CN210327146U - Wind-solar hybrid power grid monitoring system - Google Patents

Abstract

The utility model relates to the field of wind power generation, and discloses a wind-solar hybrid power grid monitoring system, which comprises a power generation unit and a camera for detecting a power grid line; the system also comprises a control unit, a weather detection module and an unmanned aerial vehicle charging platform; the control unit comprises a controller and a communication module. The monitoring system can collect weather information and accordingly determine whether the unmanned aerial vehicle can cruise or cruise frequency, continuous monitoring of the power line in the limited range is achieved through the camera, intermittent monitoring of the power line in the limited range is achieved through the unmanned aerial vehicle, monitoring of the power line in the monitoring range and the environment near the power line is achieved, monitoring can be conducted timely when ice disasters or mountain fires occur, feedback can be conducted timely, and operation safety and reliability of a power grid are improved.

Description

Wind-solar hybrid power grid monitoring system

Technical Field

The utility model relates to a wind power generation field, more specifically say, especially relate to a complementary electric wire netting monitored control system of scene.

Background

Carry out electric wire netting monitoring and periodic detection through unmanned aerial vehicle is a new born technique, and it can effectually reduce the artifical required cost of patrolling and examining.

The applicant national grid company applies an invention patent CN 201710817474.9 in 2017, and discloses an unmanned aerial vehicle inspection system, which comprises: a plurality of location transmitters, each of said location transmitters adapted to be mounted on a meter or an electrical device for transmitting a location signal and a device identification, one of said meter or electrical device corresponding to one of the device identifications; the unmanned aerial vehicle is used for receiving the position signal, flying to the meter or the electric power equipment corresponding to the equipment identifier according to the position signal, collecting a dial plate image of the meter, or detecting the temperature of the electric power equipment; the charging station is used for charging the unmanned aerial vehicle and comprises a charging platform for bearing the unmanned aerial vehicle, a charging sensor for detecting a landing signal of the unmanned aerial vehicle and a charging module for charging the unmanned aerial vehicle; the charging sensor sends to when detecting unmanned aerial vehicle's landing signal the module of charging, the module of charging is according to the landing signal is unmanned aerial vehicle output power.

The system creatively enables the unmanned aerial vehicle to realize self-cruising and self-charging without manual intervention, and can realize regular cruising.

However, most power grids in China need to cross mountains and mountains, and no commercial power is provided in most areas.

Therefore, based on the above technology, the technical problem to be solved by the present solution is: how to monitor the power grid can be monitored in 24h under the condition that no commercial power is supplied in the field.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a complementary electric wire netting monitored control system of scene, this monitored control system can gather weather information and with this decision unmanned aerial vehicle whether can cruise or the frequency of cruising, realize the continuous monitoring of the power line in the limited range through the camera, realize the power line intermittent type nature control in the limited range through unmanned aerial vehicle, realize the control of the power line in the monitoring range and the environment near power line, can in time monitor when taking place or mountain fire takes place to the ice disaster, in time feedback, the operation fail safe nature of improvement electric wire netting.

The technical scheme of the utility model as follows: a wind-solar hybrid power grid monitoring system comprises a power generation unit and a camera for detecting a power grid line; the system also comprises a control unit, a weather detection module and an unmanned aerial vehicle charging platform; the control unit comprises a controller and a communication module;

the power generation unit comprises a wind driven generator, a solar panel, a wind power complementary controller and a storage battery; the wind driven generator and the solar panel are connected to a fan access end and a photovoltaic access end of the wind power complementary controller; the storage battery is connected to a battery access end of the wind power complementary controller;

the storage battery supplies power to the communication module, the controller, the camera, the weather detection module and the unmanned aerial vehicle charging platform;

the weather detection module, the unmanned aerial vehicle charging platform and the camera are respectively and electrically connected to the controller; the controller is in communication connection with the outside through a communication module; the unmanned aerial vehicle carry on with communication module carry out communication connection's communication unit.

In the wind-solar hybrid power grid monitoring system, the weather detection module comprises a temperature sensor, a wind speed sensor and a humidity sensor; the temperature sensor, the wind speed sensor and the humidity sensor are electrically connected to the controller.

In foretell complementary electric wire netting monitored control system of scene, unmanned aerial vehicle charge platform including the buckler that can open and shut, set up the platform body in the buckler, set up the interface that charges in the platform body.

In the wind-solar hybrid power grid monitoring system, the power generation unit further comprises a stand column, the wind driven generator and the solar panel are arranged on the stand column, an electric cabinet is arranged on the stand column, the wind-solar hybrid controller, the storage battery and the control unit are arranged in the electric cabinet, and the unmanned aerial vehicle charging platform is arranged on a high platform beside the stand column.

Compared with the prior art, the utility model discloses the beneficial effect who has does:

the utility model discloses can gather weather information and with this decision unmanned aerial vehicle can cruise or cruise the frequency, realize the continuous monitoring of the power line in the limited scope through the camera, realize the power line intermittent type nature control in the limited scope through unmanned aerial vehicle, realize the control of the power line in the monitoring range and the environment near power line, can in time monitor when taking place or mountain fire takes place to the ice disaster, in time feedback improves the operation fail safe nature of electric wire netting.

Drawings

Fig. 1 is a block diagram showing the structure of embodiment 1 of the present invention;

fig. 2 is a schematic structural diagram of embodiment 1 of the present invention.

Detailed Description

The technical solution of the present invention will be further described in detail with reference to the following detailed description, but the present invention is not limited thereto.

Example 1

Referring to fig. 1-2, a wind-solar hybrid power grid monitoring system includes a power generation unit, a camera 1 for detecting a power grid line; the unmanned aerial vehicle charging system also comprises a control unit, a weather detection module and an unmanned aerial vehicle charging platform 3; the control unit comprises a controller 2 and a communication module 4;

the power generation unit comprises a wind driven generator 5, a solar panel 6, a wind power complementary controller 7 and a storage battery 8; the wind driven generator 5 and the solar panel 6 are connected to a fan access end and a photovoltaic access end of the wind power complementary controller 7; the storage battery 8 is connected to a battery access end of the wind power complementary controller 7;

the storage battery 8 supplies power to the communication module 4, the controller 2, the camera 1, the weather detection module and the unmanned aerial vehicle charging platform 3;

as another optional power supply mode, a power supply port is arranged on the wind power complementary controller 7, and the communication module 4, the controller 2, the camera 1, the weather detection module and the unmanned aerial vehicle charging platform 3 are all electrically connected to the power supply port; the wind driven generator 5 and the solar panel 6 generate electricity in the daytime and supply power to the electric equipment through the power supply port and charge the storage battery 8, and the wind driven generator 5 and the storage battery 8 supply power to the power supply equipment through the power supply interface at night.

Both of the above-described electrical connection modes are optional.

The weather detection module, the unmanned aerial vehicle charging platform 3 and the camera 1 are respectively and electrically connected to the controller 2; the controller 2 is in communication connection with the outside through a communication module; the unmanned aerial vehicle carry on with communication module carry out communication connection's communication unit.

In the operation process, the weather detection module provides guidance for whether the unmanned aerial vehicle is on duty or not and the duty frequency by detecting the weather conditions, and if the unmanned aerial vehicle is at low temperature and has high air humidity, the duty frequency of the unmanned aerial vehicle is higher so as to prevent the power grid from being frozen; under the conditions of dryness and high temperature, the attendance frequency of the unmanned aerial vehicle is higher, so that the mountain fire near the electric tower can be forecasted; under the condition such as raining, storm, unmanned aerial vehicle can not attendance.

The supplementary of patrolling and examining as unmanned aerial vehicle, continuously monitor power line and peripheral circumstances through camera 1, can monitor under the unable condition of attendance of unmanned aerial vehicle. Camera 1 can only detect the condition of less scope, and its work that can not replace unmanned aerial vehicle completely.

Unmanned aerial vehicle charging platform 3 can provide sufficient electric power support for unmanned aerial vehicle.

The drone communicates through a communication module 4 having a built-in communication unit and a control unit, and generally, it is preferable to perform automatic connection communication through bluetooth.

The power supply of the embodiment is generated by the wind power generator 5 and the solar panel 6, processed by the wind power complementary controller 7, and supplied to the storage battery 8, and is not affected by weather and daytime, and can continuously generate the power supply.

The communication unit of the embodiment is mainly communicated with the remote server so as to transmit the data generated every day to the remote server in real time for the monitoring personnel to use and analyze.

The wind-solar hybrid power grid monitoring system of the embodiment is provided with a plurality of wind-solar hybrid power grid monitoring systems on the whole power line, and the plurality of wind-solar hybrid power grid monitoring systems can realize continuous monitoring of the power line along the line.

In this embodiment, the weather detection module includes a temperature sensor 9, a wind speed sensor 10, and a humidity sensor 11; the temperature sensor 9, the wind speed sensor 10 and the humidity sensor 11 are electrically connected to the controller 2.

In this embodiment, unmanned aerial vehicle charging platform 3 including the buckler 31 that can open and shut, set up platform body 32 in buckler 31, set up the interface 33 that charges in platform body 32, should charge interface 33 and hold battery 8 and be connected. The charging interface 33 of the present embodiment can be automatically connected to the drone, and it can be specifically described with reference to paragraphs 66 to 67 of the specification of CN 201710817474.9.

In this embodiment, the electric power generation unit further includes a vertical column 12, the wind driven generator 5 and the solar cell panel 6 are arranged on the vertical column 12, the electric cabinet 13 is arranged on the vertical column 12, the wind power complementary controller 7, the storage battery 8 and the control unit are arranged in the electric cabinet 13, and the unmanned aerial vehicle charging platform 3 is arranged on a high platform 14 beside the vertical column 12.

The foregoing is only a preferred embodiment of the present invention, and all modifications, equivalents, and improvements made within the spirit and scope of the present invention are intended to be included within the scope of the present invention.

Claims (4)

1. A wind-solar hybrid power grid monitoring system comprises a power generation unit and a camera for detecting a power grid line; the intelligent control system is characterized by further comprising a control unit, a weather detection module and an unmanned aerial vehicle charging platform; the control unit comprises a controller and a communication module;

the power generation unit comprises a wind driven generator, a solar panel, a wind power complementary controller and a storage battery; the wind driven generator and the solar panel are connected to a fan access end and a photovoltaic access end of the wind power complementary controller; the storage battery is connected to a battery access end of the wind power complementary controller;

the storage battery supplies power to the communication module, the controller, the camera, the weather detection module and the unmanned aerial vehicle charging platform;

the weather detection module, the unmanned aerial vehicle charging platform and the camera are respectively and electrically connected to the controller; the controller is in communication connection with the outside through a communication module; the unmanned aerial vehicle carry on with communication module carry out communication connection's communication unit.

2. The wind-solar hybrid power grid monitoring system according to claim 1, wherein the weather detection module comprises a temperature sensor, a wind speed sensor and a humidity sensor; the temperature sensor, the wind speed sensor and the humidity sensor are electrically connected to the controller.

3. The wind-solar hybrid power grid monitoring system according to claim 1, wherein the unmanned aerial vehicle charging platform comprises a waterproof cover capable of being opened and closed, a platform body arranged in the waterproof cover, and a charging interface arranged in the platform body.

4. The wind-solar hybrid power grid monitoring system according to claim 1, wherein the power generation unit further comprises a stand column, the wind driven generator and the solar panel are arranged on the stand column, an electric cabinet is arranged on the stand column, the wind-solar hybrid controller, the storage battery and the control unit are arranged in the electric cabinet, and the unmanned aerial vehicle charging platform is arranged on a high platform beside the stand column.

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