KR101347845B1 - Monitoring system for solar power generater - Google Patents

Abstract

The present invention includes a solar cell unit in which a plurality of solar cell modules are arranged in rows and columns, and a monitoring unit capable of monitoring voltage and current output from the solar cell unit, wherein the solar cell unit includes a plurality of solar cell modules. It is divided into a plurality of solar cell lines divided into row units or column units, and each of the solar cell lines monitors an individual unit solar cell module connected to a measuring unit measuring voltage and current output from the solar cell module and transmitting the current to the monitoring unit. It's about the system.

Description

Individual unit solar cell module monitoring system {MONITORING SYSTEM FOR SOLAR POWER GENERATER}

The present invention relates to an individual unit solar cell module monitoring system capable of real-time monitoring of a plurality of solar cell modules.

A photovoltaic management system used generally includes a solar cell module in which a plurality of cell-type solar cells a1..1n, d1 ... dn are formed as one group (a ... d, e) and having a communication device (4) for each of the groups (a ... d, e) to control the group-type solar cells from the central server (5) remotely through the communication device (4). , Managed, monitored. Representative examples include Korean Patent Publication No. 10-2000-2864 and Korean Patent Publication No. 10-2008-11979.

However, even when controlling the solar cell module formed in the form of a plurality of cells as described above, if one of the plurality of solar cells failed, the administrator inspects all solar cells one by one to determine whether one solar cell module failure. There was a problem that only the failed solar cell must be identified.

In addition, in order to operate a communication device for transmitting the operation state of the solar cell module to a remote management server, a separate power supply must be provided. When the solar cell module absorbs solar energy, immediately before sunset or immediately after sunrise. Since the light intensity of the sun is weak, the amount of solar energy absorbed by the solar cell module immediately before sunset or immediately after sunrise is insufficient, and a malfunction of the solar cell module that does not properly absorb solar energy is transmitted to the management server. According to the failure signal of the solar cell module, the administrator had to re-examine the solar cell module.

In addition, although solar power generation is performed with efficiency significantly lower than the capacity of the solar cell module due to the amount of solar radiation, in general, the solar energy of the solar cell module composed of a plurality of solar cells has been manually managed by the administrator. Since the maintenance of the battery has to be checked and maintained, the inefficiency of manpower increases, and if the solar cell module cannot be maintained due to the management's negligence, the power generation efficiency of the solar cell module is lowered and the energy efficiency is reduced. .

The present invention has been made in order to solve the above problems, it is an object of the present invention to provide an individual unit solar cell module monitoring system that improves the efficiency of management by monitoring a plurality of solar cell modules in an individual unit.

In order to achieve the above object, the present invention includes a solar cell unit in which a plurality of solar cell modules are arranged in rows and columns, and a monitoring unit capable of monitoring voltage and current output from the solar cell unit, wherein the solar cell The unit is divided into a plurality of solar cell line by dividing a plurality of solar cell module by row unit or column unit, each of the solar cell line measuring unit for measuring the voltage and current output from the solar cell module and transmitting to the monitoring unit We propose a separate unit solar cell module monitoring system.

As described above, the present invention monitors the voltage / current output from the individual solar cell module and the voltage / current output from the solar cell line in which the plurality of solar cell modules form a group. When the same abnormality occurs, it can quickly identify and maintain the solar cell module or solar cell line that is a problem, thereby increasing the efficiency of management and improving the power generation efficiency.

1 is a configuration diagram showing a conventional solar cell module monitoring system,
2 is an overall configuration showing a solar cell module monitoring system according to the present invention,
Figure 3 is a detailed configuration showing a solar cell module monitoring system according to the present invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the detailed description of known functions and configurations incorporated herein will be omitted when it may unnecessarily obscure the subject matter of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to FIGS. 2 to 3.

2 is an overall configuration showing a solar cell module monitoring system according to the present invention, Figure 3 is a detailed configuration showing a solar cell module monitoring system according to the present invention.

As illustrated in FIGS. 2 to 3, a plurality of solar cell modules 110 for converting light energy incident from the sun into electrical energy are output from the solar cell unit 100 and the solar cell unit 100. It includes a measuring unit 200 for measuring the voltage and current to be received and the monitoring unit 300 to receive and output the measurement value from the measuring unit 200 to monitor the administrator.

The solar cell unit 100 is a solar cell module 110 for converting the light energy emitted by the sun into electrical energy by using the photovoltaic effect of a semiconductor such as silicon to form a cluster, a plurality of solar cell modules The 110 is formed in a planar shape in which a predetermined row and column are connected to and arranged between adjacent solar cell modules 110. Here, the solar cell unit 100 is divided into a plurality of solar cell line 120 by partitioning the solar cell module 110 having a predetermined row and column into each row or each column.

In this case, the solar cell line 120 is connected to the solar cell module 110 included in the same solar cell line 120 in series / parallel. Therefore, the solar cell line 120 collects power output from a plurality of solar cell modules 110 included in the same line, and the solar cell unit 100 is collected from each solar cell line 120. The power is collected again and transmitted to the outside.

On the other hand, each solar cell line 120 is connected to the measuring unit 200 for measuring the voltage / current output from the solar cell module 110. The measurement unit 200 measures the voltage and current output from the solar cell module 110 included in each solar cell line 120 and transmits it to a separate monitoring unit 300 provided outside. Here, the measurement unit 200 is a sampling measurement of the voltage / current output from the individual measurement module 202 and the entire solar cell line 120 to measure the sampling voltage / current output from each solar cell module 110 The line-by-line measurement module 204 is provided, the individual measurement module 202 is provided in a number corresponding to one to one solar cell module 110, the line-by-line measurement module 204 is each solar cell line It is formed in the number corresponding to (120).

That is, in one measuring unit 200, all voltages output from the plurality of individual measuring modules 202 and the solar cell line 120 corresponding to the number of solar cell modules 110 included in the solar cell line 120. And one line-by-line measurement module 204 for sampling measurement of current. Accordingly, at the same time as sampling and measuring the voltage / current output from each solar cell module 110, all the voltage / current output from the solar cell line 120 is also measured and transmitted to the monitoring unit 300.

In addition, the measurement unit 200 includes a multiplexer 206 connected to the individual measurement module 202 and the line-by-line measurement module 204 and a data processing device 210 for analyzing the sampled measurement values and processing them into digital data. Communication module 212 for transmitting the converted digital data to the monitoring unit 300 is further included. Here, the individual measurement module 202, the line-by-line measurement module 204, the multiplexer 206, the data processing device 210, and the communication module 212 are electrically connected in the order described to transmit and receive signals.

The multiplexer 206 includes a plurality of input terminals corresponding to the plurality of individual measurement modules 202 and the line-by-line measurement module 204 and one output terminal for transmitting the input signal to the data processing apparatus 210. Accordingly, when the measured values sampled by the plurality of individual measurement module 202 and the line-by-line measurement module 204 are input to the plurality of input terminals, they are sequentially transmitted to the data processing apparatus 210 through one output terminal.

In addition, the data processing apparatus 210 calculates and analyzes the measured values sampled by the individual measurement module 202 and the line-by-line measurement module 204 and processes them into various digital data. One of the most widely used MCUs.

In addition, the data processing apparatus 210 includes an A / D converter 208 to convert measured values having an analog format into digital values. If the data processing apparatus 210 without an A / D converter is used, As shown in FIG. 3, the measurement unit 200 preferably includes a separate A / D converter 208.

Here, the data that the data processing apparatus 210 calculates, analyzes, and derives the sampled measured value is derived from the measured value, that is, the value measured by the individual measurement module 202 and the value measured by the line-specific measurement module 204. As a result, data is derived. Looking at this in detail, the data derived by calculating and analyzing the values measured by the individual measurement module 202 is the voltage / current / power / impedance change output from one solar cell module 110, the daily cumulative power amount, the highest voltage / current , Minimum voltage / current, average voltage, standard deviation, maximum voltage / current slope, minimum voltage / current slope, minute variation of voltage / voltage output per hour, overvoltage / low voltage value and cumulative time, overcurrent / low current value and cumulative time, tolerance Data such as the upper and lower limit of standard deviation deviation are derived.

And, the data derived by calculating and analyzing the value measured by the line-by-line measurement module 204 is the voltage / current / power / impedance change, the daily cumulative power amount, the highest voltage / current, output from the entire solar cell line 120 There are minimum voltage / current, average voltage, standard deviation, maximum voltage / current slope, and minimum voltage / current slope. In addition, there are common recognition data for each solar cell module 110, power generation status for each solar cell module 110, and recognition data for each solar cell line 120. In addition, it is possible to derive various data necessary to operate the solar system according to the manager's needs.

 The data derived from the data processing device 210 as described above is transmitted to the monitoring unit 300 provided separately from the outside through the communication module 212, the manager through the monitoring unit 300 from the outside of the solar cell module 110 You can check the development status of).

Accordingly, real-time monitoring of the voltage / current output from individual solar cells and the voltage / current output from the solar cell line that constitutes a group of solar cells causes problems in case of abnormality such as output voltage / current drop and surge. You can quickly identify and take action on solar cells or solar cell lines.

Meanwhile, the measurement unit 200 further includes a power supply unit 214 for supplying driving power to the multiplexer 206, the A / D converter 208, the data processing device 210, and the communication module 212. The power supply unit 214 receives and charges the power generated by the power solar cell 130, which is provided separately, to charge the multiplexer 206, the A / D converter 208, the data processing device 210, and the communication module 212. To supply the driving power.

In addition, as described above, the plurality of solar cell modules 110 constituting the solar cell unit 100 are connected in series / parallel, where each solar cell module 110 is connected to the solar cell unit 100. It is further included a switch (not shown) for opening and closing the connection. In addition, the measurement unit 200 includes a control device (not shown) for detecting a problem occurring in the solar cell module 110 and controlling a switch (not shown) provided in the solar cell unit 100. That is to control, that is to open and close the connection between the solar cell module (110). At this time, the switch (not shown) is to open and close the connection between each solar cell line 120. Therefore, when an abnormal situation occurs, the connection between the solar cell module 110 or the solar cell line 120 and another solar cell module 110 which is a problem immediately is limited.

For example, if overcurrent occurs in 5 solar cells of 1-10 solar cells, the control device (not shown) immediately restricts the connection between solar cells 4 and 6 connected to solar cell 5. .

Accordingly, when a problem occurs in the solar cell unit 100, the control device (not shown) detects a problem situation and restricts the connection between the solar cell module 110 or the solar cell line 120 in which the problem occurs. By preventing the factor from spreading throughout the solar cell unit 100, all of the solar cell modules 110 except the solar cell module 110 in question can maintain a normal power generation state. As described above, the present invention has an effect of increasing management efficiency and improving power generation efficiency according to the operation of the solar cell module 110 as compared with the conventional solar operation system.

100: solar cell unit 110: solar cell module
120: solar cell line 200: measuring unit
202: individual measurement module 204: line-by-line measurement module
300: Monitoring section

Claims (6)

A plurality of solar cell module 110 includes a solar cell unit 100 arranged in rows and columns and a monitoring unit 300 for monitoring the voltage and current output from the solar cell unit 100, The solar cell unit 100 is divided into a plurality of solar cell modules 110 in a row unit or a column unit and divided into a plurality of solar cell lines 120, and each of the solar cell lines 120 includes a solar cell module 110. Measurement unit 200 for measuring the voltage and current output from the transmission to the monitoring unit 300 is connected,
The solar cell unit 100 further includes a switch for opening and closing the connection of the solar cell module 110 connected in series / parallel, the measurement unit 200 further includes a control device for controlling the operation of the switch. ,
Individual unit solar cell module monitoring system, characterized in that to limit the connection between the solar cell module 110 and the adjacent solar cell module 110 in which the abnormality occurs in the control device when the solar cell module 110 occurs.
The method according to claim 1,
The measurement unit 200 includes an individual measurement module 202 corresponding to each solar cell module 110 one by one to measure the voltage and current output from a plurality of solar cell module 110, respectively, the monitoring Individual unit solar cell module monitoring system, characterized in that for transmitting to the unit (300).
The method according to claim 1,
The measuring unit 200 further includes a line-specific measuring module 204 for measuring the voltage and current output from the entire solar cell line 120 and transmitting it to the monitoring unit 300. Modular monitoring system.
4. The method according to any one of claims 1 to 3,
The measurement unit 200 is a multiplexer 206 connected to the individual measurement module 202 and the line-by-line measurement module 204 and the data processing device 210 for analyzing the measured value into digital data and the converted digital data Individual unit solar cell module monitoring system, characterized in that it further comprises a communication module (212) for transmitting to the monitoring unit (300).
delete 5. The method of claim 4,
The measurement unit 200 further includes a power supply unit 214 for supplying driving power to the multiplexer 206, the data processing device 210, and the communication module 212.
The power supply unit 214 receives and charges the power generated by the power solar cell 130 separately provided to supply driving power of the multiplexer 206, the data processing device 210, and the communication module 212. Individual solar cell module monitoring system.

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