pulling force of a pulley hanging point and data of monitoring a pulley posture, transmitting the data to the 8-port exchanger through a network cable, and controlling the pan-tilt camera through micro-power communication;

the micro gateway is also connected with an equipment management module, and the equipment management module is used for managing the pan-tilt camera;

the centralized control center communicates through a built-in micropower communication module to obtain a power-on and power-off instruction of the pan-tilt camera.

Preferably, an integrated power supply unit is further arranged on the box body and used for supplying power to the data monitoring component in the built-in integrated box.

Preferably, the integrated power supply unit includes: the system comprises a power supply module, a solar panel, a miniature wind driven generator and a power supply management module;

the power supply module, the solar panel and the miniature wind driven generator are respectively connected to the power supply management module;

the power management module and the power module are arranged in the built-in integrated box;

the solar panel and the miniature wind driven generator are arranged on the outer surface of the box body.

Preferably, the case includes: the front surface, the back surface and the side surface of the box body;

the front side of the box body is provided with an access door, and the upper end of the back side of the box body is provided with a fixed connecting frame;

the upper top surface of the box body is provided with a hoisting frame and a miniature wind driven generator, and the lower bottom surface of the box body is provided with a vertical support.

Preferably, the fixed connecting frames are two groups arranged at intervals.

Preferably, the hoisting frames are symmetrically arranged in two groups, the hoisting frames are respectively arranged on two sides of the upper top surface of the box body, and the miniature wind driven generator is arranged on one side of the upper top surface of the box body and is arranged at intervals with the hoisting frames.

Preferably, the back of the box body is also welded with directional bridge fixing frames near the bottom end, and the two groups of directional bridge fixing frames are arranged at intervals.

Preferably, the solar panels are provided with two groups, and the two groups of solar panels are respectively arranged on two sides of the box body;

the solar panel is divided into two parts, wherein one part is arranged on the solar tray, and the other part is fixed on the side wall of the box body;

the solar tray is located at a position, close to the bottom end, of the side face of the box body and is connected with the box body through a hinge, an inclined support is hinged to the bottom of the solar tray, and a vertical support is hinged to the other end of the inclined support.

Preferably, four groups of vertical supports are arranged, and the four groups of vertical supports are respectively arranged at four corners of the lower bottom surface of the box body.

Preferably, the lower bottom surface of the box body is also provided with a pan-tilt camera and a network bridge pan-tilt, the pan-tilt camera and the network bridge pan-tilt are respectively arranged on two sides of the lower bottom surface of the box body and are arranged at intervals with the vertical support, and the lower surface of the network bridge pan-tilt is fixed with a network bridge through bolts;

the network bridge is connected between the 8-port switch and the centralized control center, and is used for transferring the instructions sent and received by the 8-port switch and transmitting the data controlled by the stretching machine to the centralized control center.

Compared with the closest prior art, the utility model discloses the beneficial effect who has as follows:

the utility model provides an integrated monitoring platform for overhead transmission lines, which comprises a box body and a built-in integrated box; the box body is fastened on the cross arm of the angle steel tower of the power transmission line; the built-in integrated box is arranged inside the box body; the built-in integrated box is used for integrated installation of all data monitoring components to realize integration; the utility model discloses a thereby will not see and the module is all integrated as an organic whole has satisfied the operating mode demand of each module, can carry out the unified integrated processing to the data that the monitoring obtained, has reduced high altitude construction's complexity, effectual reduction safety risk.

Drawings

Fig. 1 is a schematic diagram of the integrated monitoring platform box body of the overhead transmission line of the utility model;

fig. 2 is a schematic diagram of the back of the integrated monitoring platform box body of the overhead transmission line of the utility model;

fig. 3 is a schematic structural diagram of the integrated monitoring platform system for overhead transmission lines of the present invention;

fig. 4 is the utility model discloses overhead transmission line integration monitoring platform box unoperated state schematic diagram.

Description of the reference numerals:

1-built-in integrated box; 2-a miniature wind-driven generator; 3-fixing a connecting frame; 4-a box body; 5-hoisting frame; 6-solar panel; 7-a solar tray; 8-a diagonal brace; 9-vertical support; 10-a pan-tilt camera; 11-bridge pan-tilt; 12-a bridge; 13-an access door; 14-directional bridge mount; 15-a power supply module; 16-a power management module; 17-industrial AP; 18-a device management module; 19-a micro gateway; 20-8 port exchanger; 21-a centralized control center; 22-video monitoring of the stretching machine; 23-a sled camera; 24-traction plate monitoring; 25-pulley hanging point tension; 26-tackle attitude monitoring; and 27-controlling a stretching machine.

Detailed Description

The following describes the embodiments of the present invention in further detail with reference to the attached drawings.

Example 1:

as shown in fig. 1, the utility model provides an overhead transmission line integration high altitude monitoring platform includes: the box body 4 and the built-in integrated box 1; the box body 4 is fastened on a cross arm of the angle steel tower of the power transmission line; the built-in integrated box 1 is arranged inside the box body 4; the built-in integrated box 1 is used for integrated installation of each data monitoring component, and integration is achieved.

When the integrated high-altitude monitoring platform is installed, the integrated high-altitude monitoring platform is arranged on a cross arm of an angle steel tower of a power transmission line in an overhead mode, the integrated high-altitude monitoring platform is internally provided with an integrated box 1 which is used for monitoring a high-altitude line, transmitting monitored data to the monitoring platform and carrying out control on the power transmission line.

As shown in fig. 2, specifically, the box 4 includes: the front surface of the box body 4, the back surface of the box body 4 and the side surface of the box body 4;

the front side of the box body 4 is provided with an access door 13, and the upper end of the back side of the box body 4 is provided with a fixed connecting frame 3;

the upper top surface of the box 4 is provided with a hoisting frame 5 and a miniature wind driven generator 2, and the lower bottom surface of the box 4 is provided with a vertical support 9.

Specifically, the fixed connecting frames 3 are two groups arranged at intervals.

Specifically, the hoisting frames 5 are symmetrically arranged in two groups, the hoisting frames 5 are respectively arranged on two sides of the upper top surface of the box body 4, and the miniature wind driven generator 2 is arranged on one side of the upper top surface of the box body 4 and is arranged at intervals with the hoisting frames 5.

The side of box 4 is equipped with access door 13, can overhaul each inside subassembly of box 4 through access door 13, the dismantlement work to box 4 has been avoided, reduce the operating frequency of construction and maintainer aerial work, box 4 is fixed in on the transmission line angle-bar tower through fixed connection frame 3 and hoist and mount frame 5, can closely monitor transmission line, in time receive data feedback and make response and adjustment, fixed connection frame 3 and hoist and mount frame 5 all are equipped with two sets of balances that are used for keeping box 4 and fall in order to avoid the high altitude.

As shown in fig. 3, specifically, the built-in data monitoring component in the built-in all-in-one box 1 includes: the system comprises an industrial AP17, an 8-port switch 20, an equipment management module 18, a micro gateway 19 and a centralized control center;

the industrial AP17 is used for receiving the video monitoring 22 of the stretching machine and the pulley camera 23 and forwarding the videos to the 8-port exchanger 20 through a network cable;

the 8-port switch 20 is used for sending and receiving instructions;

the micro gateway 19 is used for receiving data of a traction plate monitoring 24, a pulley hanging point tension 25 and a pulley attitude monitoring 26, forwarding the data to the 8-port exchanger 20 through a network cable, and controlling the pan-tilt camera 10 through micro-power communication;

the micro gateway 19 is further connected to an equipment management module 18, and the equipment management module 18 is used for managing the pan-tilt-zoom camera 10;

the centralized control center performs communication through a built-in micropower communication module to obtain a power-on and power-off instruction of the pan-tilt camera 10.

The integrated management realizes the integrated installation of each component of a power module, a power management module, a photovoltaic power generation module, a wind power generation module, an industrial AP, a network bridge cradle head, an 8-port exchanger, an equipment management module, a micro gateway, a cradle head camera, a network bridge and a centralized control center, and meets the working condition requirements of each module; in the monitoring process, the micro gateway 19 controls the start and the close of the pan-tilt camera 10, the integrated high altitude monitoring inputs the monitored data of the tensioning machine video monitoring 22 and the pulley camera 23 into the industrial AP17 through the pan-tilt camera 10, inputs the data of the pulley hanging point tension point 25, the pulley attitude monitoring data and the traction plate monitoring 24 into the micro gateway 19, inputs the data of the tensioning machine control 27 into the bridge 12, and finally exchanges the data in the 8-port exchanger 20 to complete the management and the control of the received data.

As shown in fig. 2, specifically, an integrated power supply unit is further disposed on the box body 4, and the integrated power supply unit is configured to supply power to the data monitoring component inside the built-in integrated box 1.

The integrated power supply unit includes: the solar energy power generation system comprises a power supply module 15, a solar panel 6, a miniature wind driven generator 2 and a power supply management module 16;

the power supply module 15, the solar panel 6 and the micro wind driven generator 2 are respectively connected to the power supply management module 16;

the power management module 16 and the power module 15 are arranged in the built-in integrated box 1;

the solar panel 6 and the miniature wind driven generator 2 are arranged on the outer surface of the box body 4.

Through power module 15, miniature aerogenerator 2 and solar panel 6 are equipped with external power source transmission of electricity, wind power generation and photovoltaic power generation in integration high altitude monitoring platform, realize multiple power type electricity generation, can use under various different conditions and the weather to remain integration high altitude monitoring platform all has the power supply, the diversification of power and the continuation of supplying power have been realized, the maintenance required because of the mains operated has been reduced, the life of platform has been prolonged, the power is various, reach the stable purpose of supplying power.

As shown in fig. 2, specifically, directional bridge fixing frames 14 are further welded on the back of the box 4 near the bottom end, and two sets of directional bridge fixing frames 14 are arranged at intervals.

The directional bridge fixing frame 14 is used for fixing the bridge 12 arranged at the bottom end of the box body 4, and therefore the phenomenon that the tripod head camera 10 cannot monitor the power transmission line traction data of the stretching machine and the pulley due to the fact that the bridge 12 falls off from the bottom of the box body 4 is avoided.

As shown in fig. 1, specifically, two groups of solar panels 6 are provided, and the two groups of solar panels 6 are respectively disposed on two sides of the box body 4;

the solar panel 6 is divided into two parts, wherein one part is arranged on the solar tray 7, and the other part is fixed on the side wall of the box body 4;

the solar tray 7 is located at a position, close to the bottom end, of the side face of the box body 4 and connected with the box body 4 through a hinge, an inclined support 8 is hinged to the bottom of the solar tray 7, and a vertical support 9 is hinged to the other end of the inclined support 8.

In the work that solar panel 6 supplied power, open solar tray 7 and with the bottom of tray with the braced frame 8 is articulated, supports the tray through braced frame 8 and perpendicular support 9, makes solar panel 6 can receive the direct solar radiation and carry out photovoltaic and charge for the platform uses photovoltaic electricity, energy saving under sufficient circumstances.

As shown in fig. 4, specifically, four sets of the vertical supports 9 are provided, and the four sets of the vertical supports 9 are respectively disposed at four corners of the lower bottom surface of the box 4.

The vertical supports 9 at the four corners of the box body 4 are used for supporting the solar tray 7 and protecting the pan-tilt camera 10, the network bridge 12 and the network bridge pan-tilt 11 at the bottom of the box body 4.

Specifically, a pan-tilt camera 10 and a bridge pan-tilt 11 are further arranged on the lower bottom surface of the box body 4, the pan-tilt camera 10 and the bridge pan-tilt 11 are respectively arranged on two sides of the lower bottom surface of the box body 4 and are spaced from the vertical support 9, and a bridge 12 is fixed on the lower surface of the bridge pan-tilt 11 through bolts;

the network bridge 12 is connected between the 8-port switch 20 and the centralized control center 21, and is used for relaying the instructions sent and received by the 8-port switch 20 and transmitting the data of the stretcher control 27 to the centralized control center 21.

The monitoring system centralizes data of the traction machine, the tension machine, the monitoring pulley, the traction plate and the centralized control center 21 in a unified background for unified management, functions are centralized, the difficulty of supervision is reduced, the complexity and times of high-altitude operation are reduced through integrated integration, and safety risks are effectively reduced.

It should be noted that the above-mentioned embodiments are only used for illustrating the technical solutions of the present invention and not for limiting the protection scope, and although the present invention has been described in detail with reference to the above-mentioned embodiments, it should be understood by those skilled in the art that various changes, modifications or equivalents can be made to the specific embodiments of the application after reading the present invention, but these changes, modifications or equivalents are all within the protection scope of the claims of the pending application.

Claims (10)

1. Overhead transmission line integration high altitude monitoring platform which characterized in that includes: a box body (4) and a built-in integrated box (1);

the box body (4) is fastened on the cross arm of the angle steel tower of the power transmission line;

the built-in integrated box (1) is arranged inside the box body (4); the built-in integrated box (1) is used for integrated installation of all data monitoring components to realize integration;

it includes to establish data monitoring part in built-in integrated integrative case (1): the system comprises an industrial AP (17), an 8-port switch (20), an equipment management module (18), a micro gateway (19) and a centralized control center (21);

the industrial AP (17) is used for receiving the video monitoring (22) of the stretching machine and the pulley camera (23) and forwarding the videos to the 8-port exchanger (20) through a network cable;

the 8-port switch (20) is used for sending and receiving instructions;

the micro gateway (19) is used for receiving data of a traction plate monitoring (24), a pulley hanging point tension (25) and a pulley attitude monitoring (26), transmitting the data to the 8-port exchanger (20) through a network cable, and controlling the pan-tilt camera (10) through micro-power communication;

the micro gateway (19) is also connected with an equipment management module (18), and the equipment management module (18) is used for managing the pan-tilt camera (10);

the centralized control center (21) communicates through a built-in micropower communication module to obtain a power-on and power-off instruction of the pan-tilt camera (10).

2. The integrated overhead monitoring platform for the overhead transmission line according to claim 1, wherein an integrated power supply unit is further arranged on the box body (4), and the integrated power supply unit is used for supplying power to the data monitoring component in the built-in integrated box (1).

3. The integrated overhead monitoring platform of claim 2, wherein the integrated power supply unit comprises: the solar energy power generation system comprises a power supply module (15), a solar panel (6), a micro wind driven generator (2) and a power supply management module (16);

the power supply module (15), the solar panel (6) and the miniature wind driven generator (2) are respectively connected to the power supply management module (16);

the power management module (16) and the power module (15) are arranged in the built-in integrated box;

the solar panel (6) and the miniature wind driven generator (2) are arranged on the outer surface of the box body (4).

4. The integrated overhead monitoring platform of claim 3, characterized in that the box (4) comprises: the front surface, the back surface and the side surface of the box body;

an access door (13) is arranged on the front surface of the box body (4), and a fixed connecting frame (3) is arranged at the upper end of the back surface of the box body (4);

the upper top surface of the box body (4) is provided with a hoisting frame (5) and a miniature wind driven generator (2), and the lower bottom surface of the box body (4) is provided with a vertical support (9).

5. The integrated overhead monitoring platform for the overhead transmission line according to claim 4, wherein the fixed connecting frames (3) are two groups arranged at intervals.

6. The integrated overhead monitoring platform for the overhead transmission line according to claim 4, wherein the hoisting frames (5) are symmetrically arranged in two groups, the two groups of hoisting frames (5) are respectively arranged on two sides of the upper top surface of the box body (4), and the micro wind driven generator (2) is arranged on one side of the upper top surface of the box body (4) and is spaced from the hoisting frames (5).

7. The integrated overhead monitoring platform for the overhead transmission lines according to claim 4, wherein two groups of directional bridge fixing frames (14) are welded on the back surface of the box body (4) close to the bottom end, and the two groups of directional bridge fixing frames (14) are arranged at intervals.

8. The integrated overhead monitoring platform for the overhead transmission line according to claim 3, wherein two groups of the solar panels (6) are arranged, and the two groups of the solar panels (6) are respectively arranged at two sides of the box body (4);

the solar panel (6) is divided into two parts, wherein one part is arranged on the solar tray (7), and the other part is fixed on the side wall of the box body (4);

the solar tray (7) is located at a position, close to the bottom end, of the side face of the box body (4) and connected with the box body (4) through a hinge, an inclined support (8) is hinged to the bottom of the solar tray (7), and a vertical support (9) is hinged to the other end of the inclined support (8).

9. The integrated overhead monitoring platform of claim 8,

the four groups of vertical supports (9) are arranged, and the four groups of vertical supports (9) are respectively arranged at four corners of the lower bottom surface of the box body (4).

10. The integrated overhead monitoring platform for the overhead transmission lines according to claim 4, wherein a pan-tilt camera (10) and a bridge pan-tilt (11) are further arranged on the lower bottom surface of the box body (4), the pan-tilt camera (10) and the bridge pan-tilt (11) are respectively arranged on two sides of the lower bottom surface of the box body (4) and are arranged at intervals with the vertical support (9), and a bridge (12) is fixed on the lower surface of the bridge pan-tilt (11) through bolts;

the network bridge (12) is connected between the 8-port switch (20) and the centralized control center (21), and is used for transferring the instructions sent and received by the 8-port switch (20) and transmitting the data of the tension controller (27) to the centralized control center (21).

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