KR102347881B1 - Monitoring apparatus for solar power generation supporting automatic protocol setting and automatic protocol setting method of the same - Google Patents

Abstract

The present invention relates to a monitoring apparatus for solar power generation supporting automatic protocol setting and an automatic protocol setting method thereof, and more particularly, to a monitoring apparatus for solar power generation and an automatic protocol setting method thereof, in which a protocol for communication with solar power generation facilities for solar power generation with different protocols for each manufacturer and facility type is automatically identified and set. According to the monitoring apparatus of an embodiment of the present invention, the monitoring device obtains a data value from a data packet by analyzing a data packet transmitted from a solar power generation facility that requires protocol setting for one or more protocols possessed by each facility type, and the data value obtained through the analysis is compared with a normal data range according to a type of the facility of a relevant solar power generation facility to automatically identify and set the protocol in which the data value closest to the normal data range is obtained as a protocol used by the solar power generation facility, so that the protocol corresponding to the solar power generation facility is automatically and accurately found and set without manually setting the protocol as in the related art, so that convenience and efficiency of protocol setting of solar power generation facilities are increased.

Description

Monitoring apparatus for solar power generation supporting automatic protocol setting and automatic protocol setting method thereof {Monitoring apparatus for solar power generation supporting automatic protocol setting and automatic protocol setting method of the same}

The present invention relates to a monitoring device for photovoltaic power generation supporting automatic protocol setting and an automatic protocol setting method thereof, and more particularly, communication with photovoltaic power generation facilities for photovoltaic power generation with different protocols for each manufacturer and facility type. It relates to a monitoring device for photovoltaic power generation that automatically identifies and sets a protocol for, and an automatic protocol setting method thereof.

Currently, various modules for converting renewable energy into electrical energy are being developed, and among them, a solar module for converting sunlight, which is a renewable energy, into electrical energy, and a solar power generation system using the same are in the spotlight.

The solar power generation system, which obtains power generation based on sunlight by configuring such a solar module in the form of an array, is easy to configure compared to other types of new and renewable energy, and thus the distribution is gradually expanding.

At this time, since most of the solar power generation system is configured by being exposed to the external environment, the risk of damage is high and monitoring is essential. It communicates with various facilities constituting the photovoltaic power generation system, such as connecting panels, inverters, relays (VCB, ACB), temperature and humidity devices, etc. Monitoring devices must be deployed to collect various data such as data (input power, output power, frequency, power factor and efficiency data), temperature data, humidity data, etc.

At this time, each facility can have different data types (ASCII, HEX) or different protocols with different data locations for each manufacturer and model, so that communication between all facilities and monitoring devices is compatible for data collection. It is required, and for this compatibility, the protocol of each facility must be checked and programmed in the monitoring device and set according to the device.

Currently, these protocol settings are manually set by the manager, checking the manufacturer, model name, and protocol name of the equipment connected to the monitoring device, and trying communication tests several times to set the protocol for each equipment. As the number of facilities increases, not only does the manager's work load increase, but this method has to be repeated every time an extension is made, so time, money, and effort are unnecessarily redundantly invested.

Korean Patent No. 10-1409774

The present invention automatically analyzes the protocol for the data received from the photovoltaic facility to determine the most similar protocol, and through this, supports to automatically set the protocol to the device monitoring the photovoltaic facility without administrator intervention. The purpose is to increase the convenience and efficiency of communication setting with power generation facilities.

In addition, the present invention supports to increase the accuracy of the protocol set for the photovoltaic power generation facility by automatically performing a precise communication protocol confirmation process using weather information in the protocol analysis process to set up communication with the photovoltaic power plant. The purpose is to increase the credibility of

A monitoring device for photovoltaic power generation that communicates with one or more photovoltaic power generation facilities constituting the photovoltaic power generation system according to an embodiment of the present invention and supports automatic protocol setting, includes data from the photovoltaic power generation facility that is a communication target with the monitoring device. A communication unit for receiving a packet, and an analysis unit for analyzing the data packet by one or more preset protocols to generate measurement information including attribute values for a plurality of preset attributes required for monitoring the photovoltaic system for each protocol; The data range is set for each of the plurality of properties and the preset information is compared with the same properties as the measurement information generated for each protocol, and protocols other than the protocol corresponding to the measurement information having an attribute value not included in the data range Each of the plurality of different division ranges obtained by dividing the data range for each of the one or more pieces of measurement information corresponding to the selected one or more candidate protocols is preset for each attribute. Based on each attribute, a final score is calculated by calculating a score according to the division range to which the attribute value of the measurement information belongs, and a candidate protocol corresponding to the measurement information having the highest final score of the solar power generation facility It may include a control unit for setting the communication protocol.

As an example related to the present invention, the attribute may be a data type required for monitoring the photovoltaic system, and the plurality of attributes may be different data types.

As an example related to the present invention, the control unit generates an information request signal using a protocol for each of the one or more protocols, transmits it to the photovoltaic power generation facility that is the communication target, and requests one or more information corresponding to the one or more protocols, respectively Among the signals, it may be characterized in that measurement information is generated through the analysis unit for only a protocol corresponding to an information request signal to which a response signal from the photovoltaic power generation facility is received.

As an example related to the present invention, the monitoring device may be configured in a remote terminal device (RTU) or a monitoring server.

As an example related to the present invention, the photovoltaic power generation facility may be any one of an inverter, a connection board connected to one or more photovoltaic modules, a VCB, an ACB, and a weather related device.

As an example related to the present invention, the control unit receives weather information including at least one of insolation and temperature from an external server through the communication unit, and the setting information includes a correlation between the weather information and the data range for each attribute. is preset, the control unit receives the weather information through the communication unit to calculate the final score, and includes in the setting information based on the correlation included in the setting information according to the received weather information A weight is given to each divided range, and a weight assigned to the divided range to which the attribute value of the measurement information belongs for each attribute is applied to an acquired score corresponding to the divided range to which the attribute value belongs, and a score is calculated for each attribute. It may be characterized in that the final score is calculated by adding the scores calculated by reflecting the weight.

As an example related to the present invention, the monitoring device further includes a storage unit storing protocol information for each of the one or more protocols, wherein the control unit communicates based on specific protocol information corresponding to a specific candidate protocol determined as the communication protocol. A protocol setting is performed for a target photovoltaic facility, and recommendation information for recommending a facility type of a photovoltaic facility as a communication target is generated and provided based on the facility type included in the specific protocol information. can

As an example related to the present invention, the control unit may be characterized in that it normalizes a data packet received from a photovoltaic power generation facility in which a communication protocol is set according to a preset normalization rule between the communication protocol and a preset standard protocol.

An automatic protocol setting method of a monitoring device communicating with one or more photovoltaic power generation facilities constituting a photovoltaic system according to an embodiment of the present invention comprises the steps of: receiving a data packet from a photovoltaic power plant that is a communication target with the monitoring device; , analyzing the data packet by one or more preset protocols to generate measurement information including attribute values for a plurality of preset attributes required for monitoring the photovoltaic system for each protocol, and data for each of the plurality of attributes By comparing the set information stored in advance with the range set between the same properties as the measurement information generated for each protocol, the remaining protocols except for the protocol corresponding to the measurement information having an attribute value not included in the data range are selected as candidate protocols, respectively. step, and a plurality of different division ranges obtained by dividing the data range for each of the one or more pieces of measurement information corresponding to the selected one or more candidate protocols, respectively, for each property based on the setting information preset for each property Calculate a score according to the division range to which the attribute value of the measurement information belongs, calculate a final score, and set a candidate protocol corresponding to the measurement information having the highest final score as the communication protocol of the solar power generation facility may include steps.

A monitoring device according to an embodiment of the present invention obtains a data value from a data packet by analyzing a data packet transmitted from a photovoltaic power generation facility that requires protocol setting for one or more protocols possessed by the monitoring device for each facility type, and through the analysis By comparing the obtained data value with the normal data range according to the type of the photovoltaic facility, the protocol in which the data value closest to the corresponding normal data range is obtained can be automatically identified and set as the protocol used by the photovoltaic facility. As such, it is possible to automatically find and set the protocol corresponding to the photovoltaic facility accurately without the need to set the protocol manually, thus increasing the convenience and efficiency of the protocol setting of the photovoltaic facility.

In addition, the monitoring device according to the present invention analyzes a data packet for a new photovoltaic power generation facility requiring protocol setting and compares the data value obtained through the analysis with the normal data range according to the facility type of the photovoltaic power plant, A protocol in which a new photovoltaic power generation facility uses a protocol in which a data value closest to the normal data range changed according to a change in weather is detected by varying the normal data range in relation to the weather by applying a weight to the data range according to the weather information can be automatically identified and set, and through this, it has the effect of significantly increasing the reliability and accuracy of the protocol setting by setting the protocol corresponding to the solar power generation facility more accurately by reflecting the current weather conditions.

1 is a configuration environment diagram of a monitoring device for photovoltaic power generation supporting automatic protocol setting according to an embodiment of the present invention.
2 is a detailed configuration diagram of a monitoring device for photovoltaic power generation supporting automatic protocol setting according to an embodiment of the present invention.
3 to 5 are diagrams illustrating an operation of a monitoring device for photovoltaic power generation supporting automatic protocol setting according to an embodiment of the present invention.
6 is an operation flowchart for an automatic protocol setting method of a monitoring device for photovoltaic power generation supporting automatic protocol setting according to an embodiment of the present invention.

Hereinafter, detailed embodiments of the present invention will be described with reference to the drawings.

1 is a configuration environment diagram of a monitoring device 100 for photovoltaic power generation supporting automatic protocol setting according to an embodiment of the present invention.

As shown, the monitoring device 100 may communicate with one or more photovoltaic power generation facilities constituting the photovoltaic power generation system through a communication network.

At this time, the monitoring device 100 is configured in at least one of a remote terminal unit (RTU) and a monitoring server that communicates with the one or more solar power generation facilities through a communication network, or the monitoring device 100 is an RTU or a monitoring server. It can be self-constructed.

Here, the RTU may communicate with the one or more solar power generation facilities through a serial communication method, for example, may be connected to the one or more solar power generation facilities through an RS-485 communication method to communicate with each other.

In addition, the RTU may receive data from each of one or more solar power generation facilities and transmit it to the monitoring server.

In addition, the monitoring server may be connected to the RTU through a communication network to receive a data packet transmitted by the one or more solar power generation facilities from the RTU, and communicate with the one or more solar power generation facilities without an RTU. You can also communicate directly through

In addition, the photovoltaic power generation system may be composed of one or more photovoltaic power generation facilities, and the photovoltaic power generation facility is composed of any one of a connection board, a vacuum circuit breaker (VCB), an air circuit breaker (ACB), and a weather related device. However, the present invention is not limited thereto, and any facility constituting the photovoltaic power generation system may be configured as the photovoltaic power generation facility.

In addition, a solar panel array composed of one or more solar modules (or solar panels, solar cells) that generate (produce) electric power using sunlight may be connected to one or more of the junction panels, The half may provide power provided from the solar panel array to the inverter connected to it.

In addition, the connection panel collects sensing information received from the sensor configured for each solar module and information related to the generated power provided to the connection panel to generate a data packet including a measurement value for each data type, and then the RTU or monitoring server In this case, the one or more sensors configured in the solar module may include various sensors such as a temperature sensor, a humidity sensor, and a solar radiation sensor.

In addition, the inverter may convert the generated power provided from the junction panel into commercial power and provide it to the grid, and the inverter measures the power provided from the junction panel and the power provided to the grid, input voltage, Measurement values for each data type such as output voltage, power, frequency, power factor, efficiency, etc. may be generated, and a data packet including the measurement value for each data type may be transmitted to the RTU or the monitoring server.

In addition, the relays such as the VCB and ACB may generate state information about their operating state, generate a data packet based on this, and transmit it to the RTU or the monitoring server.

In addition, the meteorological device includes one or more sensors, and weather information including measurement values for various data types such as temperature, humidity, insolation, wind direction, wind speed, rainfall, and whether or not the solar power generation system is configured in the region. It can be generated and transmitted as a data packet to the RTU or monitoring server. In this case, the sensor may include a temperature sensor, a humidity sensor, a solar radiation sensor, a wind direction sensor, a wind speed sensor, a rainfall sensor, and the like.

On the other hand, the monitoring device 100 is configured in the RTU or monitoring server as shown to receive a data packet including a measurement value for each data type from each of the one or more photovoltaic power generation facilities. In order to identify the measured value for each data type required for monitoring the power generation system, it can be normally identified only through the protocol used by the photovoltaic power plant that transmitted the data packet.

However, at least one of the one or more photovoltaic power generation facilities configured in the photovoltaic system may use different protocols instead of using a unified protocol, and accordingly, in the past, the manager directly transmits photovoltaic power generation to the monitoring device 100 . Since the protocol corresponding to the facility has to be manually set in the monitoring device 100, a problem occurred in that time, cost, and effort for the monitoring system construction of the photovoltaic power generation facility were unnecessarily consumed considerably.

Therefore, the monitoring device 100 according to the embodiment of the present invention automatically analyzes and identifies the protocol of the solar power generation facility and automatically sets it in the monitoring device 100, thereby reducing the time, cost and effort required for the existing protocol setting. It is possible to reduce and greatly improve the efficiency and convenience of building a monitoring system, which will be described in detail with reference to the drawings below.

First, FIG. 2 is a detailed configuration diagram of a monitoring device 100 according to an embodiment of the present invention. As shown, the monitoring device 100 includes a communication unit 110 , an analysis unit 120 , and a storage unit 130 . ) and the control unit 140 may be included.

At this time, at least one of the components constituting the monitoring device 100 may be included in another component, for example, the communication unit 110 , the analysis unit 120 , and the storage unit 130 are the It may be configured to be included in the control unit 140 .

In addition, some of the constituent units constituting the monitoring device 100 may be composed of the RTU in which the monitoring device 100 is configured or a constituent unit of the monitoring server.

In addition, the control unit 140 executes the overall control function of the monitoring device 100 using the program and data stored in the storage unit 130, and the control unit 140 controls the RAM, ROM, CPU, GPU, and bus. may include, and RAM, ROM, CPU, GPU, etc. may be connected to each other through a bus.

An operation example of the monitoring apparatus 100 according to an embodiment of the present invention will be described with reference to FIG. 3 based on the above configuration.

First, the communication unit 110 may communicate with the one or more solar power generation facilities through a communication network, and may receive a data packet from the one or more solar power generation facilities.

In this case, the communication network described in the present invention may include a wired/wireless communication network, and as an example of such a wireless communication network, a wireless LAN (WLAN), a DLNA (Digital Living Network Alliance), a Wibro (Wireless Broadband: Wibro), WiMAX (World Interoperability for Microwave Access: Wimax), GSM (Global System for Mobile communication), CDMA (Code Division Multi Access), CDMA2000 (Code Division Multi Access 2000), EV-DO (Enhanced Voice-Data Optimized or Enhanced Voice- Data Only), Wideband CDMA (WCDMA), High Speed Downlink Packet Access (HSDPA), High Speed Uplink Packet Access (HSUPA), IEEE 802.16, Long Term Evolution (LTE), Long Term Evolution-A (LTE-A) Advanced), Wireless Mobile Broadband Service (WMBS), 5G mobile communication service, Bluetooth, LoRa (Long Range), RFID (Radio Frequency Identification), Infrared Data Association (IrDA), Ultra Wideband (UWB), ZigBee, Near Field Communication (NFC), Ultra Sound Communication (USC), Visible Light Communication (VLC), Wi-Fi, Wi-Fi Direct may be included. In addition, wired communication networks include wired LAN (Local Area Network), wired WAN (Wide Area Network), Power Line Communication (PLC), USB communication, Ethernet, serial communication, optical/coaxial A cable may be included.

In addition, the analysis unit 120 analyzes the data packet for each of one or more preset protocols to generate measurement information including attribute values for a plurality of preset attributes required for monitoring the photovoltaic system for each protocol. have.

That is, the analysis unit 120 may analyze the data packet with a protocol possessed, and generate the measurement information for each protocol possessed.

At this time, one or more protocol information for each protocol may be stored in the storage unit 130 , and preferably, a plurality of protocol information for each protocol is stored in the storage unit 130 , and the storage unit 130 . The plurality of protocol information stored in may be different information from each other.

Also, the attribute is a data type required for monitoring the photovoltaic system, and the plurality of attributes may be different data types.

As an example of these properties, various data types such as power, voltage, current, frequency, power factor, temperature, humidity, insolation, operating state, etc., which are data types measured by solar power generation facilities, may be included, and the power, voltage, As for the current, power (input power, output power), voltage (input voltage, output voltage), current (input current, output current), etc. for each of the input and output may be included as data types.

Accordingly, the analysis unit 120 analyzes the data packet according to the protocol for each one or more protocols based on the one or more protocol information stored in the storage unit 130, and one or more measurement information corresponding to the one or more protocols, respectively. can create

For example, as shown in FIG. 4 , the analysis unit 120 analyzes the data packet according to a first protocol and extracts the data packet from a first data area corresponding to an input voltage set in the first protocol in the data packet. Extracting an attribute value (measured value) for an input voltage that is a first attribute among the plurality of attributes, and an output voltage that is a second attribute among the plurality of attributes from a second data area corresponding to an output voltage set in the first protocol By extracting an attribute value (measured value) for , first measurement information including the extracted attribute value for each attribute may be generated corresponding to the first protocol.

In addition, the analysis unit 120 analyzes the same data packet according to a second protocol, and in the data packet, the attribute value for the input voltage, which is the first attribute, from the third data area corresponding to the input voltage set in the second protocol. and extracting an attribute value for the output voltage, which is the second attribute, from a fourth data area corresponding to the output voltage set in the second protocol, and generating second measurement information including the extracted attribute value for each attribute. It can be generated corresponding to the second protocol.

That is, since different data areas between the first and second protocols may be set for the same property in the analysis unit 120, the attribute value for the same property from the data area set in each protocol for the same data packet can be extracted to generate measurement information for each protocol for one data packet to generate a plurality of measurement information.

On the other hand, the control unit 140 compares the set information stored in advance in which a data range is set for each of the plurality of properties with the same properties as the measurement information generated for each protocol, and is not included in the data range. Protocols other than the corresponding protocol may be selected as candidate protocols, respectively.

In this case, the setting information may be stored in advance in the storage unit 130 .

As an example of this, as shown in FIG. 4 , when the data range of the input voltage is set to 0 to 1000 V in the setting information, the controller 140 receives the input from the first measurement information generated corresponding to the first protocol. When the attribute value corresponding to the voltage-related attribute is 550V, the first protocol may be selected as a candidate protocol.

In addition, when the attribute value corresponding to the input voltage-related attribute in the second measurement information generated in response to the second protocol indicates a negative value as -10V, the control unit 140 excludes the second protocol from the candidate protocol. can

Also, as described above, the control unit 140 sets the acquired scores for each of a plurality of different division ranges obtained by dividing the data range for each of the one or more pieces of measurement information corresponding to the selected one or more candidate protocols in advance for each attribute. A final score is calculated by calculating a score according to the division range to which the attribute value of the measurement information belongs for each attribute based on the set setting information, and the final score is calculated as a candidate protocol corresponding to the measurement information having the highest final score. It can be set with the communication protocol of the solar power plant.

As an example of this, as shown in FIG. 4 , in the setting information, the data range set for each of the plurality of properties is divided into a plurality of different division ranges (or operation ranges) set in advance, so that a plurality of different division ranges are interrelated with each other. Different acquisition points may be preset for each division range.

Accordingly, when the first attribute value corresponding to the input voltage, which is the first attribute, in the first measurement information generated corresponding to the first protocol that is the candidate protocol is 550V, the controller 140 sets the first attribute value of the first attribute value. Among the first data ranges corresponding to one attribute, 10 points, which are obtained points set in the setting information, are calculated corresponding to 500V to 1000V, which is a division range to which the first attribute value belongs, and output that is the second attribute in the first measurement information When the second attribute value corresponding to the voltage is 450V, the second attribute value is set in the setting information corresponding to 400V to 500V, which is a division range to which the second attribute value belongs among the second data ranges corresponding to the second attribute of the second attribute value. Six points, which are obtained points, may be calculated, and obtained points calculated corresponding to each of the first attribute value and the second attribute value may be summed to calculate a final score of 16 points.

In addition, when the third attribute value corresponding to the input voltage, which is the first attribute, in the third measurement information generated corresponding to the third protocol, which is the candidate protocol, is 150V, the control unit 140 may control the third attribute value corresponding to the third attribute value. In the first data range of the first attribute, three points are calculated, which is an acquisition point set in the setting information, corresponding to 100V to 200V, which is a division range to which the third attribute value belongs, and a second attribute in the second measurement information When the fourth attribute value corresponding to the output voltage is 5V, the setting corresponds to 0 to 100V, which is a division range to which the fourth attribute value belongs among the second data ranges of the second attribute corresponding to the fourth attribute value. Two points, which are obtained points set in the information, may be calculated, and five points may be calculated by adding up the obtained points calculated corresponding to each of the third attribute value and the fourth attribute value.

As described above, when the final score is calculated for each candidate protocol for the specific data packet, the control unit 140 uses the first protocol, which is the candidate protocol with the highest final score, for the photovoltaic power generation facility that has transmitted the specific data packet. It may be determined to be a communication protocol, and the first protocol may be set for the solar power plant.

In this case, the control unit 140 may identify specific protocol information corresponding to the specific candidate protocol determined as the communication protocol in the storage unit 130 in correspondence to the specific candidate protocol, and based on the specific protocol information, Protocol setting may be performed for the photovoltaic power generation facility corresponding to the determined communication protocol.

For example, the control unit 140 extracts facility identification information for the photovoltaic facility from the header of the data packet, and provides matching information obtained by matching the facility identification information with specific protocol information determined by the communication protocol. generated and stored in the storage unit 130 .

Through this, the control unit 140 is a communication protocol corresponding to the photovoltaic facility based on the matching information for the data packet transmitted from the photovoltaic power generation facility for which protocol setting is completed and received through the communication unit 110 . By analyzing the data packet, it is possible to generate data related to photovoltaic power generation, which can be transmitted to the RTU or monitoring server.

In addition, each of the one or more protocol information stored in the storage unit 130 may include a facility type, and the controller 140 recommends information including the facility type included in the specific protocol information when the specific protocol information is identified. can be provided so that the administrator can identify the facility type of the photovoltaic power generation facility for which protocol setting has been completed by outputting it to an external output device after creating it.

That is, the control unit 140 may recommend or inform the manager of the facility type of the photovoltaic power generation facility, which is the communication target for which protocol setting is required, through the recommendation information.

In this case, the external output device may be configured in the monitoring device 100 or configured in the RTU or the monitoring server. Also, the control unit 140 may transmit the recommendation information to a preset device through the communication unit 110 and output it through the device.

That is, the monitoring device 100 according to an embodiment of the present invention analyzes a data packet transmitted from a photovoltaic power generation facility that requires protocol setting for each one or more protocols possessed by the monitoring device 100 for each facility type, and provides a data value from the data packet. is obtained, and the data value obtained through the analysis is compared with the normal data range according to the type of facility of the photovoltaic power generation facility, and the photovoltaic facility uses the protocol in which the data value closest to the normal data range is obtained As it can be automatically identified and set as a function, it is possible to accurately find and set the protocol corresponding to the photovoltaic facility automatically without the need to set the protocol manually as in the past, thereby increasing the convenience and efficiency of the protocol setting of the photovoltaic facility. .

Meanwhile, in the above-described configuration, the control unit 140 may generate an information request signal using a protocol for each of the one or more protocols and transmit it to the photovoltaic power generation facility that is the communication target.

In addition, the control unit 140 selects the analysis unit 120 for only the protocol corresponding to the information request signal received the response signal from the solar power generation facility among the one or more information request signals respectively corresponding to the one or more protocols. measurement information can be generated.

That is, the control unit 140 may generate an information request signal for each protocol using each of one or more protocols, and then transmit it to a specific photovoltaic power generation facility that requires protocol setting, and receives the information request signal for each protocol. Only one or more protocols in which a response signal is generated in response to a corresponding information request signal from a photovoltaic facility are provided to the analysis unit 120 as a protocol corresponding to the specific photovoltaic facility and analyzed by the analysis unit 120 (setting) Accordingly, protocols not related to the photovoltaic power generation facility can be excluded prior to analysis by the analysis unit 120 , thereby greatly increasing the analysis efficiency of the analysis unit 120 .

On the other hand, the monitoring device 100 according to the embodiment of the present invention, based on the meteorological information on the meteorological information on the meteorological environment of the region in which a specific photovoltaic power generation facility that requires communication protocol setting when calculating the final score is located Considering the measurement value change, it is possible to support more accurately detecting a communication protocol corresponding to a specific photovoltaic facility, which will be described in detail.

The control unit 140 may receive weather information including at least one of solar radiation and temperature from an external server through the communication unit 110 . In this case, the external server may be the above-described weather related device.

In addition, a correlation between the weather information and the data range for each attribute may be preset in the setting information.

For example, in the setting information, a correlation between a change in weather information including at least one of insolation and temperature and a change in weight given to each division range constituting a data range for each attribute may be set. That is, a correlation with respect to a weight change for each division range for each attribute according to a change in the weather information may be set in the setting information.

Accordingly, the control unit 140 may receive the weather information through the communication unit 110 in order to calculate the final score in the process of calculating the final score.

In addition, the control unit 140 assigns a weight to each division range included in the setting information based on the correlation included in the setting information according to the received weather information to calculate the final score, and by the attribute A weight reflection score is calculated by applying a weight given to the division range to which the attribute value of the measurement information belongs to a (set) acquisition score corresponding to the division range to which the attribute value belongs, and a weight is calculated for each attribute included in the measurement information. The final score may be calculated by adding up the reflected and calculated (obtained) scores (weighted reflection score).

For example, as shown in FIG. 5 , when the amount of insolation according to the weather information is high, the amount of power generation of the solar module increases, and accordingly, data received as the input voltage of the connection panel, which is one of a plurality of properties according to the setting information, is Since it is most likely to belong to the division range of 500 ~ 1000V, the control unit 140 assigns the highest weight to the corresponding division range 500 ~ 1000V according to the correlation included in the setting information, so that the measurement information related to the input voltage If the attribute value of is in the division range of 500~1000V, 20 points, the highest score, can be calculated (calculated).

In addition, when the amount of insolation according to the weather information is low, the amount of power generated by the solar module is reduced, and accordingly, the data received as the input voltage of the connection panel has the highest probability that it belongs to the division range of 1 to 100V, so the control unit 140 ) gives the highest weight to the division range 1 to 100V according to the correlation included in the setting information. It can be calculated (calculated).

As described above, the monitoring apparatus 100 according to the present invention analyzes a data packet for a new photovoltaic power generation facility requiring protocol setting, and displays the data value obtained through the analysis as normal according to the facility type of the photovoltaic power generation facility. In comparison with the data range, by varying the normal data range in relation to the weather through the application of a weight to the data range according to the weather information, a protocol in which the data value closest to the normal data range changed according to the weather change is detected. As a protocol used by photovoltaic power generation facilities, it can be automatically identified and set, and through this, the reliability and accuracy of the protocol setting can be greatly increased by setting the protocol corresponding to the photovoltaic power plant more accurately by reflecting the current weather conditions.

On the other hand, in addition to the above-described configuration, when the communication protocol for the specific photovoltaic power generation facility is determined, the monitoring device 100 sets the communication protocol for the specific photovoltaic power plant as described above, and from the data packet to the attribute value for each data type. However, when a plurality of different photovoltaic power generation facilities use different protocols, the load of the monitoring device 100 increases because the data packet must be interpreted according to the protocol corresponding to each photovoltaic power generation facility.

That is, since the various photovoltaic power generation facilities for which the communication protocol is set have different data packets depending on the location of the value defined by the manufacturer of the facility, when the data packet is received by the monitoring device 100 as it is, the data packet is parsed into the desired form. operation should be performed every time a packet is received.

To solve this, a standard protocol is set in the control unit 140 of the monitoring device 100, and rules for normalizing (converting) to a standard protocol for each of a plurality of different protocols may be set.

Accordingly, when a communication protocol is set for a specific photovoltaic facility, the control unit 140 converts a data packet received from the specific photovoltaic facility into a data packet corresponding to a standard protocol according to a rule corresponding to the specific photovoltaic facility. can be normalized.

Through this, the control unit 140 may generate a normalized data packet obtained by normalizing data packets received from a plurality of different photovoltaic power generation facilities according to a corresponding rule, and through this, based on the normalized data packet, the When performing data extraction through rapid parsing according to a standard protocol or when the monitoring device 100 is configured in an RTU that communicates with the monitoring server, a plurality of different normalized data corresponding to the plurality of different photovoltaic power generation facilities, respectively Packets may be interconnected and transmitted as a single packet to the monitoring server.

Through the above-described configuration, the monitoring device 100 according to an embodiment of the present invention normalizes data packets received for each photovoltaic power generation facility according to a standard protocol, thereby reducing the data processing load and increasing the data processing speed.

6 is a flowchart of an automatic protocol setting method of the monitoring apparatus 100 for photovoltaic power generation supporting automatic protocol setting according to an embodiment of the present invention.

As shown, the monitoring device 100 may receive a data packet from a photovoltaic power generation facility that is a communication target with the monitoring device 100 (S1).

In addition, the monitoring device 100 analyzes the data packet for each of a plurality of preset protocols to generate measurement information including attribute values for a plurality of preset attributes required for monitoring the photovoltaic system for each protocol. can be (S2).

In addition, the monitoring device 100 compares the set information stored in advance in which a data range is set for each of the plurality of properties with the same properties as the measurement information generated for each protocol (S3), and an attribute value not included in the data range The remaining protocols except for the protocol corresponding to the measurement information with , may be selected as candidate protocols, respectively (S4).

Next, the monitoring device 100 sets the acquisition score for each of a plurality of different division ranges obtained by dividing the data range for each of the one or more pieces of measurement information corresponding to the selected one or more candidate protocols in advance for each attribute. A final score is calculated by calculating a score according to the division range to which the attribute value of the measurement information belongs for each attribute based on the setting information (S5), and a candidate protocol corresponding to the measurement information having the highest final score is selected It can be set as a communication protocol of the solar power generation facility (S6).

The various devices and components described herein may be implemented by hardware circuitry (eg, CMOS-based logic circuitry), firmware, software, or a combination thereof. For example, it may be implemented using transistors, logic gates, and electronic circuits in the form of various electrical structures.

Those of ordinary skill in the art to which the present invention pertains may modify and modify the above-described contents without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments. The protection scope of the present invention should be construed by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

100: monitoring device 110: communication unit
120: analysis unit 130: storage unit
140: control unit

Claims (9)

In the monitoring device communicating with one or more solar power generation facilities constituting the solar power generation system,
a communication unit for receiving a data packet from a photovoltaic power generation facility that is a target of communication with the monitoring device;
an analysis unit that analyzes the data packet for each of one or more preset protocols and generates measurement information including attribute values for a plurality of preset attributes required for monitoring the photovoltaic system for each protocol; and
The data range is set for each of the plurality of properties and the preset information is compared with the same properties as the measurement information generated for each protocol, and protocols other than the protocol corresponding to the measurement information having an attribute value not included in the data range Each of the plurality of different division ranges obtained by dividing the data range for each of the one or more pieces of measurement information corresponding to the selected one or more candidate protocols is preset for each attribute. Based on each attribute, a final score is calculated by calculating a score according to the division range to which the attribute value of the measurement information belongs, and a candidate protocol corresponding to the measurement information having the highest final score of the solar power generation facility Control unit set by communication protocol
A monitoring device for photovoltaic power generation that supports automatic protocol setting, including
The method according to claim 1,
The property is a data type required for monitoring the photovoltaic system, and the plurality of properties are different data types.
The method according to claim 1,
The control unit generates an information request signal using a protocol for each of the one or more protocols and transmits it to the photovoltaic facility as the communication target, and from the photovoltaic facility among one or more information request signals corresponding to the one or more protocols, respectively A monitoring device for photovoltaic power generation supporting automatic protocol setting, characterized in that the measurement information is generated through the analysis unit for only a protocol corresponding to the information request signal received with the response signal.
The method according to claim 1,
The monitoring device is a monitoring device for photovoltaic power generation supporting automatic protocol setting, characterized in that configured in a remote terminal unit (RTU) or a monitoring server.
The method according to claim 1,
The solar power plant is
A monitoring device for photovoltaic power generation supporting automatic protocol setting, characterized in that it is any one of an inverter, a connection panel connected to one or more photovoltaic modules, VCB, ACB, and weather related devices.
The method according to claim 1,
The control unit receives weather information including at least one of insolation and temperature from an external server through the communication unit,
A correlation between the weather information and the data range for each attribute is preset in the setting information,
The control unit receives the weather information through the communication unit to calculate the final score, and weights each division range included in the setting information based on the correlation included in the setting information according to the received weather information. and calculating a score by applying a weight assigned to the division range to which the attribute value of the measurement information belongs for each attribute to an acquired score corresponding to the division range to which the attribute value belongs, and the weight is reflected for each attribute A monitoring device for photovoltaic power generation supporting automatic protocol setting, characterized in that the final score is calculated by summing the obtained scores.
The method according to claim 1,
Further comprising a storage unit storing the protocol information for each of the one or more protocols,
The control unit performs protocol setting for the photovoltaic power generation facility that is the communication target based on specific protocol information corresponding to the specific candidate protocol determined as the communication protocol, and the communication target based on the type of facility included in the specific protocol information A monitoring device for photovoltaic power generation supporting automatic protocol setting, characterized in that it generates and provides recommendation information for recommending a facility type of photovoltaic power generation facility.
The method according to claim 1,
The control unit for photovoltaic power generation supporting automatic protocol setting, characterized in that the data packet received from the photovoltaic facility in which the communication protocol is set is normalized according to a preset normalization rule between the communication protocol and the preset standard protocol monitoring device.
In the automatic protocol setting method of a monitoring device that communicates with one or more photovoltaic facilities constituting a photovoltaic system,
receiving a data packet from a photovoltaic power generation facility that is a target of communication with the monitoring device;
generating measurement information including attribute values for a plurality of preset attributes required for monitoring the photovoltaic system for each protocol by analyzing the data packet for each of one or more preset protocols;
The data range is set for each of the plurality of properties and the preset information is compared with the same properties as the measurement information generated for each protocol, and protocols other than the protocol corresponding to the measurement information having an attribute value not included in the data range selecting each candidate protocol; and
Acquisition scores for a plurality of different division ranges obtained by dividing the data range for each of the one or more pieces of measurement information corresponding to the selected one or more candidate protocols, respectively, are measured for each property based on the setting information preset for each property calculating a final score summed by calculating a score according to the division range to which the attribute value of information belongs, and setting a candidate protocol corresponding to the measurement information having the highest final score as the communication protocol of the solar power generation facility
Automatic protocol setting method of a monitoring device for photovoltaic power generation that supports automatic protocol setting comprising a.

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