KR20160116370A - PV system control and monitoring integrated system - Google Patents

Abstract

The present invention relates to an integrated system for controlling and monitoring a photovoltaic device. More specifically, the present invention relates to an integrated system for controlling and monitoring a photovoltaic device, wherein a photovoltaic tracking unit is configured to be remotely controlled and monitored, a manager can remotely manage a position adjustment state of an array of a solar cell without directly needing to visit an installation site, power is supplied to a power supply unit by using a constant power source stored in advance when it is difficult to secure a predetermined incident angle due to sunset or weather deterioration, it is not necessary to dispose a separate power line in the photovoltaic tracking unit, wiring is connected to the inside of the device to minimize external wiring, and the temperature and humidity of usage environment in the device are controlled to improve the usage environment, thereby extending the lifespan of the system.

Description

Photovoltaic Device Control and Monitoring Integrated System {omitted}

The present invention relates to a photovoltaic device control and monitoring integrated system. More specifically, the solar tracking unit can be remotely controlled and monitored, thereby allowing the manager to remotely manage the position adjustment state of the solar cell array without having to visit the installation site directly, If it is difficult to obtain a certain amount of incident angle, it is not necessary to dispose a separate power line in the solar tracking unit by supplying power using the regular power source previously stored in the power supply unit, and the wiring is connected to the inside of the apparatus to minimize external wiring And an integrated system for monitoring and controlling a photovoltaic power generation apparatus that can extend the service life of the system by controlling the temperature and humidity of the environment in which the apparatus is used.

In general, photovoltaic devices are devices that integrate sunlight irradiated from the sun into one place and convert it into electrical energy. Adjust the angle of the photovoltaic power generation device so that the incidence efficiency can be optimized according to the change of the altitude of the sun, so that the power generation efficiency can be maximized.

In recent years, research and development related to photovoltaic devices have been actively under way. As a prior art document related thereto, Korean Patent Registration No. 1264846 (Registered on May 31, 2013), a solar optical tracker and a solar power generation device are disclosed.

1. A solar tracker capable of moving a solar panel according to the position of the sun, the solar tracker comprising: a lower post portion mounted on the ground; a post composed of an upper post portion detachably connected to the lower post portion and having an inner space; A plurality of rollers spaced apart from each other by a predetermined distance on the support plate, a support plate disposed on the upper portion of the support plate, a rotation plate arranged to face the support plate and hinged to the solar power generation panel, An azimuth angle adjusting module connected to the rotating plate so as to be accommodated in the upper post portion and configured to rotate the rotating plate to adjust the azimuth angle of the solar power generation panel, an elevation support unit connected to the azimuth angle adjusting module, Adjust the altitude of the PV panel by shortening or extending the length Is achieved by the composition-part height adjustment includes a respective control module.

However, since such a photovoltaic power generation device is required to secure a certain incident light by being directly exposed to sunlight due to the characteristics of the device, it is installed in a place where it is installed outdoors or in a place where it is easy to secure incident light, It is not easy.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide an apparatus and a method for remotely controlling a solar tracking unit and monitoring a position adjustment state of a solar cell array, And to provide efficiency.

In order to achieve the above object, an integrated PV system control and monitoring system according to the present invention, which is devised to achieve the above object, supplies power through a bidirectional DC-DC converter with its own power generated in a solar cell array and adjusts a tilt angle and an azimuth angle, At least one solar tracking unit for moving the array; A weather observation sensor unit for measuring at least one of at least one of solar radiation amount, temperature, humidity, wind direction and wind speed, converting the atmospheric data into a specific value, and moving the converted value to the integrated control unit; An integrated controller for controlling the solar tracking unit to move to a position capable of ensuring a maximum incident amount according to a real time incident amount of the solar cell array in conjunction with the solar tracking unit, the weather observation sensor unit, and the monitoring unit; And a voltage value input to and output from the integrated control unit in real time, receives power generation data generated by the solar tracking unit and weather data generated by the weather observation sensor unit in real time, stores the data in a database, And transmitting the statistical information to the administrator terminal.

The integrated control unit receives the weather data measured by the weather observation sensor unit, and when the incident efficiency of the solar cell array falls below a pre-stored threshold value due to sunset or weather deterioration, The monitoring unit transmits the generated power generation data transmitted from the solar tracking unit and the weather data transmitted from the weather observation sensor unit to the database and stores the generated data for a predetermined period of time. If an error occurs in the component, the cause of the failure can be diagnosed by calling the database and extracting the difference from the standard value in order to identify the cause of the failure.

According to the present invention, the inclination angle and the azimuth angle of the solar cell array are controlled by remotely controlling the solar tracking unit, and the position adjustment state of the solar cell array is monitored, thereby providing the convenience and efficiency of management so that the manager does not have to visit the installation site directly It is effective in doing.

According to the present invention, the monitoring unit receives the meteorological data generated by the meteorological observation sensor unit and the generated power generation data generated by the solar cell array, compares the meteorological data with the reference data previously stored in the database, and monitors whether the power generation efficiency of a proper value is calculated It has the effect to make.

According to the present invention, the power used in the solar tracking unit is supplied as self-generated power generated by the solar cell array. However, when it is difficult to secure a certain amount of incident angle of the solar cell array due to sunset or weather deterioration, So that it is not necessary to construct a separate power line necessary for the solar tracking unit.

In addition, according to the present invention, it is possible to manufacture an integrated control device which is individually installed and exposed to an outdoor environment and inconvenient for maintenance and maintenance, so that the control devices can be collectively managed, The external wiring is minimized and the temperature and humidity of the use environment inside the apparatus are controlled to improve the use environment to extend the service life of the system.

1 is a conceptual diagram of an integrated photovoltaic apparatus control and monitoring system according to a preferred embodiment of the present invention,
2 is a configuration diagram of a solar tracking unit of a solar power system control and monitoring integrated system according to a preferred embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to designate the same or similar components throughout the drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. In addition, the preferred embodiments of the present invention will be described below, but it is needless to say that the technical idea of the present invention is not limited thereto and can be variously modified by those skilled in the art.

FIG. 1 is a conceptual diagram of an integrated photovoltaic apparatus control and monitoring system according to a preferred embodiment of the present invention. FIG. 2 is a block diagram of a solar photovoltaic apparatus according to a preferred embodiment of the present invention. .

1 and 2, an integrated photovoltaic device control and monitoring system according to a preferred embodiment of the present invention includes a solar light tracking unit 100, an integrated control unit 200, a monitoring unit 300, Unit 400, a solar cell array 500, and a wireless communication unit 600.

The solar tracking unit 100 is installed in a place suitable for securing the outdoor or incidence amount and receives the power required for driving from the power supply unit 10 to move the solar cell array 500 to a position where the incidence angle of the solar cell array 500 is optimized . One solar tracking unit 100 may be provided for each solar cell array 500.

A part of the power secured in the solar cell array 500 is supplied to the power supply unit 10 as power required for driving the solar tracking unit 100.

More specifically, the power generated from the solar cell array 500 is tracked by the maximum power tracking (MPPT) and supplied at a rated voltage, and the power supplied from the bidirectional DC-DC converter is supplied through the solar inverter And supplies the generated power to the generated voltage.

The power supply unit 10 supplies the pre-stored DC power through the bidirectional DC-DC converter when the solar tracking unit 100 is difficult to receive the self-power of the solar cell array due to sunset or weather deterioration. This method has the effect of not requiring a separate power line in the solar tracking unit.

The solar tracking unit 100 includes an inclination angle sensor unit 20 for adjusting the inclination angle of the solar cell array 500 to increase the efficiency of the solar cell array, an azimuth angle sensor unit 30 for adjusting the azimuth angle of the solar cell, .

The weather observation sensor unit 400 measures at least one of the solar radiation amount, the temperature, the humidity, the wind direction, and the wind speed, converts the measured temperature data into a specific value, and transmits the specific value to the integrated control unit 200.

The integrated control unit 200 is connected to the solar tracking unit 100, the monitoring unit 300, and the weather observation sensor unit 400 in a wireless communication manner, so that an angle at which the maximum incident amount can be secured at the current position of the solar cell array And direction and transmits it to the solar tracking unit 100.

More specifically, it is possible to diagnose a change to a position at which a maximum incident amount can be secured by analyzing an incident amount that can be maximally reached based on a current time and a current position value of the solar cell array 500.

The integrated controller 200 changes the direction of the power supply unit 10 to be supplied to the solar tracking unit 100 and changes the direction of the power supply unit 10 to be supplied to the DC-DC converter 200 when the incident amount of the stored reference value falls below a threshold value due to sunset or weather deterioration. (40).

The monitoring unit 300 detects voltage and current values input and output to and from the integrated control unit 200, monitors and analyzes whether proper values are being transmitted and received, and transmits the analyzed values to the administrator terminal.

The monitoring unit 300 may perform a numbering operation for each of the solar tracking units 100 so that the azimuth angle and the tilt angle of the solar cell array 500 disposed at specific locations of the plurality of solar tracking units 100 can be individually adjusted. ) Are stored and managed by the administrator.

For example, if a solar cell array # 1, a solar cell array # 2, a solar cell array # 3, and an nth solar cell array are arranged, a solar cell tracking device And the operation of each sensor unit is checked to see if the operation is smooth for a predetermined time.

The monitoring unit 300 monitors the input and output values transmitted and received by the solar tracking unit 100 in real time so that the manager can continuously check whether there is any abnormality. More specifically, the monitoring unit 300 transmits and receives data to and from the solar inverter 50 and the weather observation sensor unit 400 via wireless communication, and receives the electricity generation amount data transmitted from the solar tracking unit 100 and the weather observation sensor unit 400 to the database and stores the stored weather data for a predetermined period of time. When an error occurs in a specific component of the solar tracking unit 100 based on the accumulated database, And extracts the parts that differ from the standard values to diagnose the cause of the failure.

Also, the monitoring unit 300 can output the power generation amount generated in the solar cell array 500 in real time, and calculate the average power generation amount over a year based on the monthly power generation amount.

The integrated control unit 200 and the monitoring unit 300 are provided separately from the existing control devices or are exposed to the outdoor environment so that there are many wiring and piping and inconvenience of maintenance, And the internal environment of the integrated control device 200 is set to an appropriate temperature and humidity so that the service life can be extended by improving the use environment.

The wireless communication unit 600 transmits and receives data generated between the solar tracking unit 100, the integrated control unit 200, and the monitoring unit 300 by wireless communication.

It will be apparent to those skilled in the art that various modifications, substitutions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims. will be. Therefore, the embodiments disclosed in the present invention and the accompanying drawings are intended to illustrate and not to limit the technical spirit of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments and the accompanying drawings . The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

10 - power supply unit 20 - inclination angle sensor unit
30 - azimuth sensor part 100 - solar tracking part
200 - Integrated control unit 300 - Monitoring unit
400-meteorological sensor part 500 - solar cell array
600 -

Claims (2)

At least one solar ray tracing unit for receiving power from a bi-directional DC-DC converter with its own power generated from the solar array and moving the solar array by adjusting the tilt angle and the azimuth angle;
A weather observation sensor unit for measuring at least one of at least one of solar radiation, temperature, humidity, wind direction and wind speed, converting the atmospheric data into a specific value, and moving the converted value to the integrated control unit;
An integrated controller for controlling the solar tracking unit to move to a position capable of ensuring a maximum incident amount according to a real time incident amount of the solar cell array in conjunction with the solar tracking unit, the weather observation sensor unit, and the monitoring unit; And
The power generation data generated by the solar tracking unit and the weather data generated by the weather observation sensor unit are received in real time and stored in a database, And transmits the statistical information to the administrator terminal
Wherein the photovoltaic device control and monitoring integrated system comprises a photovoltaic device. The method according to claim 1,
The integrated control unit
When the incident efficiency of the solar cell array drops below a pre-stored threshold value due to sunset or weather deterioration by receiving the meteorological data measured by the weather observation sensor unit, commands the power supply unit to temporarily supply power to the solar tracking unit through the constant power source ,
The monitoring department
When generation of an error occurs in a specific component of the solar ray tracking unit based on the accumulated data, the generation amount data transmitted from the solar ray tracking unit and the weather data transmitted from the weather observation sensor unit to the database, An integrated system for controlling and monitoring the photovoltaic power generation system that diagnoses the cause of failure by extracting the difference from the standard value by calling the database to identify the cause of the failure.

Images