KR102137775B1 - Data Monitoring & Deciding Apparatus for Photovoltaic Data with Remote Function and Photovoltaic Data Monitoring System using It - Google Patents

Abstract

The present invention relates to a photovoltaic data surveillance/determination device including a remote function and a photovoltaic data monitoring system using the same, capable of optimizing solar power generation. According to the present invention, the photovoltaic data surveillance/determination device including the remote function includes: a collection module (11); a primary determination module (12); an auxiliary storage unit (14); a secondary determination module (13); a transmission module (16); a self-check module (15) for checking an abnormality of the collection module (11) or the primary determination module (12), and operating the secondary determination module (13) when the primary determination module (12) has the abnormality; and a power supply unit (17).

Description

A photovoltaic data monitoring and judgment device including a remote function and a photovoltaic data monitoring system using the same {Data Monitoring & Deciding Apparatus for Photovoltaic Data with Remote Function and Photovoltaic Data Monitoring System using It}

The present invention relates to a photovoltaic data monitoring and determination device including a remote function and a photovoltaic data monitoring system using the same, and more specifically, collecting and transmitting data of various facilities and sensors constituting the photovoltaic power generation facility. In the process, it checks whether the data is abnormal and self-checks whether the internal processor is abnormal, so that only normal data is transmitted, it improves the reliability of data related to photovoltaic power generation and monitors it to provide a remote function to optimize the photovoltaic power generation. The present invention relates to a photovoltaic data monitoring and determination device including a photovoltaic data monitoring system using the same.

Photovoltaic power generation is a power generation method that directly converts sunlight into electric energy using a solar cell without the help of a generator.It can be generated with direct light as well as diffused light, so it can be generated regardless of weather conditions, as well as close to infinity. Since solar power is used, there is an advantage of low cost of power generation, no pollution, and easy maintenance. However, there are disadvantages in that the amount of electricity produced depends on the amount of sunlight, the installation location is limited, and the initial investment cost is high.

However, due to the recent increase in the production of polysilicon, the main material of solar cells, the unit cost of cells has decreased, and the initial investment cost is reduced, and the construction of power generation facilities is relatively simple, so solar power generation using solar energy, which has excellent power generation efficiency compared to investment, is in the limelight. The situation is being received.

On the other hand, a typical photovoltaic power generation facility includes a solar cell, a storage battery, and a power converter, and when the sunlight is split into the solar cell, the potential difference that occurs when holes and electrons are generated in the solar cell due to the energy of the sunlight. Electricity is produced using the principle that current flows through it. Photovoltaic power generation using this principle is one of the technologies related to renewable energy to escape from fossil energy, and the demand for understanding is rapidly increasing due to the advantage of being eco-friendly without fuel cost.

However, in the photovoltaic power generation, the amount of power production depends on the amount of sunlight, and a large installation area is required to install a large-capacity photovoltaic power generation facility. In addition, it is not easy to grasp the amount of sunshine and temperature by time in the installation area, and it is difficult to determine whether the solar panel operates normally or the efficiency of the photovoltaic power generation facility and the amount of power generated by the photovoltaic power generation. The disadvantage is that the larger the installation area, the more difficult it is to maintain and maintain the photovoltaic power generation facility.

In addition, as the connection panel and the inverter are included in the photovoltaic power generation facility, and many sensors are attached, the technology for the data collection device and monitoring is also developing. The photovoltaic data collection device collects equipment data and sensor data, and transmits the data to a remote server, and monitors it through a monitoring device. However, even if data is transferred from the photovoltaic data collection device to a remote server, considering the fact that a failure may occur in various parts of the photovoltaic data collection device, it is difficult to trust the accuracy and effectiveness of the monitoring data. There is a problem that it is difficult for facility managers to manage solar power facilities normally.

The causes of the above-described photovoltaic data collection device failure include internal power failure, communication error, circuit failure, and inoperability of the data collection device. When such a failure occurs, maintenance of the photovoltaic power generation facility becomes difficult. There is a problem.

In other words, the conventional photovoltaic data collection device simply performs a function of collecting and transmitting data and does not judge whether there are any abnormalities in the components, so it is not easy for facility managers to judge the accuracy and validity of the data. Therefore, it becomes difficult to maintain and maintain the photovoltaic power generation facility using data reliability.

Meanwhile, as a result of investigating prior art related to the present invention, a number of patent documents have been searched, and some of them are as follows.

Patent Document 1, the monitoring device receives the temperature value of the photovoltaic array from the photovoltaic array or status information including the component temperature inside the inverter from the inverter, and maintenance of the component or photovoltaic array based on the received external information It is implemented through the process of judging whether it is necessary, and monitors the status of major components of the photovoltaic power generation system in real time, increases the life span of each component, and increases the power generation efficiency of the photovoltaic power generation facility. Disclosed is a method for monitoring a photovoltaic facility and a monitoring device used therefor.

Patent document 2, a solar cell array for concentrating solar light incident from the outside to produce electricity, a connection panel for collecting and outputting DC current produced from the solar cell array, and a DC current transmitted through the connection panel An inverter for receiving and converting the received direct current to an alternating current and supplying it to an electric power consumer, a sensor unit for detecting weather information, including the presence or absence of an abnormality in the solar cell array, the connection panel, and the inverter, and the solar cell array A local monitoring system that displays whether the connection panel and the inverter are abnormal together with the generated power generation amount and weather information detected from the sensor unit, and a KEPCO system that supplies power to a customer when power is not produced from the solar cell array. And a home monitoring system that displays the amount of electricity produced and the amount of electricity produced from the solar cell array, weather information, the failure/failure of the photovoltaic power generation system, and the amount of power supplied from the KEPCO system. Disclosed is a monitoring and control system for solar power generation facility management that accurately calculates the amount of power and the amount of power supplied from the KEPCO system to promote convenience for users.

Patent Document 3 is a sequential wireless transmission system of monitoring data of a photovoltaic power generation facility that monitors current/voltage states of a plurality of photovoltaic panels constituting a photovoltaic power generation facility and sequentially transmits the data. A distribution panel is installed for each set of solar cell modules, and each distribution panel includes a current/voltage detection unit, a communication module and a data storage unit, and each distribution panel is given a sequence number, and each distribution panel is detected from the current/voltage detection unit belonging to it. Photovoltaic power generation that collects data transmitted from the previous switchboard to data and stores the data in the data storage unit to perform general data transmission to the next switchboard through the communication module, or to perform leap data transmission that skips the next switchboard A sequential wireless transmission system for facility monitoring data is disclosed.

KR 10-1061220 B1 KR 10-1390405 B1 KR 10-1580669 B1

The present invention has been devised to solve the above-described problems of the prior art, and checks whether data is abnormal in the process of collecting and transmitting data of various facilities and sensors constituting a photovoltaic power generation facility, and whether an internal processor is abnormal. After self-checking, only normal data is transmitted to improve the reliability of data related to photovoltaic power generation, and monitor and judge photovoltaic power data including remote functions to monitor and optimize photovoltaic power generation, and photovoltaic power generation using the same The purpose is to provide a data monitoring system.

The photovoltaic power data monitoring and determination device including the remote function of the present invention for achieving the above object, collects sensing data and facility data of the photovoltaic power generation facility at the request of a server provided in the system operation unit and determines whether the data is abnormal. As a solar power data monitoring and judgment device including a remote function to determine,
A collection module for collecting data from a plurality of sensors and a plurality of facilities provided in the solar power generation facility at the request of the server; A first determination module for determining whether data collected in real time is abnormal; An auxiliary storage unit that stores data determined as normal by the primary determination module when there is no data request from the server, and provides stored data according to the server request; A second judgment module that performs the same function as the first judgment module and operates when an error occurs in the first judgment module; A transmission module for transmitting real-time data judged as normal by the primary judgment module or secondary judgment module to the server or transmitting data stored in the auxiliary storage unit to the server; A self-checking module that checks whether the collection module or the primary judgment module is abnormal and operates the secondary judgment module when it is determined that there is an abnormality in the primary judgment module; Includes; a power supply for supplying power;
The primary judging module has a function of determining whether a data request from a server has been received, a function of determining whether data is collected by the collection module, a temperature range value and a specification of a connection panel and an inverter for data transmitted from the photovoltaic power generation facility. A function that detects abnormal data by comparing ranges, and performs a function of monitoring whether a facility is abnormal through heartbeat information of a connection panel and an inverter, and weather sensors, connection panels, and inverters of the photovoltaic power generation facility. Real-time data transmitted from the transfer to the transmission module,
The power supply unit is a collection power supply unit for supplying power to the collection module, a main power supply unit for supplying power to the primary determination module, the transmission module, the self-check module and the auxiliary storage unit, and the secondary operation by the self-check module In addition to being divided into an emergency operating power supply for supplying power to the determination module and the auxiliary storage unit, the collection power supply unit, the main power supply unit, and the emergency operating power supply unit are configured to independently supply power.
The auxiliary storage unit is configured to store data of the primary determination module when an error occurs in the transmission module, and after the abnormality of the transmission module is released, the stored data is transmitted through the transmission module and then deleted.
The self-checking module activates the secondary determination module in case an unexpected error occurs in the primary determination module or the primary determination module operates abnormally, resets the main power supply, resets the primary determination After confirming that the module is operating normally, after the operation of the secondary judgment module is terminated, the data of the primary judgment module is transmitted to the server, and after storing reset information and abnormal data log values in the auxiliary storage unit. It is characterized by transmitting the abnormal data log value at the request of the server.
In addition, the system operation unit transmits a data request packet to the primary determination module at regular intervals, a server having a main storage unit in which power generation-related data is stored as a database, and converts the data received through the transmission module to analyze and judge it. If it is determined that the data is characterized in that it comprises a final judgment unit for storing data in the main storage unit of the server and, if it is determined to be abnormal data, to request the data to the primary judgment module again.

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In addition, the photovoltaic data monitoring system according to the present invention includes the photovoltaic data collection device for collecting data of a photovoltaic power generation facility, and a system operation unit for processing and monitoring the collected data, and the system operation unit It characterized in that it further comprises a monitoring unit for displaying the database stored on the server as a screen.

In the process of collecting and transmitting data of various facilities and sensors constituting the photovoltaic facility, the photovoltaic data monitoring and determination device including the remote function according to the present invention and the photovoltaic power data monitoring system using the same are checked for data anomalies. By checking and self-checking whether the internal processor is abnormal, only normal data is transmitted, thereby improving the reliability of data related to photovoltaic power generation and monitoring it, thereby optimizing photovoltaic power generation.

In addition, according to the photovoltaic data monitoring and determination device including the remote function of the present invention and the photovoltaic data monitoring system using the same, as the power section is divided into a plurality and independently controlled, data transmission failure due to a power supply failure is prevented. It is effective in preventing confusion due to double transmission of data.

In addition, according to the photovoltaic data monitoring and determination device including the remote function of the present invention and the photovoltaic data monitoring system using the same, if an error occurs in the primary determination module, the self-check module resets the main power supply unit and the emergency operating power supply unit. Through this, the secondary judgment module is operated, so data is stably transmitted to the server regardless of the error of the primary judgment module.

In addition, according to the photovoltaic data monitoring and determination device including the remote function of the present invention and the photovoltaic data monitoring system using the same, as the server and the final judgment unit are provided in the system operation unit, the data transmitted from the data collection device is the main storage unit. In addition to being able to store it in the database, it is possible to determine whether the transmitted data is normal data and store only normal data, thereby improving the reliability of the database.

In addition, according to the photovoltaic data monitoring and determination device including the remote function of the present invention and the photovoltaic data monitoring system using the same, a monitoring unit is provided in the system operation unit to collect photovoltaic facilities and data as the database is displayed on the screen. This has the effect of being able to check in real time whether the device is operating normally.

1 is a block diagram schematically showing an apparatus for monitoring and determining photovoltaic power generation data including a remote function according to the present invention.
Figure 2 is a block diagram schematically showing a photovoltaic data monitoring system according to the present invention.

Hereinafter, a photovoltaic data monitoring and determination device including a remote function of the present invention and a photovoltaic data monitoring system using the same will be described with reference to the accompanying drawings.

Terms used in the present invention are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of the user or operator, so definitions of these terms are consistent with the technical matters of the present invention. And should be interpreted as a concept.

In addition, the embodiments of the present invention are not intended to limit the scope of the present invention, but are merely illustrative of the components presented in the claims of the present invention, and are included in the technical idea throughout the specification of the present invention and of the claims. It is an embodiment including a component that can be substituted as an equivalent in the component.

And, the optional terms in the embodiments below are used to distinguish one component from other components, and the component is not limited by the terms.

Accordingly, in describing the present invention, detailed descriptions of related well-known technologies that may unnecessarily obscure the subject matter of the present invention are omitted.

1 is a block diagram schematically showing an apparatus for monitoring and determining photovoltaic data including a remote function according to the present invention, and FIG. 2 is a photovoltaic data monitoring according to the present invention. It is a block diagram schematically showing the system.

The solar power data monitoring and determination device including a remote function according to the present invention is a solar power facility 20 according to the request of the server 31 provided in the system operation unit 30, as shown in FIGS. 1 and 2. It is a device that collects sensing data and facility data and determines whether the data is abnormal.

Specifically, the photovoltaic data monitoring and determination device 10 including the remote function of the present invention receives data from a plurality of sensors and a plurality of facilities provided in the solar power generation facility 20 at the request of the server 31. A collection module 11 for collecting; A primary judgment module 12 and a secondary judgment module 13 for determining whether data collected in real time is abnormal; An auxiliary storage unit (14) for storing data of the primary judgment module (12) when there is no data request from the server (31) or when the transmission module (16) is abnormal; A transmission module 16 for transmitting real-time data determined by the primary judgment module 12 or the secondary judgment module 13 or data stored in the auxiliary storage 14 to the server 31; A self-checking module that checks whether the collection module 11 or the primary judgment module 12 is abnormal and operates the secondary judgment module 13 when it is confirmed that there is an abnormality in the primary judgment module 12 15) and; It comprises a; power supply unit 17 for supplying power to each of the modules.

The collection module 11 collects data such as temperature, solar radiation, and wind speed from a plurality of sensors provided in the solar power generation facility 20, and also connects the connection panel 22 and the inverter constituting the solar power generation facility 20. The data from (23) will be collected.

In addition, the primary determination module 12 is a function for determining whether a data request from the server 31 has been received, a function for determining whether data is collected by the collection module 11, and from the solar power generation facility 20. The function of detecting abnormal data through the actual temperature range value and the specification range of the connecting panel and the inverter, and the function of monitoring the abnormality of the facility through the heartbeat information of the connecting panel and the inverter, respectively. It performs, and transmits the real-time data transmitted from the weather sensor 21, the connection panel 22, and the inverter 23 of the solar power generation facility 20 to the transmission module 16.

In addition, the secondary judgment module 13 is operated by the self-checking module 15 when an unexpected error occurs in the primary judgment module 12 and does not function properly. The same function as the module 12 is performed.

The secondary storage unit 14 collects data determined by the primary judgment module 12 when there is no data request from the server in the primary judgment module 12 or when an error occurs in the transmission module 16. Is stored. At this time, the data stored in the auxiliary storage unit 14 is the server 31 through the transmission module 16 when the transmission module 16 is operating normally or when the data request from the server 31 is confirmed. Data is transferred, and data that has been transferred is deleted.

The self-checking module 15 checks the abnormality of various modules constituting the data collection device 10, and checks the abnormality of each module in a synchronous, sequential process. Therefore, when an unexpected error occurs in each module stage, it is possible to diagnose the errors of the modules. For example, if an unexpected error occurs in the primary judgment module 12 or the primary judgment module 12 operates abnormally, the secondary judgment module 13 is operated and the main power supply unit ( 17b) will be reset. Then, when it is confirmed that the primary judgment module 12 is normally operated after the reset, the operation of the secondary judgment module 13 is ended and data of the primary judgment module 12 is transmitted to the server. After storing the reset information and the abnormal data log value in the auxiliary storage unit 14, the abnormal data log value is transmitted at the request of the server 31.

In this way, when an error occurs in the primary determination module 12, the self-check module 15 resets the main power unit 17b and enables the secondary determination module 13 to operate through the emergency operating power unit 17c. , Regardless of whether an error occurs in the primary judgment module 12, data can be stably transmitted to the server 31.

The transmission module 16 transmits real-time data or data stored in the auxiliary storage unit 14 to the server 31, and includes at least two of RS-485, TCP/IP, and LORA. desirable. This is to minimize the phenomenon that data is not transmitted due to a communication error by allowing data to be transmitted through different methods.

The power supply unit 17 is for supplying power to each module constituting the data collection device 10, the collection power supply unit 17a for supplying power to the collection module 11, and the primary determination module 12 ) And the transmission module 16, the self-check module 15 and the main power supply unit 17b for supplying power to the auxiliary storage unit 14, and the self-check module 15 is operated by the second determination module ( 13) and an auxiliary operating unit (14c) for supplying power to the auxiliary storage unit (14c). In addition, the collection power supply unit 17a, the main power supply unit 17b and the emergency operating power supply unit 17c are configured to supply power independently, and the system operating unit 30 receives a separate reset command to cut off the power or It is configured to connect.

As described above, as the power supply unit 17 is divided into a plurality and controlled independently, data transmission failure due to abnormality of the power supply unit 17 is prevented, and confusion due to double transmission of data is prevented.

The system operation unit 30 transmits a data request packet to the primary determination module 12 at regular intervals, and a server 31 having a main storage unit 32 in which power generation related data is stored as a database, and the transmission module 16 Converts the received data through analysis and judgment, and if it is determined to be normal data, stores the data in the main storage unit 32 of the server 31 and, if it is judged to be abnormal data, re-sets the data in the primary judgment module 12 It includes the final decision unit 33 to request.

At this time, the server 31 is configured to transmit a data request packet to the primary judgment module 12 at a period of approximately 10 seconds, and the final judgment part 33 is data stored as a database in the main storage part 32 It is judged whether there is an abnormality on the basis of. Specifically, the final determination unit 33 determines whether an abnormality is based on data of the same time ago one day, and when the same problem occurs repeatedly, an abnormality data warning alarm is generated.

As described above, as the server 31 and the final judgment unit 33 are provided in the system operation unit 30, the data transmitted from the data collection device 10 can be stored in the database of the main storage unit 32 as well. Based on this, it is determined whether the transmitted data is normal data, and only the normal data is stored, thereby improving the reliability of the database.

The photovoltaic data collection device of the present invention configured as described above checks whether data is abnormal in the process of collecting and transmitting data of various facilities and sensors constituting the photovoltaic power generation facility and self-checking whether the internal processor is abnormal. Afterwards, by transmitting only normal data, it is possible to improve the reliability of data related to photovoltaic power generation and to optimize the photovoltaic power generation by monitoring it.

Meanwhile, the photovoltaic data monitoring system according to the present invention monitors the photovoltaic data using the photovoltaic data collection device 10 described above. As shown in FIG. 2, the data collection device ( 10) includes a system operating unit 30 that processes and monitors the collected data, and the system operating unit 30 includes the server 31, the main storage unit 32, and the final determination unit 33, in addition to the server 31. It further comprises a monitoring unit 35 for displaying the database stored in the main storage unit 32 of the screen.

As described above, when the monitoring unit 35 is provided on the system operation unit 30 to display a database on a screen, a system administrator can check whether the solar power generation facility 20 and the data collection device 10 are operating normally in real time. You can check with.

Although described and illustrated in connection with some embodiments for illustrating the technical idea of the present invention, the present invention is not limited to the configuration and operation as described above, and the scope of the technical idea described in the description of the invention It will be understood by those skilled in the art that many changes and modifications to the present invention are possible without departing. Accordingly, all such suitable changes and modifications and equivalents should be considered to be within the scope of the present invention.

10...Data collection device
11...Collection module
12...1st judgment module
13... Secondary judgment module
14...Auxiliary storage
15...self check module
16...Communication module
17...Power supply
17a... collection power supply
17b... main power supply
17c... emergency operation power supply
20...Solar Power Generation Equipment
21...weather sensor
22...box
23...Inverter
30...system operation department
31...server
32...Main storage
33...Final Judgment
35...monitoring part

Claims (5)

At the request of the server 31 provided in the system operation unit 30, monitoring and determining solar power data including a remote function that collects sensing data and facility data of the solar power facility 20 and determines whether the data is abnormal. As device 10,
A collection module 11 for collecting data from a plurality of sensors and a plurality of facilities provided in the solar power generation facility 20 at the request of the server 31;
A primary judgment module 12 for determining whether data collected in real time is abnormal;
When there is no data request from the server 31, the primary judging module 12 stores data determined as normal, and provides an auxiliary storage unit 14 that provides data stored at the request of the server 31. Wow;
A second judgment module 13 that performs the same function as the first judgment module 12 and operates when an error occurs in the first judgment module 12;
The primary judgment module 12 or the secondary judgment module 13 transmits real-time data determined to be normal to the server 31 or transmits data stored in the auxiliary storage 14 to the server 31. And the transmission module 16;
A self-checking module that checks whether the collection module 11 or the primary judgment module 12 is abnormal and operates the secondary judgment module 13 when it is confirmed that there is an abnormality in the primary judgment module 12 15) and;
It includes; a power supply unit 17 for supplying power;
The primary determination module 12 is a function for determining whether a data request from the server 31 has been received, a function for determining whether data is collected by the collection module 11, transmitted from the solar power generation facility 20 Through the function of detecting abnormal data by comparing the temperature range value with the specification range of the connection panel 22 and the inverter 23, and through the heart bit information of the connection panel 22 and the inverter 23 Each function performs a function of monitoring whether the facility is abnormal, and transmits real-time data transmitted from the weather sensor 21, the connection panel 22, and the inverter 23 of the photovoltaic power generation facility 20 to the transmission module 16. To pass on,
The power supply unit 17 includes a collection power supply unit 17a for supplying power to the collection module 11, the primary determination module 12, the transmission module 16, the self-check module 15, and the auxiliary storage unit 14 ), the main power supply 17b for supplying power, and the emergency operation power supply 17c operated by the self-check module 15 to supply power to the secondary determination module 13 and the auxiliary storage 14 In addition to being formed in a divided manner, the collection power supply unit 17a, the main power supply unit 17b, and the emergency operating power supply unit 17c are configured to supply power independently, respectively.
The auxiliary storage unit 14 stores the data of the primary determination module 12 when an abnormality occurs in the transmission module 16, and after the abnormality of the transmission module 16 is released, the stored data is It is configured to be deleted after being transmitted through the transmission module 16,
The self-checking module 15 operates the secondary determination module 13 when an unexpected error occurs in the primary determination module 12 or the primary determination module 12 operates abnormally. After resetting the main power supply unit 17b and confirming that the primary judgment module 12 is operating normally after reset, the operation of the secondary judgment module 13 is terminated, and then the data of the primary judgment module 12 is restored. In addition to being transmitted to the server 31, a remote characterized in that it stores the reset information and the abnormal data log values in the auxiliary storage unit 14 and then transmits the abnormal data log values at the request of the server 31. PV monitoring and judgment device including functions. delete delete According to claim 1,
The system operation unit 30 transmits a data request packet to the primary determination module 12 at regular intervals, and a server 31 having a main storage unit 32 in which power generation related data is stored as a database, and the transmission module 16 Converts the received data through analysis and judgment, and if it is determined to be normal data, stores the data in the main storage unit 32 of the server 31 and, if it is judged to be abnormal data, re-sets the data in the primary judgment module 12 Solar power data monitoring and determination device including a remote function, characterized in that it comprises a final decision unit (33) to request. The solar power generation data monitoring and determination device 10 including the remote function of claim 1 or 4, which collects the data of the solar power generation facility 20, and the system operation unit 30 for processing and monitoring the collected data Including,
The system operating unit 30 further comprises a monitoring unit 35 for displaying a database stored on the server 31 as a screen, a photovoltaic data monitoring system.

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