KR102360703B1 - A system for fault diagnosis and notice about solar farm - Google Patents

Abstract

The present invention diagnoses an abnormality or fault of a solar panel condition, inverter condition, peripheral generation facility condition, communication condition, power transmission condition of a large-scale solar power generation plant and quickly notifies a manager who manages the solar power generation plant through a SMS if the abnormality or fault occurs. The present invention includes a solar panel (100), an inverter unit (200), a fault diagnosis unit (300), and a management server (400).

Description

Solar power plant fault diagnosis and notification system {A system for fault diagnosis and notice about solar farm}

The present invention relates to a photovoltaic power plant failure diagnosis and notification system, and more particularly, it is an invention that promptly informs a manager of various abnormalities or failures occurring in a large-scale photovoltaic power plant.

That is, the present invention diagnoses abnormalities or failures related to the solar panel state, inverter state, peripheral power generation facility state, communication state, and power transmission state occurring in a large-scale solar power plant, and when an error or failure occurs, promptly via SMS It is an invention that informs the manager who manages the relevant solar power plant.

In modern society, as technology develops day by day, our lives are becoming more convenient and enriched, and in proportion to this, the amount of electricity we use is also increasing.

In particular, electricity produced in Korea is obtained through thermal power generation, hydro power generation, nuclear power generation, and power generation by new and renewable energy. The country's electricity is dependent on thermal power generation and nuclear power generation.

However, countries around the world have implemented environmental regulatory systems such as declaration of eco-friendly policies such as greenhouse gas reduction, and due to the oil shock and oil price rise in the past, and the Fukushima nuclear accident in Japan, the energy supply system that relies on fossil fuels and nuclear power As the necessity of new and renewable energy is being emphasized to escape from the current situation, interest in power generation using new and renewable energy, including solar power generation, is also increasing.

In particular, photovoltaic power generation has been actively carried out in recent years by receiving near-infinite energy from the sun naturally without consumption of fuel.

At this time, a large number of managers are required to efficiently manage and maintain a large-scale photovoltaic power plant, but since this causes excessive labor costs, the need to efficiently manage a large-scale photovoltaic power plant through the minimum number of managers is growing. .

In addition, the solar power plant managed by the minimum manager needs to quickly diagnose various abnormalities or failures that occur in the solar power plant, and when an abnormality or breakdown occurs, it is necessary to promptly notify the manager so that follow-up measures can be taken. .

Therefore, through the present invention, abnormalities or failures related to the solar panel status, inverter status, surrounding power generation facility status, communication status, and power transmission status generated in a large-scale solar power plant are diagnosed through the present invention. We would like to propose a technology that allows a small number of managers to efficiently manage and maintain a large-scale photovoltaic power plant by notifying the manager who manages the photovoltaic power plant so that they can take follow-up actions. The following are prior art related to this.

1. Republic of Korea Patent Publication No. 10-1832454 Method for analyzing the location of heat in a solar cell using a drone-based thermal infrared sensor 2. Republic of Korea Patent Publication No. 10-2018-0138354 Solar module diagnostic system using unmanned aerial vehicle 3. Republic of Korea Patent Publication No. 10-2019-0036589 Server for detecting whether a solar array is defective

An object of the present invention is to quickly diagnose abnormalities or failures related to a photovoltaic panel state, an inverter state, a peripheral power generation facility state, a communication state, and a power transmission state occurring in a large-scale photovoltaic power plant.

In addition, the present invention promptly informs the manager who manages the photovoltaic power plant through SMS in the event of an abnormality or failure regarding the photovoltaic panel status, inverter status, surrounding power generation facility status, communication status, and power transmission status, so that follow-up actions are taken aimed at making it possible.

In order to achieve the above object, the present invention solar power plant failure diagnosis and notification system,

A solar panel 100 for generating DC power using sunlight and providing it to the inverter unit 200;

DC power provided by the solar panel 100 is converted into AC power and provided to a transmission line, and DC wattage information of DC power provided by the solar panel 100 and AC wattage information of AC power provided through the transmission line and an inverter unit 200 for providing error code information of neighboring power generation facilities connected to the inverter to the fault diagnosis unit 300;

a failure diagnosis unit 300 for diagnosing a solar panel state, an inverter state, a peripheral power generation facility state, a communication state, and a power transmission state, and providing diagnosis result information to the management server 400;

It is characterized in that it includes a management server 400 that provides fault details according to the diagnosis result information provided by the fault diagnosis unit 300 to the manager.

The present invention diagnoses abnormalities or failures related to the solar panel status, inverter status, surrounding power generation facility status, communication status, and power transmission status occurring in large-scale solar power plants, By notifying the manager who manages the solar power plant so that they can take follow-up actions, it provides the effect that only a few managers can efficiently manage and maintain a large-scale photovoltaic power plant.

1 is a conceptual diagram of the present invention;
2 is a block diagram of the present invention;
3 is a detailed configuration diagram of the present invention;

An embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1, the present invention diagnoses abnormalities or failures related to the solar panel state, inverter state, peripheral power generation facility state, communication state, and power transmission state occurring in a large-scale photovoltaic power plant, and when an abnormality or failure occurs, It relates to an invention that allows a small number of managers to efficiently manage and maintain a large-scale solar power plant by notifying the manager who manages the photovoltaic power plant quickly through SMS so that a follow-up action can be taken, as shown in FIG. As such, it is configured to include a solar panel 100 , an inverter unit 200 , a failure diagnosis unit 300 , and a management server 400 .

Specifically, the present invention solar power plant failure diagnosis and notification system,

A solar panel 100 for generating DC power using sunlight and providing it to the inverter unit 200;

DC power provided by the solar panel 100 is converted into AC power and provided to a transmission line, and DC wattage information of DC power provided by the solar panel 100 and AC wattage information of AC power provided through the transmission line and an inverter unit 200 for providing error code information of neighboring power generation facilities connected to the inverter to the fault diagnosis unit 300;

a failure diagnosis unit 300 for diagnosing a solar panel state, an inverter state, a peripheral power generation facility state, a communication state, and a power transmission state, and providing diagnosis result information to the management server 400;

It is characterized in that it includes a management server 400 that provides fault details according to the diagnosis result information provided by the fault diagnosis unit 300 to the manager.

Referring to FIG. 3 , the solar panel 100 is configured to generate DC power using sunlight and provide it to the inverter unit 200 , and is also referred to as a solar power module.

In general, as shown in FIG. 1 , a photovoltaic array, which is a structure made up of a plurality of photovoltaic panels as shown in FIG. 3 , is collectively installed in a photovoltaic power plant.

The photovoltaic panel 100 installed in the photovoltaic power plant uses sunlight to produce direct current type power. The produced DC power is provided to the inverter unit 200 for conversion into AC power.

Referring to FIG. 3 , the inverter unit 200 converts the DC power provided by the solar panel 100 into AC power and provides it to the transmission line, and the amount of DC power of the DC power provided by the solar panel 100 . It is a configuration that provides information and information on the amount of AC power of AC power provided to the transmission line and error code information of neighboring power generation facilities connected to the inverter to the fault diagnosis unit 300 .

Specifically, the inverter unit 200,

An inverter 210 that converts DC power provided by the solar panel 100 into AC power and provides it to a power transmission line;

The solar panel 100 provides information on the amount of DC power of DC power provided to the inverter 210 and information on the amount of AC power of the AC power provided by the inverter 210 to the transmission line to the fault diagnosis unit 300 periodically, When an abnormality occurs in the neighboring power generation facilities connected to the inverter 210, the information providing unit 220 generates error code information corresponding to the generated abnormality and provides the generated error code information to the failure diagnosis unit 300.

The inverter 210 is configured to convert DC power into AC power, and the power produced by the solar panel 100 is DC power, and the power used by consumers is AC power. Therefore, it is necessary to convert the DC power produced by the solar panel 100 into AC power according to the customer, and the configuration for this is the inverter 210 .

In addition, various peripheral power generation facilities required for solar power generation are connected to the inverter 210 . For example, it may be a transformer, a reactor, a current unbalance detector, a voltage unbalance detector, a circuit breaker, an overcurrent detector, an overvoltage detector, and the like.

The information providing unit 220 periodically diagnoses the failure of DC power amount information of DC power provided by the solar panel 100 to the inverter 210 and AC power amount information of AC power provided by the inverter 210 to the transmission line. provided as part 300 .

For example, the amount of DC power provided by the solar panel 100 to the inverter 210 may be 200 kW, and the amount of AC power provided by the inverter 210 to the power transmission line may be 190 kW.

In addition, when an abnormality occurs in neighboring power generation facilities connected to the inverter 210 , the information providing unit 220 generates error code information corresponding to the generated abnormality and provides the generated error code information to the failure diagnosis unit 300 .

As described above, various peripheral power generation facilities (eg, transformer, reactor, current unbalance detector, voltage unbalance detector, circuit breaker, overcurrent detector, overvoltage detector, etc.) are connected to the inverter 210, and the information providing unit ( 220 , when an abnormality occurs in neighboring power generation facilities connected to the inverter 210 , generates error code information corresponding to the generated abnormality and provides the generated error code information to the failure diagnosis unit 300 .

For example, it may be an input overvoltage error code 01A3, an output overcurrent error code 02D4, and a grid current imbalance error code 02D5.

Referring to FIG. 3 , the failure diagnosis unit 300 diagnoses a solar panel state, an inverter state, a peripheral power generation facility state, a communication state, and a power transmission state, and provides diagnosis result information to the management server 400 . to be.

Specifically, the failure diagnosis unit 300, as shown in FIG. 2,

A first diagnosis unit 310 that diagnoses the state of the solar panel using the DC power amount information provided by the inverter unit 200, generates information about the diagnosis result of the solar panel according to the diagnosis, and provides the information to the management server 400; ,

A second diagnosis unit 320 that diagnoses the inverter status using the DC and AC power amount information provided by the inverter unit 200, generates inverter status diagnosis result information according to the diagnosis, and provides the information to the management server 400;

A third diagnostic unit 330 that diagnoses the status of the surrounding power generation facility using the error code information provided by the inverter unit 200, generates information about the condition of the surrounding power generation facility according to the diagnosis, and provides it to the management server 400; ,

A fourth diagnostic unit 340 that diagnoses a wired communication state with the inverter unit 200 and a wireless communication state with the management server 400, generates communication state diagnosis result information according to the diagnosis, and provides it to the management server 400; ,

and a fifth diagnostic unit 350 for diagnosing the operating state of the circuit breaker installed between the inverter 210 and the power transmission line, generating power transmission state diagnosis result information according to the diagnosis, and providing the information to the management server 400 do it with

The first diagnosis unit 310 diagnoses the state of the solar panel using the DC power amount information provided by the inverter unit 200 , and generates information about the diagnosis result of the solar panel state according to the diagnosis and provides it to the management server 400 . is a configuration that

Specifically, the first diagnosis unit 310 collects weather information from the outside when the state in which the amount of power according to the DC power amount information provided by the inverter unit 200 has decreased to less than or equal to the set value compared to the rated capacity continues for more than a set time, If the collected weather information is cloudy, snowy or rainy, it is judged as normal, and if the collected weather information is in a clear weather condition, it is judged that the solar panel is malfunctioning. It is characterized in that the solar panel state diagnosis result information is generated and provided to the management server 400 .

A solar panel produces DC power corresponding to its rated capacity in normal conditions (sunny weather), but produces DC power less than its rated capacity when the weather is cloudy or it is snowing or raining.

A photovoltaic panel is a power generation facility that uses sunlight to produce electricity. In sunny weather (when sunlight is sufficient for power generation), it produces DC power corresponding to its rated capacity, but when the weather is cloudy or snowy If it is raining or the sunlight is not enough for power generation, it will produce DC power less than its rated capacity.

Therefore, the determination of the failure of the solar panel should not be judged only by the amount of DC power produced by the solar panel, but the failure should be determined in connection with the weather.

There are cases in which the state in which the amount of power according to the DC power information provided by the inverter unit 200 has decreased to less than the set value compared to the rated capacity continues for more than a set time. In this case, the solar panel may be malfunctioning or the weather may be cloudy. have.

Therefore, when the state in which the amount of power due to the DC power information provided by the inverter unit 200 has decreased to less than or equal to the set value compared to the rated capacity continues for more than a set time, weather information is collected from the outside (eg, the Korea Meteorological Administration), and the collected weather information is If the weather conditions are cloudy, snowy or raining, it is determined as normal, and if the collected weather information is clear weather conditions, it is determined that the solar panel is malfunctioning.

For example, if it is assumed that the rated capacity of the solar panel is 200kW, the amount of electric power according to the DC wattage information provided by the inverter unit 200 is 150kW that is less than or equal to the set value (eg, 180kW, which is 90% of the rated capacity) compared to the rated capacity of 200kW. If the reduced state continues for more than a set time (eg: 1 hour), weather information is collected from the outside.

If the collected weather information is cloudy or snowy or rainy, it is normal for the solar panel to produce 150kW with a rated capacity of 200kW or less because it is normal due to the weather. It is necessary to produce 180~200kW of power within the set value compared to the rated capacity of 200kW, but it is judged as a failure because it is producing 150kW that is less than the set value (eg, 180kW, 90% of the rated capacity) compared to the rated capacity of 200kW.

The reason for determining whether the amount of power by the DC power amount information provided by the inverter unit 200 is less than or equal to the set value compared to the rated capacity of the solar panel is that the solar panel may produce power corresponding to its rated capacity even in sunny conditions However, it can also produce slightly less power than its rated capacity. The reason is that the amount of power generated by the solar panel is slightly different depending on the physical and chemical state of the solar cells constituting the solar panel.

In addition, the reason that a condition in which the amount of power according to the DC power amount information provided by the inverter unit 200 has decreased to less than or equal to the set value compared to the rated capacity continues for more than a set time as a prerequisite for determining the solar panel failure is due to temporary weather changes. This is because the power produced by the optical panel may be reduced. In other words, if there is a temporary cloudiness, the power produced by the solar panel may temporarily decrease, because it is wrong to judge this as a failure.

The second diagnosis unit 320 diagnoses the inverter status using the DC and AC power amount information provided by the inverter unit 200 , and generates inverter status diagnosis result information according to the diagnosis and provides the information to the management server 400 . to be.

Specifically, the second diagnosis unit 320 uses the DC and AC wattage information provided by the inverter unit 200 to determine that the inverter is faulty when the AC wattage is out of the conversion allowable range compared to the DC wattage, and the inverter is abnormal. It is characterized in that the inverter status diagnosis result information including the content notifying that this has occurred is generated and provided to the management server 400 .

Power loss occurs while the inverter 210 converts DC power into AC power, and the loss ratio is generally about 2 to 10%. For example, the inverter converts 100 kW of DC power into 98-90 kW of AC power.

If the loss rate exceeds 10% in the power conversion process, it is determined that an abnormality has occurred in the inverter.

The second diagnosis unit 320 determines whether the amount of AC power is out of a conversion allowable range compared to the amount of DC power by using the DC and AC power amount information provided by the inverter unit 200 .

For example, if the amount of DC power provided by the inverter unit 200 is 100 kW and the conversion allowable range is 98 to 90% compared to the amount of DC power, it is normal if the amount of DC power provided by the inverter unit 200 is in the range of 98 to 90 kW , and if it is less than 90 kW, it is determined that the inverter has an abnormal failure.

If it is determined that the inverter is faulty, the second diagnosis unit 320 generates inverter status diagnosis result information including information notifying that an abnormality has occurred in the inverter and provides the information to the management server 400 .

In addition, the second diagnostic unit 320 uses the DC and AC wattage information provided by the inverter unit 200 to determine if the AC wattage is within a conversion allowable range compared to the DC wattage, and the DC and AC wattage information provided by the inverter unit 200 is used. It is characterized in that the conversion efficiency from DC power to AC power is calculated using the amount of power information, and inverter status diagnosis result information including the calculated conversion efficiency information is generated and provided to the management server 400 .

The inverter 210 that converts DC power into AC power may deteriorate in function according to use. That is, even if it is not a malfunction, the power conversion efficiency within the conversion tolerance range is gradually reduced according to functional aging.

Therefore, if the conversion efficiency gradually decreases as the functional aging occurs in the inverter, the inverter must be replaced with a new one at a certain point in time to prevent further serious problems due to the functional aging of the inverter. To this end, the second diagnostic unit 320 ) is to provide conversion efficiency information of the inverter to the management server 400 .

For example, when the DC and AC wattage information provided by the inverter unit 200 is 100kW and 98kW, respectively, and the conversion tolerance range is 98 to 90%, the AC wattage 98kW is 98 to 90% of the DC wattage that is the conversion tolerance range Since it is a value within the range of 98 to 90 kW, the conversion efficiency of 98% is calculated while determining that it is normal, and inverter status diagnosis result information including 98% of the calculated conversion efficiency information is generated and provided to the management server 400 .

As another example, when the DC and AC wattage information provided by the inverter unit 200 is 100kW and 95kW, respectively, and the conversion tolerance range is 98 to 90%, the AC wattage 95kW is 98 to 90% of the DC wattage that is the conversion tolerance range Since it is a value within the range of 98 to 90 kW, the conversion efficiency of 95% is calculated while judging as normal, and inverter status diagnosis result information including 95% of the calculated conversion efficiency information is generated and provided to the management server 400 .

As another example, when the DC and AC wattage information provided by the inverter unit 200 is 100kW and 91kW, respectively, and the conversion tolerance range is 98 to 90%, the 91kW AC wattage is 98 to 90% of the DC wattage that is the conversion tolerance range Since it is a value within the range of 98 to 90 kW, the conversion efficiency of 91% is calculated while judging that it is normal, and inverter status diagnosis result information including 91% of the calculated conversion efficiency information is generated and provided to the management server 400 .

As described above, an administrator who understands the inverter conversion efficiency that gradually decreases with the aging of the inverter replaces the inverter with a new one before serious additional problems occur due to the functional aging of the inverter.

The third diagnostic unit 330 diagnoses the status of the surrounding power generation facility using the error code information provided by the inverter unit 200 , and generates information about the status of the surrounding power generation facility according to the diagnosis and provides it to the management server 400 . is a configuration that

Specifically, the third diagnosis unit 330 uses the error code information provided by the inverter unit 200 and the pre-stored error code index information to determine the contents of the fault corresponding to the error code, and the peripheral power generation including the identified fault contents. It is characterized in that the facility state diagnosis result information is generated and provided to the management server 400 .

As described above, various peripheral power generation facilities (eg, a transformer, a reactor, a current unbalance detector, a voltage unbalance detector, a circuit breaker, an overcurrent detector, an overvoltage detector, etc.) are connected to the inverter 210, the inverter 210 When an abnormality occurs in neighboring power generation facilities connected to the , error code information corresponding to the generated abnormality is provided to the failure diagnosis unit 300 through the information providing unit 220 of the inverter unit 200 .

The fault diagnosis unit 300 uses the error code provided by the information providing unit 220 of the inverter unit 200 and the pre-stored error code index information provided by the information providing unit 220 of the inverter unit 200. Find out the details of the fault corresponding to the error code.

For example, if the error code is 01A3, the error content of input overvoltage is identified, if the error code is 02D4, the error content of the output overcurrent is identified, and if the error code is 02D5, the failure content of the system current imbalance is identified. .

That is, the error code index information stored in advance by the fault diagnosis unit 300 is information that matches the error code with the contents of the fault, and the fault diagnosis unit 300 is provided by the information providing unit 220 of the inverter unit 200 . Using one error code and pre-stored error code index information, it is possible to identify the fault corresponding to the error code.

The fault diagnosis unit 300 that has identified the faults generates information about the status of the surrounding power generation equipment including the identified faults, and provides it to the management server 400 .

For example, the diagnosis result information of the peripheral power generation facility may include input overvoltage generation, output overcurrent generation, and grid current imbalance.

The fourth diagnosis unit 340 diagnoses the wired communication state with the inverter unit 200 and the wireless communication state with the management server 400 , and generates communication state diagnosis result information according to the diagnosis and provides it to the management server 400 . is a configuration that

Specifically, when the first communication check signal is transmitted to the inverter unit 200 through a wire, and there is no response signal to the transmitted first communication check signal, it is determined that an abnormality has occurred in the wired communication state with the inverter unit 200 . The first communication state diagnosis result information including the notification content is provided to the management server 400, a second communication check signal is transmitted to the management server 400 wirelessly, and a response to the transmitted second communication check signal If there is no signal, the second communication state diagnosis result information including the content notifying that an abnormality has occurred in the wireless communication state with the management server 400 is provided to the management server 400 .

The reason for diagnosing the wired communication state with the inverter unit 200 is that if the wired communication state with the inverter unit 200 is out of order, the fault diagnosis unit 300 receives various information (DC wattage information, AC) from the inverter unit 200 . Since the power amount information and error code information) is not provided, the wired communication state with the inverter unit 200 is diagnosed.

In addition, the reason for diagnosing the wireless communication state with the remote management server 400 is that if the wireless communication state with the management server 400 is out of order, various diagnostic result information (solar panel state) generated by the failure diagnosis unit 300 . Diagnosis result information, inverter state diagnosis result information, peripheral power generation facility state diagnosis result information, communication state diagnosis result information, power transmission state diagnosis result information, etc.) cannot be provided to the management server 400, so Diagnosing wired communication status.

The fifth diagnosis unit 350 is configured to diagnose the operating state of the circuit breaker installed between the inverter 210 and the power transmission line, generate power transmission state diagnosis result information according to the diagnosis, and provide it to the management server 400 .

Specifically, the fifth diagnostic unit 350 determines whether the circuit breaker installed between the inverter 210 and the power transmission line is operating, and if the circuit breaker is in an operating state, notifying that an abnormality has occurred in power transmission to the transmission line is included. It is characterized in that the power transmission state diagnosis result information is generated and provided to the management server 400 .

As shown in FIG. 3 , a circuit breaker is installed between the inverter 210 providing AC power to the transmission line and the transmission line.

If the AC power output from the inverter 210 is introduced into the transmission line in an overcurrent or overvoltage or grid current unbalance or grid voltage unbalance state, it causes a problem in the transmission system. Therefore, it is necessary to block the AC power output from the inverter 210 in the overcurrent or overvoltage or grid current unbalance or grid voltage unbalance state from entering the transmission line, and the configuration for this is a breaker.

When the circuit breaker operates, AC power output from the inverter 210 is not introduced into the transmission line, and this should be reported to the manager who manages the solar power plant.

To this end, the fifth diagnostic unit 350 determines whether the circuit breaker installed between the inverter 210 and the power transmission line is operating, and if the circuit breaker is in an operating state, notifies that an abnormality has occurred in power transmission to the transmission line (eg, AC). The power transmission state diagnosis result information including power is not provided through the transmission line) is generated and provided to the management server 400 .

The management server 400 is configured to provide fault details according to the diagnosis result information provided by the fault diagnosis unit 300 to the manager.

Specifically, the management server 400 transmits the failure details according to the diagnosis result information provided by the failure diagnosis unit 300 to the manager terminal as shown in FIG. 3 through a short message service (SMS). do.

That is, the management server 400 delivers the abnormality or breakdown that occurred in the solar power plant to the manager who manages the photovoltaic power plant through SMS (short message service), so that the manager can follow up on the abnormality or breakdown. is to make it

The failure contents according to the diagnosis result information transmitted by the management server 400 to the manager terminal are, for example, "solar panel failure", "inverter failure", "inverter conversion efficiency 96%", "output overcurrent occurrence", It may be "a grid current imbalance occurs", "communication with the inverter is impossible", "power cannot be provided to the transmission line due to the operation of a breaker", and the like.

Although the technical idea of the present invention has been described together with the accompanying drawings in the above, this is an exemplary description of a preferred embodiment of the present invention and does not limit the present invention, the scope of the present invention is not limited to the embodiment, It will be apparent that those skilled in the art also include modifications within the scope of the technical spirit of the present invention.

100: solar panel
200: inverter unit
300: fault diagnosis unit
400 : management server

Claims (10)

In the solar power plant failure diagnosis and notification system,

a solar panel 100 for generating DC power using sunlight and providing it to the inverter unit 200;
DC power provided by the solar panel 100 is converted into AC power and provided to a transmission line, and DC wattage information of DC power provided by the solar panel 100 and AC wattage information of AC power provided through the transmission line and an inverter unit 200 that provides error code information of neighboring power generation facilities connected to the inverter to the fault diagnosis unit 300;
a failure diagnosis unit 300 for diagnosing a solar panel state, an inverter state, a peripheral power generation facility state, a communication state, and a power transmission state, and providing diagnosis result information to the management server 400;
and a management server 400 that provides fault details according to the diagnosis result information provided by the fault diagnosis unit 300 to the manager,

The failure diagnosis unit 300,
A first diagnosis unit 310 that diagnoses the state of the solar panel using the DC power amount information provided by the inverter unit 200, generates information about the diagnosis result of the solar panel according to the diagnosis, and provides the information to the management server 400; ,
A second diagnostic unit 320 that diagnoses the inverter status using the DC and AC power amount information provided by the inverter unit 200, generates inverter status diagnosis result information according to the diagnosis, and provides the information to the management server 400;
A third diagnostic unit 330 that diagnoses the state of the surrounding power generation facility using the error code information provided by the inverter unit 200, generates information about the condition of the surrounding power generation facility according to the diagnosis, and provides it to the management server 400; ,
A fourth diagnostic unit 340 that diagnoses a wired communication state with the inverter unit 200 and a wireless communication state with the management server 400, generates communication state diagnosis result information according to the diagnosis, and provides it to the management server 400; ,
A fifth diagnostic unit 350 for diagnosing the operating state of the circuit breaker installed between the inverter 210 and the power transmission line, generating power transmission state diagnosis result information according to the diagnosis and providing it to the management server 400;

The first diagnostic unit 310,
When the state in which the amount of power due to the DC power amount information provided by the inverter unit 200 decreases to less than the set value compared to usual continues for more than a set time, weather information is collected from the outside, and the collected weather information is cloudy or snowy or rainy If the condition is normal, it is determined that the collected weather information is in a clear weather condition, the solar panel is judged to be faulty, and the solar panel condition diagnosis result information including the contents to notify that an abnormality has occurred in the solar panel is generated and the management server (400) Solar power plant failure diagnosis and notification system, characterized in that provided.
The method according to claim 1,
The inverter unit 200,
An inverter 210 that converts DC power provided by the solar panel 100 into AC power and provides it to a power transmission line;
The solar panel 100 provides information on the amount of DC power of DC power provided to the inverter 210 and information on the amount of AC power of the AC power provided by the inverter 210 to the transmission line to the fault diagnosis unit 300 periodically, Solar power comprising an information providing unit 220 that generates error code information corresponding to the generated abnormality and provides the error code information to the fault diagnosis unit 300 when an abnormality occurs in nearby power generation facilities connected to the inverter 210 . Power plant fault diagnosis and notification system.
delete delete The method according to claim 1,
The second diagnostic unit 320,
Using the DC and AC wattage information provided by the inverter unit 200, if the AC wattage is out of the conversion allowable range compared to the DC wattage, it is determined that the inverter is faulty and the inverter status diagnosis including the contents to notify that an abnormality has occurred in the inverter A solar power plant failure diagnosis and notification system, characterized in that the result information is generated and provided to the management server (400).
The method according to claim 1,
The second diagnostic unit 320,
Using the DC and AC wattage information provided by the inverter unit 200, when the AC wattage is within the conversion allowable range compared to the DC wattage, the inverter 200 uses the DC and AC wattage information provided from DC power to AC power A solar power plant failure diagnosis and notification system, characterized in that by calculating the conversion efficiency to , generating inverter state diagnosis result information including the calculated conversion efficiency information and providing the information to the management server (400).
The method according to claim 1,
The third diagnostic unit 330,
By using the error code information provided by the inverter unit 200 and the pre-stored error code index information, the error code corresponding to the error code is identified, and information about the status of the surrounding power generation equipment including the identified failure is generated and the management server (400) Solar power plant failure diagnosis and notification system, characterized in that provided.
The method according to claim 1,
The fourth diagnostic unit 340,
When the first communication check signal is transmitted to the inverter unit 200 through a wire, and there is no response signal to the transmitted first communication check signal, the content notifying that an abnormality has occurred in the wired communication state with the inverter unit 200 Provides the included first communication state diagnosis result information to the management server 400,
When the second communication check signal is transmitted to the management server 400 wirelessly, and there is no response signal to the transmitted second communication check signal, the content notifying that an abnormality has occurred in the wireless communication state with the management server 400 A solar power plant failure diagnosis and notification system, characterized in that the included second communication state diagnosis result information is provided to the management server 400 .
The method according to claim 1,
The fifth diagnostic unit 350,
It determines whether the circuit breaker installed between the inverter 210 and the transmission line is operating, and if the circuit breaker is in an operating state, generates power transmission state diagnosis result information that includes information indicating that an abnormality has occurred in power transmission to the transmission line and creates a management server (400) Solar power plant failure diagnosis and notification system, characterized in that provided.
The method according to claim 1,
The management server 400,
A solar power plant failure diagnosis and notification system, characterized in that the failure diagnosis unit 300 transmits the failure details according to the diagnosis result information to the manager terminal through a short message service (SMS).

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