KR20160106395A - Self-diagnosising monitoring system for solar module - Google Patents

Abstract

The present invention relates to a self-diagnosis monitoring system for a solar module. The system comprises: a plurality of solar modules for producing power from sunlight; an environment information measurement unit configured to measure environment sensing information; a self-diagnosis control unit configured to analyze power generation efficiency and a performance state of each solar module; and a remote management unit connected to the self-diagnosis control unit. Therefore, the system can monitor a current state of each solar module in real time.

Description

[0001] SELF-DIAGNOSISING MONITORING SYSTEM FOR SOLAR MODULE [0002]

The present invention relates to a solar-module self-diagnosis monitoring system, and more particularly, to a solar-module self-diagnosis monitoring system that analyzes a performance state of a plurality of solar modules installed for power generation in a solar- By recording and storing data on power generation efficiency information and performance status information, it is possible to allow a user or an administrator to monitor the current performance status and an abnormal status of each solar module in real time through a smart device equipped with a dedicated application It is also possible to monitor the current status of each solar module at a remote location by calculating and displaying statistical data using integrated data stored separately in the database, or to perform a solar module self-diagnosis On monitoring systems The.

Generally, photovoltaic power generation is a power generation system that converts sunlight directly into electric energy using solar cell. Such solar power generation is attracting attention as a new energy source due to the depletion of fossil fuels and pollutants generated when fossil fuels are burned.

2. Description of the Related Art A power generation apparatus for generating photovoltaic power comprises a plurality of solar cells and a converter in which a plurality of battery cells are connected in series or in parallel. Such a photovoltaic power generation apparatus is usually installed on the roof of a building or on an idle land where people do not travel well and is operated as an unmanned person.

However, since the photovoltaic power generation system operates unattended on the roof of a building, it is difficult to know when an unexpected abnormal operation occurs in a solar cell panel. For example, it is difficult to detect an abnormal operation due to sunlight deficiency due to contamination of the solar cell panel or an open or short circuit of a plurality of unit cells, which is difficult to detect, And the like.

For example, in a conventional technology, Korean Patent Registration No. 10-1059355 entitled " Apparatus and Method for Monitoring Output Quality of a Solar Power Inverter ", voltage and current waveforms of a photovoltaic power generation system, , An output quality monitoring apparatus and method of a solar power inverter having a function of detecting and displaying a voltage drop and a momentary power failure and having an alarm function, And monitoring the voltage drop and the instantaneous power failure, thereby preventing deterioration and obstacle of the performance of the solar power generation system, and a method of monitoring the output quality of the solar power inverter.

As described above, the output quality monitoring apparatus of the solar power inverter described above can confirm whether or not the solar inverter is faulty if the user or the manager visits the place where the solar inverter is installed, There was no problem.

In addition, when the failure of the photovoltaic module to generate the power of the photovoltaic power generation system, it is not easy to find the photovoltaic module in which the abnormality occurs due to the output quality of the inverter due to the current and voltage.

SUMMARY OF THE INVENTION The present invention has been conceived to solve the problems as described above, and it is an object of the present invention to provide a self-diagnosis control unit capable of analyzing performance state information and abnormal state information for a plurality of solar modules according to various environmental changes, Diagnosis performance information and performance status information including environmental sensing information for each solar module can be monitored in real time by allowing the smart device capable of connecting to the self-diagnosis control unit through wireless communication, By using the integrated data stored in the database to generate statistical data that can be easily managed, it is possible to monitor the current state of each photovoltaic module from a remote place in real time, or to perform a self-diagnosis of the photovoltaic module to conveniently manage various integrated data and statistical data Monitoring system.

According to an aspect of the present invention, there is provided a solar-module self-diagnosis monitoring system including: a plurality of solar modules for generating electric power from solar light; An environmental information measuring unit for measuring environmental sensing information of at least one of current, voltage, temperature, humidity, illumination, and radiation dose from each of the plurality of solar modules; A self-diagnosis controller for receiving the environmental sensing information measured by the environmental information measuring unit from a data logger and converting the received environmental sensing information into a digital signal and analyzing the power generation efficiency and the performance state of each of the plurality of solar modules using the digital signal; A remote control unit connected to the self-diagnosis control unit, monitoring the environmental sensing information in association with the data logger, and monitoring power generation efficiency information and performance status information analyzed through the self-diagnosis control unit; .

Also, the solar module self-diagnosis monitoring system according to the present invention may include: a DB management server for receiving and storing integrated data including the environmental sensing information, the power generation efficiency information, and the performance status information from the self-diagnosis controller; Wherein the remote control unit is connected to the DB management server to monitor the integrated data in real time.

Further, in the solar module self-diagnosis monitoring system according to the present invention, the remote control unit calculates and displays statistical data for a predetermined period through the integrated data accumulated in connection with the DB management server, displays the statistics data, Management is possible.

Further, in the solar module self-diagnosis monitoring system according to the present invention, the environment information measuring unit may include a module connector for connecting the solar module and the self-diagnosis controller to measure the voltage and current, And a sensor device installed in the periphery of the sensor for measuring the environmental sensing information.

Further, in the solar module self-diagnosis monitoring system according to the present invention, the remote control unit drives a dedicated application connected to the self-diagnosis control unit through a wireless communication network including Wi-Fi and zigbee, If the at least one of the environmental sensing information, the power generation efficiency information, and the performance state information falls outside the set value, the dedicated application determines the abnormal state as the abnormal state, and if the information indicates the current state information of the corresponding solar module Is displayed.

According to the above-described configuration, the solar module self-diagnosis monitoring system according to the present invention can be applied to a system for diagnosing the abnormality such as power factor degradation, aged deterioration, harmonics, The user can easily grasp the information such as the power generation efficiency and the performance state of the photovoltaic module by monitoring the user in real time through the smart phone installed with the application.

In addition, the solar module self-diagnosis monitoring system according to the present invention generates statistical data that can be easily managed using integrated data stored in a separate database, thereby monitoring the current state of each solar module in a remote place, And statistical data can be conveniently managed.

1 is a schematic diagram of a solar module self-diagnosis monitoring system according to an embodiment of the present invention;
2 is a configuration diagram of a solar module self-diagnosis monitoring system according to an embodiment of the present invention;
3 is a block diagram illustrating a solar module self-diagnostic monitoring system in accordance with an embodiment of the present invention.
4 is a photographic copy of a control module implementation of a self-diagnosis control module of a solar module self-diagnosis monitoring system according to an embodiment of the present invention.
5 is a photographic copy showing a display state of a remote controller of a solar module self-diagnosis monitoring system according to an embodiment of the present invention.

Throughout the specification, when an element is referred to as "comprising ", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise. Also, the terms " part, "" module," and " module ", etc. in the specification mean a unit for processing at least one function or operation and may be implemented by hardware or software or a combination of hardware and software have.

Hereinafter, the solar module self-diagnosis monitoring system according to the present invention will be described in detail with reference to the embodiments shown in the drawings.

FIG. 1 is a schematic diagram of a solar module self-diagnosis monitoring system according to an embodiment of the present invention, FIG. 2 is a configuration diagram of a solar module self-diagnosis monitoring system according to an embodiment of the present invention, FIG. 4 is a block diagram illustrating a photovoltaic module self-diagnosis monitoring system according to an exemplary embodiment of the present invention. FIG. FIG. 5 is a photographic copy showing a display state of the remote controller of the solar module self-diagnosis monitoring system according to an embodiment of the present invention.

The solar module self-diagnosis monitoring system according to an embodiment of the present invention includes a plurality of solar modules 10, an environment information measurement unit 20, a self-diagnosis control unit 30, a DB A management server 40, and a remote control unit 50. [

The plurality of solar modules 10 are installed to convert solar energy into electric energy and provide it to an electric power supply device such as an inverter. The plurality of solar modules 10 may be configured to be adjustable in angle through a separate mechanism so as to increase the light-condensing efficiency.

The environment information measuring unit 20 may be networked with the solar module 10 to receive environmental information of at least one of current, voltage, temperature, humidity, illumination, or solar radiation from the solar module 10, The power generation efficiency and the performance state of the module 10 are analyzed.

The self-diagnosis and control unit 30 receives the environmental sensing information 210 measured by the environmental information measuring unit 20 from a data logger, converts the environmental sensing information 210 into a digital signal and records the converted digital signal, The power generation efficiency and performance state of each optical module 10 are analyzed.

The environment information measuring unit 20 may include a module connection connector 21 and a sensor device 22. [

The module connection connector 21 connects the plurality of solar modules 10 to the self-diagnosis controller 30 to measure the voltage and current of the environmental sensing information 210, and the sensor device 22 Humidity, illuminance, or solar radiation amount of the environmental sensing information 210 installed in the periphery of each of the solar modules 10.

The sensor unit 22 may be a temperature sensor, a humidity sensor, an illuminance sensor, or a solar radiation sensor. The sensor unit 22 may be connected to the module connector 21, It is possible to provide environmental information such as current, voltage, temperature, humidity, illuminance or time measured from each module 10 to the self-diagnosis and control unit 30, such as solar radiation according to altitude.

Therefore, the self-diagnosis and control unit 30 converts the analog data, which is generated by sensing the environment sensing information 210 in the data logger, into digital data and analyzes the digital data, thereby changing the environment of each of the plurality of solar modules 10 The average power according to the current, the voltage, the temperature, the humidity, the illuminance, or the solar radiation. The power generation efficiency information 310 of each of the plurality of solar modules 10, So that the performance status information 320 can be recorded.

4, the self-diagnosis and control unit 30 receives the power generation efficiency information 310 and performance status information 310 through a wired / wireless communication network including a USB RS232 module, a WiFi Ethernet, and a Zigbee module 320). ≪ / RTI >

That is, the self-diagnosis and control unit 30 measures the efficiency of the solar module 10, analyzes the performance of the solar module 10 according to the environmental sensing information 210, Accordingly, the remote control unit 50, which will be described later, allows the user and the manager to monitor the power generation efficiency information 310 and the performance status information 320 via the wired / wireless connection with the self-diagnosis and control unit 30 .

The DB management server 40 receives the integrated data 410 including the environmental sensing information 210, the power generation efficiency information 310 and the performance status information 320 from the self-diagnosis and control section 30 .

The DB management server 40 receives environment sensing information 210 such as current, voltage, temperature, humidity, illuminance, or radiation dose measured by the environment information measuring unit 20, Data on the power generation efficiency information 310 and the performance status information 320 can always be stored.

The remote control unit 50 can be connected to the self-diagnosis and control unit 30 through wired / wireless communication as described above. The remote control unit 50 can access the power generation efficiency information 310 and the performance status information (320) in real time.

The remote control unit 50 displays the environment sensing information 210 in conjunction with a data logger provided in the self-diagnosis control unit.

At this time, the remote control unit 50 connects to the DB management server 40 and calculates and displays statistical data 420 for a predetermined period of time using various data information accumulated in the integrated data 410.

The remote control unit 50 may be a smart device such as a smart phone capable of wireless communication through a wifi ethernet or zigbee module of the self-diagnosis and control unit 30. It is preferable that the smart device is a mobile communication terminal in which a dedicated application can be installed. Using the mobile communication terminal, the remote control unit 50 transmits the integrated data 410 for a predetermined period So that the user or the manager can manage the statistical data 420 to check the solar power generation efficiency and the performance state according to the above-described aspect and the long-term use of the module 10 .

In addition, the remote controller 50 can drive a dedicated application connected to the self-diagnosis controller 30 through a wireless communication network including a Wi-Fi (Wi-Fi) and a zigbee.

If the at least one of the environmental sensing information 210, the power generation efficiency information 310, and the performance status information 320 is other than the set value, And displays the current state information of the corresponding solar module 10 determined as an abnormal state.

5, a user or an administrator selects a corresponding photovoltaic module that needs to be managed among the plurality of photovoltaic modules 10 through a channel selection, and determines the current, voltage, temperature, The power generation efficiency information 310 and the performance state information 320 analyzed using the environmental sensing information 210 and the environmental sensing information 210 in real time.

At this time, the self-diagnosis control unit 30 transmits the environmental sensing information 210 provided from the environment information measurement unit 20, the power generation efficiency information 310 and the performance status information 320 to the USB RS232 It is possible to process data in a form suitable for a module, a wifi ethernet, and a zigbee module, and transmit the processed data information to the DB management server 40 or the remote control unit 50 .

With the above-described configuration, the solar module self-diagnosis monitoring system of the present invention can monitor the abnormal state of each of the plurality of solar modules 10 according to various environmental changes in real time, It is possible to check and manage the power generation efficiency and the performance state of each of the solar modules 10 over a certain period of time by using the statistical data separately stored in the solar module 10, Operation and management can be easily performed.

The photovoltaic module self-diagnostic monitoring system described above and shown in the drawings is only one embodiment for carrying out the present invention and should not be construed as limiting the technical idea of the present invention. The scope of protection of the present invention is defined only by the matters set forth in the following claims, and the embodiments improved and changed without departing from the gist of the present invention are obvious to those having ordinary skill in the art to which the present invention belongs It will be understood that the invention is not limited thereto.

10 Photovoltaic module 20 Environmental information measuring section
21 Module connection connector 22 Sensor unit
30 self-diagnosis control unit 40 DB management server
50 remote control unit
210 Environmental sensing information 310 Power generation efficiency information
320 Performance status information 410 Integrated data
420 statistical data

Claims (5)

A plurality of solar modules for generating electric power from solar light;
An environmental information measuring unit for measuring environmental sensing information of at least one of current, voltage, temperature, humidity, illumination, and radiation dose from each of the plurality of solar modules;
A self-diagnosis controller for receiving the environmental sensing information measured by the environmental information measuring unit from a data logger and converting the received environmental sensing information into a digital signal and analyzing power generation efficiency and performance state of each of the plurality of solar modules using the digital signal;
A remote control unit connected to the self-diagnosis control unit, monitoring the environmental sensing information in conjunction with the data logger, and monitoring power generation efficiency information and performance status information analyzed through the self-diagnosis control unit; Wherein the solar module is a self-diagnostic monitoring system. The method according to claim 1,
A DB management server for receiving and storing the integrated data including the environmental sensing information, the power generation efficiency information, and the performance status information from the self-diagnosis controller; Further included,
Wherein the remote control unit is connected to the DB management server and is capable of monitoring the integrated data in real time. 3. The method of claim 2,
Wherein the remote control unit is capable of calculating and displaying statistical data for a predetermined period of time through the integrated data accumulated in connection with the DB management server and managing the statistical data. 4. The method according to any one of claims 1 to 3,
The environmental information measuring unit may include a module connector for connecting the solar module and the self-diagnosis controller to measure the voltage and current, and a sensor device installed around each of the solar modules to measure the environmental sensing information And a monitoring module for monitoring the solar module. 4. The method according to any one of claims 1 to 3,
The remote control unit may drive a dedicated application connected to the self-diagnosis control unit through a wireless communication network including Wi-Fi and zigbee,
If the at least one of the environmental sensing information, the power generation efficiency information, and the performance state information falls outside a set value, the dedicated application determines the abnormal state as an abnormal state, And the information is displayed on the display unit.

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