KR101457643B1 - The system for diagnostic of photovoltaic generating facilities - Google Patents

Abstract

A diagnostic system for a photovoltaic power generation facility is disclosed in which a precise and reliable diagnosis is performed on a photovoltaic power generation facility.
The diagnostic system includes a diagnostic information acquisition unit for acquiring diagnostic information of a solar array installed on a site and outputting the diagnostic information based on a sensor network; A relay for collecting the diagnostic information acquired by the diagnostic information acquisition unit and relaying through the communication; And a diagnostic information analyzer for analyzing whether or not the solar array is abnormal based on the diagnosis information relayed through the repeater and whether or not the installation position is erroneous, so that it is possible to accurately determine whether the solar array is abnormal or an installation angle error And the manager can quickly know whether or not the solar array is abnormal.

Description

[0001] The present invention relates to a photovoltaic power generation system diagnosis system,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0002] The present invention relates to diagnosis of a photovoltaic power generation facility, and more particularly, to a photovoltaic power generation facility diagnosis system that enables accurate and reliable diagnosis of a photovoltaic power generation facility.

As global warming causes carbon emissions to emerge as a global problem, the development and application of new and renewable energy is continuously increasing as part of efforts to reduce greenhouse gases globally.

Especially, in the case of photovoltaic power generation, high-efficiency products are being developed through various types of cell processing technology, and it is expected that the application as an alternative energy source will proceed on a large scale in the future.

Therefore, the demand for diagnosis of solar power generation facilities will increase, and it is necessary to improve the efficiency through the reliable diagnosis results and to solve the potential factors that may cause the failure.

Various sensors, measurement equipment and techniques for diagnosing the solar power generation facility have been performed in various forms for a long time. For accurate and reliable diagnosis of photovoltaic power generation facilities, data from multiple measurement points must be acquired and analyzed at the same time.

A conventional technique for diagnosing a photovoltaic power generation facility has been disclosed in the publication No. 10-2012-0100184 (published on September 12, 2012) (hereinafter abbreviated as "prior art").

The disclosed prior art provides a monitoring system capable of monitoring the performance of the solar array, detecting failure of the solar array, and enabling monitoring from a remote location.

1. Published patent publication No. 10-2012-0100184 (2012.12.12. Disclosed)

However, the above-described conventional techniques have disadvantages in that efficient diagnosis of the photovoltaic power generation facility can not be performed due to a distance limitation in the process of linking the various sensors and the measurement equipment in the field.

In addition, the above-described conventional technique has a disadvantage in that it is impossible to detect an installation position error of the solar array.

In addition, it is impossible to notify the manager when the installation position of the solar array is erroneous. Thus, the conventional technology can not prevent deterioration of the solar power generation efficiency until the manager confirms the installation state of the solar array There are disadvantages.

It is an object of the present invention to provide a photovoltaic power generation facility diagnosis system that can accurately and reliably diagnose a photovoltaic power generation facility with respect to the problems of the prior art as described above .

Another object of the present invention is to provide a photovoltaic power generation facility diagnosis system that can accurately diagnose a photovoltaic power generation facility by collecting various information about the photovoltaic power generation facility and analyzing it in consideration of the correlation information of the collected information I have to.

It is another object of the present invention to provide a photovoltaic power generation facility diagnosis system that can confirm the installation position error of a solar array from a remote place.

Another object of the present invention is to provide a photovoltaic power generation system diagnosis system that automatically notifies a solar array manager when an installation error of a solar array is detected, so that the installation position of the solar array can be quickly corrected.

According to an aspect of the present invention, there is provided a system for diagnosing a photovoltaic power generation facility, including: a diagnostic information acquiring unit for acquiring diagnostic information of a solar array; A relay for collecting the diagnostic information acquired by the diagnostic information acquisition unit and relaying through the communication; And a diagnostic information analyzer for analyzing whether there is an abnormality or an installation position error of the solar array based on the diagnostic information relayed through the repeater.

The diagnostic information may include at least one of a voltage, a current, a solar radiation amount, a temperature of the solar array, an installation angle of the solar array, and a state value of the solar array.

The diagnostic information obtaining unit obtains diagnostic information of the solar array and converts the obtained diagnostic information into data of a communication protocol conforming to the sensor network communication method and outputs the data.

Wherein the diagnostic information obtaining unit comprises: a voltage / current detector for detecting a power state output from the solar array; A solar radiation amount meter for detecting a solar radiation amount around the solar array; And a thermocouple detecting the temperature around the solar array.

The diagnostic information obtaining unit may further include an array angle detector for detecting an installation angle of the solar array.

The diagnostic information obtaining unit may include an array for detecting the voltage and current values output from the solar array and the output power of the inverter for converting the DC power generated in the solar array into AC power and supplying the DC power to the power system, And a state value detector.

The diagnostic information obtaining unit may further include a wireless communication module for converting the detected diagnostic information into data of a communication protocol format corresponding to the sensor network communication method and wirelessly transmitting the data.

The diagnostic information analyzer may include a data storage unit for storing reference data for determining whether the solar array is abnormal;

And an array diagnosis unit for comparing the reference data stored in the data storage unit with the diagnosis information to diagnose an abnormality or an installation angle of the solar array.

The diagnostic information analyzer controls the array diagnosis unit to display the result information on the screen and controls the generation and transmission of abnormal information when the resultant information is abnormal or an installation angle error of the solar array. And further comprising:

The diagnostic information analyzer may further include an anomaly information generating unit for generating anomaly information of the anomaly of the solar array or an installation angle error under the control of the control unit as text information.

The diagnostic information analyzer may further include an abnormal information transmitting unit for transmitting the abnormal information generated by the abnormal information generating unit to the administrator terminal carried by the administrator through the network.

According to the present invention, various information about the photovoltaic power generation facility is collected and analyzed in consideration of the correlation therebetween, so that there is an effect that accurate and reliable diagnosis can be performed on the solar and power generation facilities.

In addition, according to the present invention, it is possible to confirm the installation position error of the solar array at a remote location.

In addition, according to the present invention, when the installation error of the solar array is detected, the solar array manager is automatically notified so that the installation position of the solar array can be quickly corrected.

1 is a block diagram of a solar power generation system diagnosis system according to the present invention;
FIG. 2 is a block diagram of an embodiment of the diagnostic information obtaining unit of FIG. 1. FIG.
3 is a block diagram of an embodiment of the diagnostic information analyzer of FIG.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail.

1 is a block diagram of a solar power generation system diagnosis system according to the present invention.

1, a PV system diagnosis system according to the present invention includes a solar array unit 10, an inverter 20, a diagnostic information obtaining unit 30, a repeater 40, a receiver 50, A diagnostic information analyzer 60, a network 70 and an administrator terminal 80. [

The solar array unit 10 converts light energy generated from sunlight into electrical energy to produce electricity. A plurality of solar arrays are arranged in the solar array unit 10, and one solar array includes a plurality of solar modules. The solar modules include a solar cell and a photo-electric converter . Each solar array is composed of the same components and the same operation is performed.

The inverter 20 converts DC power obtained from the sunlight array unit 10 into AC power and supplies power to loads requiring AC power.

The diagnostic information acquiring unit 30 acquires diagnostic information of the solar array.

The diagnostic information obtaining unit 30 converts the obtained diagnostic information into data of a communication protocol conforming to the sensor network communication method and outputs the data. When the diagnostic information is acquired by the sensor network method, there is no need to install a wired line to acquire diagnostic information, and there is no inconvenience in transmitting the acquired diagnostic information. In particular, when the sensor network system acquires new diagnostic information or removes, adds, or changes the sensor for acquiring diagnostic information, it becomes possible to easily acquire diagnostic information without complicated operations.

Here, the diagnostic information preferably includes at least one of an output voltage of the solar array, an output current, a solar radiation amount, a temperature, an installation angle of the solar array, and a state value of the solar array.

2, the diagnostic information obtaining unit 30 includes a voltage / current detector 31 for detecting a power state output from the solar array unit 10, (32) for detecting the solar radiation amount of the solar array unit (10), and a thermocouple (33) for detecting the temperature around the solar array unit (10).

The diagnostic information obtaining unit 30 preferably includes an array angle detector 34 for detecting an installation angle of the solar array in the solar array unit 10, a voltage and current value output from the solar array, And an array state value detector 35 for detecting the output power of the inverter as an array state value.

The diagnostic information obtaining unit 30 further includes a wireless communication module 36 that converts the detected diagnostic information into data of a communication protocol format corresponding to the sensor network communication method and wirelessly transmits the data.

The repeater 40 collects the diagnostic information obtained by the diagnostic information obtaining unit 30 and plays a role of relaying through the communication. The repeater 40 communicates with a plurality of sensors in the diagnostic information obtaining unit 30 through a sensor network communication method to collect diagnostic information.

The receiver 50 plays a role of receiving diagnostic information through the wireless communication with the relay 40. The receiver 50 wirelessly communicates directly with the repeater 40 to acquire diagnostic information or connect to the repeater 40 through the network to receive diagnostic information.

The diagnostic information analyzer 60 analyzes the presence or absence of an abnormality in the solar array and the installation position error based on the diagnosis information relayed through the relay 40. [ The diagnostic information analyzer 60 can be implemented as an IT device such as a personal computer, a notebook, a smart phone, a personal information terminal, or an iPad, which can analyze the presence or absence of a solar array based on a built- .

The diagnostic information analyzer 60 includes a diagnostic information input unit 61 for receiving diagnostic information received from the receiver 50, a data storage unit 62 for storing reference data for determining whether the solar array is abnormal, An array diagnostic unit 63 for comparing the reference data stored in the data storage unit 62 with the diagnostic information input through the diagnostic information input unit 61 to diagnose an abnormality or an installation angle of the solar array, .

In addition, the diagnostic information analyzer 60 preferably controls the array diagnosis unit 63 to display the result information on the screen, and when the result information is abnormal or an installation angle error of the solar array, And a control unit 64 for controlling information generation and transmission.

The diagnostic information analyzer 60 further preferably includes a display unit 65 for displaying diagnostic information or displaying diagnostic result information under the control of the control unit 64, An abnormal information generating unit 66 for generating abnormal information about an abnormal state of the array or an installation angle error in the form of a text message, an error information generating unit 66 for generating a text message generated by the abnormal information generating unit 66, And an abnormal information transmitting unit 67 for transmitting the abnormal information.

A specific operation of the solar power generation facility diagnosis system according to the present invention will now be described.

First, the solar array unit 10 installed on the site converts light energy generated from sunlight into electric energy and outputs the electric energy. Here, a plurality of solar arrays are arranged in the solar array unit 10, and the configuration and operation of each solar array are the same. Therefore, only one solar array will be described below for convenience of explanation.

The power (voltage, current) generated from the solar array is converted into an AC power source through the inverter 20 and supplied to a place where an AC power source is required.

Meanwhile, the diagnostic information obtaining unit 30 detects the voltage and current output status of the solar array and diagnostic information about the surrounding environment, and transmits the diagnostic information to the repeater 40 through the wireless communication module 36.

For example, as shown in FIG. 2, the voltage / current detector 31 detects the voltage / current output from the solar array and transfers it to the wireless communication module 36. The voltage / current detector 31 preferably uses a voltage detection sensor for sensing a normal output voltage and a current detection sensor for sensing an output current.

In addition, the solar irradiator 32 is installed in the vicinity of the solar array to detect the solar radiation amount of solar light and transmit it to the wireless communication module 36. In addition, the thermocouple 33 detects the temperature of the solar array and transmits the detected temperature to the wireless communication module 36. The array angle detector 34 detects the inclination angle of the solar array and transmits the detected angle to the wireless communication module 36.

Here, the array angle detector 34 preferably uses a tilt angle sensor, a gyro sensor, GPS, or the like that detects the tilt with respect to the gravity direction (vertical direction) of the earth. Usually, a pendulum is mounted on the angle input shaft of the inclination angle sensor. There is a torque balance method that makes the pendulum always stay in zero by balancing the displacement method which outputs the angle directly from the reference side of the pendulum pointing in the direction of gravity and the torque caused by flowing the electromagnetic wave in the electromagnetic coil and the tilt of the pendulum. The torque balance equation corresponds to the inclination angle of the coil current value. In the present invention, it is assumed that either the displacement method or the torque balance method is applied.

The array state value detector 35 compares the voltage / current value output from the solar array and the voltage / current value output from the inverter to the state value of the solar array and transmits the voltage / current value to the wireless communication module 36 do.

The wireless communication module 36 generates diagnostic information of the corresponding solar array by mapping a unique number (ID number) for identifying the solar array to each of the diagnostic information detected in one solar array, And transmits the generated diagnosis information to the repeater 40 in the form of a radio signal suitable for communicating with the repeater 40.

The diagnostic information generated in the solar array is transmitted to the repeater 40. The repeater 40 collects the diagnostic information transmitted through the short-range wireless communication from each solar array, converts the diagnostic information into a wireless signal, and transmits the wireless signal to the remote diagnosis information analyzer 60 in real time or periodically. Although it is advantageous in terms of accuracy in transmitting diagnostic information in real time, there is a concern that power is wasted and simultaneous transmission of a large amount of data may take a long time to process diagnostic information. In addition, it is advantageous to periodically transmit the diagnostic information to solve the problem of power consumption and to process the data transmitted every predetermined period, so that the processing time of the diagnostic information can be shortened. However, since it is a non-real time transmission method, . Therefore, it is desirable for the system designer to appropriately determine the transmission method of the diagnostic information in consideration of the advantages and disadvantages, the amount of data to be generated, the degree of information processing, and the like.

Diagnostic information transmitted through the communication from the solar array installed in the field is received at the remotely located receiver 50 and then transmitted to the diagnostic information analyzer 60.

The diagnosis information input unit 61 of the diagnostic information analyzer 60 transmits the diagnostic information transmitted from the receiver 50 to the array diagnosis unit 63.

The array diagnostic unit 63 compares input diagnostic information with reference data for determining whether there is an abnormality in the solar array stored in the data storage unit 62 and an installation angle error to determine whether or not the solar array is abnormal, .

For example, if the output voltage and the output current of the solar array are compared with the reference data (tolerance range) in the diagnostic information and the output voltage and the output current are out of the tolerance range, the efficiency of the solar array If it is determined that the output voltage and the output current are significantly lower than the lower limit of the tolerance range, the solar array is ultimately determined to be faulty. Here, since the tolerance range or the reasonably low value may vary depending on the maker of the solar array, it is preferable to use a tolerance range of the rating provided by the manufacturer of the solar array and a reference value for determining the low tolerance range.

In addition, the solar radiation amount of the diagnostic information is compared with the average solar radiation amount of the month stored in the data storage unit 62 to determine whether the solar radiation amount has changed, or whether the output voltage and current have changed due to the solar radiation amount.

The temperature of the solar array is compared with a reference temperature for determining the presence or absence of an abnormality of the solar array stored in the data storage unit 62. When the temperature of the solar array is higher than the reference temperature, It is judged that the optical array has failed.

As described above, the present invention utilizes the diagnostic information alone, but the presence or absence of the solar array is more accurately determined by analyzing the abnormality of the solar array in consideration of the correlation with other diagnostic information.

In addition, the array diagnosis unit 63 compares the status values of the solar array (the output voltage / current value of the solar array with the output voltage / current value of the inverter) among the diagnostic information to find a problem in the solar array Or whether a problem has occurred in the inverter. By using such state values, it is possible to more accurately determine the presence or absence of an abnormality in the solar array.

According to another aspect of the present invention, it is possible to remotely determine an installation position error of the solar array.

For example, the array diagnosis unit 63 extracts the solar array installation angle information from the inputted diagnostic information, extracts the installation angle information of the first solar array already registered in the data storage unit 62, It is determined whether the installation angle of the solar array is changed or the installation angle is abnormal. Here, the data storage unit 62 stores installation angle information of each solar array installed in the field.

That is, the database of the data storage unit 62 is searched by using the unique number of the solar array included in the installation angle information of the solar array extracted from the diagnostic information, and the installation angle information of the corresponding solar array is extracted .

Thereafter, the installed angle information is compared with the previously registered installation angle information, and it is determined whether or not they match. If they match, the installation angle of the solar array is determined to be normal. On the other hand, when the diagnosed installation angle information and the pre-registered installation angle information do not match, it is determined that the installation angle of the solar array is abnormal. In this case, the solar array may be distorted due to external factors such as wind and rain, or may be erroneously installed at the time of initial installation.

The diagnosis result information diagnosed by the array diagnosis unit 63 is transmitted to the control unit 64. [

The control unit 64 stores the diagnosis result information in the data storage unit 62 and displays the diagnosis result information on the display unit 65. The manager of the solar array confirms the diagnosis result information displayed on the display unit 65 directly with the naked eye to recognize the state of the solar array. However, the above method has the inconvenience that the administrator always has to directly confirm it.

Accordingly, in the present invention, the inconvenience described above is solved, and the manager transmits the abnormal information of the solar array to the manager terminal carried by the manager so that the manager can recognize the abnormality promptly when the solar array is abnormal.

For example, the abnormality information generating unit 66 generates abnormality information of the solar array under the control of the control unit 64 in the form of a text message and transmits it to the abnormality information transmitting unit 67. In this case, the generated text message preferably includes installation position information of the solar array arising from the abnormality, abnormality information of the solar array, information on whether or not the installation angle of the solar array is erroneous, and the like.

The abnormal information transmission unit 67 receives the contact number information of the manager terminal 80 that wants to transmit the abnormality of the solar array from the control unit 64, maps the text message to the contact number, ). Here, the network 70 is a communication network for transmitting a text message to the administrator terminal 80.

As a result, a text message indicating the presence or absence of an abnormality of the solar array is received in the administrator terminal 80, and the administrator can easily know what trouble has occurred in the solar array installed in the area through the received text message. It is then desirable for the administrator to take quick action so that the solar array can operate normally.

As described above, the present invention can accurately determine whether there is an abnormality of the solar array or an installation angle error, and the manager can quickly know whether or not the solar array is abnormal.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims and their equivalents. Of course, such modifications are within the scope of the claims.

10 ... The solar array part
20 ... inverter
30 ... The diagnostic information obtaining unit
40 ... Repeater
60 ... Diagnostic Information Analyzer
80 ... Administrator terminal

Claims (11)

A system for diagnosing a solar power plant, comprising:
A diagnostic information acquiring unit for acquiring diagnostic information of the solar array installed on the field and outputting the diagnostic information based on the sensor network; A relay for collecting the diagnostic information acquired by the diagnostic information acquisition unit and relaying through the communication; And a diagnostic information analyzer for analyzing whether there is an abnormality or an installation position error of the solar array based on the diagnostic information relayed through the repeater;
Wherein the diagnostic information acquiring unit further includes an array angle detector for detecting an installation angle of the solar array, acquiring diagnostic information of the solar array, and transmitting the acquired diagnostic information to a communication protocol data And outputs it,
Wherein the diagnostic information analyzer comprises: a data storage unit for storing reference data for determining whether the solar array is abnormal; An array diagnostic unit for comparing the reference data stored in the data storage unit with the diagnostic information to diagnose an installation angle or more of the solar array; A controller for controlling generation and transmission of abnormal information when the result information of diagnosis is an installation angle error of the solar array; An abnormal information generating unit for generating abnormal information about an installation angle error of the solar array in the form of a text message under the control of the controller; And an abnormal information transmitting unit for transmitting the abnormal information in the form of a text message generated by the abnormal information generating unit to an administrator terminal carried by the administrator through the network.
The solar array according to claim 1, wherein the diagnostic information includes at least one of an output voltage of the solar array, an output current, an irradiation amount, a temperature, an installation angle of the solar array, Power generation facility diagnosis system.
delete The system according to claim 1, wherein the diagnostic information obtaining unit comprises: a voltage / current detector for detecting a power state output from the solar array; A solar radiation amount meter for detecting a solar radiation amount around the solar array; And a thermocouple for detecting a temperature around the solar array.
delete The diagnostic information acquisition unit according to claim 4, wherein the diagnostic information obtaining unit obtains an output power of an inverter that converts the voltage and current values output from the solar array and the DC power generated in the solar array into AC power, And an array state value detector for detecting the state of the photovoltaic power generation facility.
The diagnostic system of claim 4, wherein the diagnostic information obtaining unit further includes a wireless communication module for converting the detected diagnostic information into data of a communication protocol format corresponding to the sensor network communication method and wirelessly transmitting the data. .
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