JP2015225597A - Solar cell monitoring device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a solar cell monitoring device capable of finding a defect of a solar cell module at low costs.SOLUTION: A solar cell monitoring device includes: an electric quantity detection section; an abnormality detection section; and a nighttime determination section. The electric quantity detection section detects electric quantity in association with power generation of solar cells. The abnormality detection section detects abnormality on the basis of the electric quantity detected by the electric quantity detection section. The nighttime determination section determines whether or not time is nighttime. Further, the solar cell monitoring device lights indicator light when the abnormality is detected by the abnormality detection section and the time is determined to be the nighttime by the nighttime determination section.

Description

  Embodiments described herein relate generally to a solar cell monitoring apparatus.

In general, a solar cell monitoring device (system) includes a solar cell module, a connection box that collects current generated by the solar cell module, and outputs the collected current to an external device such as a substation, A central monitoring device for monitoring the state of the battery module is provided.
The solar cell module is configured by connecting a plurality of solar cells in series to form a cell string, and further electrically connecting the plurality of cell strings. And the electric current generated by each photovoltaic cell is collected by the junction box.

  Such a defect of the solar cell module is generally detected by the following method. That is, a CT (current transformer) sensor is attached to each cell string, and the detection result of this CT sensor is output to the central monitoring device. The central monitoring apparatus sequentially monitors the detection result of the CT sensor, and determines whether or not a problem has occurred in the solar cell module based on the detection result.

  More specifically, when the value of the current generated by the solar battery module is lower than a preset threshold value, it is determined that the solar battery cell constituting the corresponding cell string has failed or deteriorated. The central monitoring device always makes such a determination, and displays the determination result or the actual current value every time. Here, the central monitoring device is expensive, and wiring connection between the central monitoring device and the solar cell module is complicated. For this reason, the installation expense of a solar cell monitoring apparatus becomes bulky.

JP 2013-168535 A

  The problem to be solved by the present invention is to provide a solar cell monitoring device capable of discovering a malfunction of a solar cell module at a low cost.

  The solar cell monitoring apparatus according to the embodiment includes an electric quantity detection unit, an abnormality detection unit, and a nighttime determination unit. The electric quantity detection unit detects an electric quantity accompanying the power generation of the solar battery cell. The abnormality detection unit detects an abnormality based on the electric quantity detected by the electric quantity detection unit. The night determination unit determines whether it is night. When the abnormality is detected by the abnormality detection unit and the night determination unit determines that it is nighttime, the indicator lamp is turned on.

The schematic block diagram which shows the solar power generation device of embodiment. The side view which shows the solar cell monitoring apparatus of embodiment. The schematic block diagram which shows the solar cell monitoring apparatus of embodiment.

  Hereinafter, the solar cell monitoring apparatus of embodiment is demonstrated with reference to drawings.

FIG. 1 is a schematic configuration diagram of a solar power generation device to which the solar cell monitoring device of the present embodiment is applied, and FIG. 2 is a side view of the solar cell monitoring device.
As shown in FIG. 1, the photovoltaic power generation apparatus 1 electrically connects a solar cell module 2, a substation 3 that is an external device, and the solar cell module 2 and the substation 3. A connection box 4 for supplying the generated current to the substation 3 and an indicator lamp 6 provided in the connection box 4 and recognizable at night by a maintenance inspector are provided.

  The substation 3 includes, for example, an extra high-voltage substation and a sub substation. Then, a large-scale solar power generation device (mega solar) is constructed by connecting a plurality of solar cell modules 2 to a sub-substation once and then connecting a plurality of sub-substations to an extra high-voltage substation. Is also possible.

  As shown in FIG. 2, the solar cell module 2 is placed on the gantry 5. And the solar cell module 2 is inclined and arrange | positioned in a predetermined direction so that the surface can receive sunlight most efficiently. The connection box 4 is disposed on the top of the gantry 5 in the direction of gravity. More specifically, the junction box 4 is arranged at the highest position in the vicinity of the connection portion end of the gantry 5 with the solar cell module 2. An indicator lamp 6 is provided in the connection box 4 arranged in this way. The indicator lamp 6, the junction box 4 and the solar cell module 2 constitute a solar cell monitoring device 10.

FIG. 3 is a schematic configuration diagram of the solar cell monitoring apparatus.
As shown in the figure, the solar cell module 2 is formed by arranging a plurality of cell strings 12 configured by connecting a predetermined number of solar cells 11. Each cell string 12 is connected to the connection box 4 separately.
The connection box 4 has contacts 14 to which wirings 13 extending from the cell strings 12 are individually connected. The number of contacts 14 is set to correspond to the number of cell strings 12 (each wiring 13).

Each wiring 13 is combined into one connecting wiring 15 through the contact 14. The relay line 15 is connected to the substation 3 (see FIG. 1), and can supply the electric power generated by the solar cell module 2 to the substation 3.
Further, the connection box 4 has a storage battery 16, and this storage battery 16 is connected to the relay wiring 15. The surplus power generated by the solar cell module 2 can be stored in the storage battery 16.

Further, each wiring 13 in the connection box 4 is provided with a CT sensor 17. Each CT sensor 17 is for detecting the value (current value) of the current generated by the corresponding cell string 12.
Each CT sensor 17 is connected to an undercurrent relay (UCR) 18, and further, a first auxiliary relay 21 is connected to the undercurrent relay 18. A predetermined current threshold is set in the undercurrent relay 18, and an operation signal is output to the first auxiliary relay 21 when the current threshold is lowered.
Here, the current value is detected by the CT sensor 17, but it is only necessary that the amount of electricity can be detected by detecting the voltage value using the VT sensor. Further, when the current value generated by the cell string 12 using the undercurrent relay 18 falls below a predetermined threshold value, an operation signal is output to the first auxiliary relay 21. However, the undervoltage relay or overvoltage relay is output. A frequency relay or the like may be used as long as the cell string 12 can detect an abnormality such as a decrease in output, failure, or accident from the amount of electricity generated by power generation.

The first auxiliary relay 21 is configured to turn on the contact when the operation signal output from the undercurrent relay 18 is input.
The predetermined current threshold is set by a maintenance inspector. For example, the current threshold is set to about 80% of the rated current value generated by one cell string 12.

  The first auxiliary relay 21 is connected to the storage battery 16 via the second auxiliary relay 22. An optical sensor 23 provided in the connection box 4 is connected to the second auxiliary relay 22. The optical sensor 23 determines whether the present time is daytime when the solar cell module 2 can generate power with sunlight or nighttime when the solar cell module 2 cannot generate power with sunlight. In other words, the optical sensor 23 determines whether or not the current time is nighttime.

  That is, if the sun rises and the sunlight 23 is irradiated even a little, it is determined as daytime (not nighttime) in which the solar cell module 2 can generate power. On the other hand, when the sun sets and the light sensor 23 is no longer irradiated with sunlight, it is determined that the solar cell module 2 cannot generate power by using sunlight at night. When the sun goes down and the light sensor 23 is no longer irradiated with sunlight, an operation signal is output to the second auxiliary relay 22. The second auxiliary relay 22 is configured to turn on the contact when the operation signal output from the optical sensor 23 is input.

Here, the light sensor 23 is used to determine whether it is nighttime, but other methods may be used. For example, the night time may be recognized when an internal clock is provided and the preset night time is reached, or when the power generation output from the solar cell module 2 is equal to or less than a preset threshold value. When the power generation output from the solar cell module 2 is used, there is no addition of hardware for determining a new night, and the cost can be suppressed.
Furthermore, although it has been described above that the power generation output from the solar cell module 2 falls below a preset threshold, the night is recognized. However, when the time below the threshold is a predetermined time or more, the night is recognized. By doing so, the determination accuracy is further improved.

In addition, the indicator lamp 6 provided in the connection box 4 is connected to the first auxiliary relay 21. The indicator lamp 6 is lit by power from the storage battery 16.
The CT sensor 17, the undercurrent relay 18, the first auxiliary relay 21, and the indicator lamp 6 provided in the connection box 4 are provided for each cell string 12, and each first auxiliary relay 21 is a second one. It is connected to the storage battery 16 via the auxiliary relay 22. Since the CT sensor 17, the undercurrent relay 18, the first auxiliary relay 21 and the indicator lamp 6 provided in each cell string 12 have the same configuration, illustration is omitted in FIG. 3.

Next, based on FIG. 3, operation | movement of the solar cell monitoring apparatus 10 is demonstrated.
As shown in the figure, during the daytime, each solar cell 11 generates power by irradiating each solar cell 11 constituting the solar cell module 2 with sunlight. The current generated by this power generation is supplied to the connection box 4 for each cell string 12 and collected, and further supplied to the substation 3. The surplus current is stored in the storage battery 16 of the connection box 4.

  Here, for example, if one or more of the plurality of solar cells 11 fail or deteriorate, the power generation capacity of the cell string 12 constituted by the solar cells 11 also decreases. As a result, the detection result (current value) of the CT sensor 17 corresponding to the cell string 12 may be lower than the current threshold set in the undercurrent relay 18. In such a case, the undercurrent relay 18 corresponding to the cell string 12 that has fallen below the current threshold outputs an operation signal. Based on this operation signal, the contact of the first auxiliary relay 21 is turned on.

  On the other hand, the contact of the second auxiliary relay 22 remains off while sunlight is irradiated on the optical sensor 23 (daytime). For this reason, the electric power stored in the storage battery 16 is not supplied to the indicator lamp 6, and the indicator lamp 6 is in a state of not being lit.

  On the other hand, when the sun goes down and the light sensor 23 is no longer irradiated with sunlight (at night), the contact of the second auxiliary relay 22 is turned on. Then, the electric power stored in the storage battery 16 is supplied to the indicator lamp 6 via the second auxiliary relay 22 and the first auxiliary relay 21, and the indicator lamp 6 is turned on. Thereby, the maintenance inspector can recognize the cell string 12 in which the defect has occurred.

  The cell string 12 in which a defect is found can be returned to a predetermined state by performing maintenance. Here, for example, even when a defect occurs in some of the plurality of cell strings 12, there is almost no case where the defect needs to be dealt with immediately. It is. For this reason, even if a malfunction occurs in the cell string 12 in the daytime, it can be said that it is sufficient if an alarm (indicated by the indicator lamp 6) can be given to a maintenance inspector at night.

  As described above, the solar cell monitoring device 10 is configured not to sequentially alert the maintenance inspector of the malfunction of the solar cell module 2, but to alert the maintenance inspector only at night. Accordingly, the junction box 4 of the solar cell monitoring device 10 is configured by only the CT sensor 17, the undercurrent relay 18, the optical sensor 23, the first auxiliary relay 21 and the second auxiliary relay 22, and the indicator lamp 6. be able to. For this reason, the structure of the solar cell monitoring apparatus 10 can be simplified. In addition to this, when installing the solar cell monitoring device 10, complicated connection work is eliminated, so that the manufacturing cost of the solar cell monitoring device 10 can be reduced.

Moreover, since the CT sensor 17 is provided for each cell string 12, it is possible to easily recognize which cell string 12 in the entire solar cell module 2 has a problem. For this reason, maintenance workability | operativity can also be facilitated, simplifying the structure of the solar cell monitoring apparatus 10. FIG.
Furthermore, the connection box 4 is arranged at the uppermost part in the gravitational direction of the gantry 5 that supports the solar cell module 2. For this reason, the maintenance inspector can easily recognize the display of the indicator lamp 6.

  In the above-described embodiment, the case where the undercurrent relay 18 outputs a work signal to the first auxiliary relay 21 immediately when the current value detected by the CT sensor 17 falls below a preset current threshold value will be described. did. And the case where the contact of the 1st auxiliary relay 21 was turned on based on this work signal was explained. However, the present invention is not limited to this. When the average value of the current values continuously detected by the CT sensor 17 for a predetermined period (for example, three days) falls below the current threshold, the undercurrent relay 18 generates an operation signal. You may comprise so that it may output.

  With this configuration, even if the current value generated by the solar cell module 2 in the daytime such as rainy weather temporarily falls below the current threshold value, it is considered that the cell string 12 has failed. Can reduce the percentage of For this reason, it becomes possible to raise the precision of the display result by the indicator lamp 6. FIG.

  In the above-described embodiment, the case where the optical sensor 23 is used to determine whether the current time is daytime or nighttime has been described. However, the present invention is not limited to this, and any device that can determine whether the current time is daytime or nighttime may be used. For example, instead of the optical sensor 23, the connection box 4 may be provided with a clock function. And based on the output signal of this clock function, you may comprise so that the contact of the 2nd auxiliary relay 22 may turn on at night.

  Furthermore, in the above-described embodiment, the case where the current threshold set in the undercurrent relay 18 is set to, for example, 80% of the rated current value of the cell string 12 has been described. However, the present invention is not limited to this, and the current threshold value can be arbitrarily set in the solar cell module 2 according to the specification.

  Moreover, in the above-mentioned embodiment, the case where the connection box 4 was arrange | positioned in the gravity direction uppermost part of the mount frame 5 which supports the solar cell module 2 was demonstrated. However, the position is not limited to this, and any position where the maintenance inspector can recognize the indicator lamp 6 is acceptable. Further, the position of the connection box 4 may be determined in consideration of the workability of the maintenance inspector. Specifically, for example, the gantry 5 that supports the plurality of solar cell modules 2 is arranged at a predetermined distance, and a space between them is often a maintenance inspector's passage. By providing the junction box 4 provided with the indicator lamp 6 in the above, a more efficient maintenance inspection work can be performed.

  Furthermore, in the above-described embodiment, a case where the undercurrent relay 18 is used as an electronic component that outputs an operation signal to the first auxiliary relay 21 when the current value detected by the CT sensor 17 falls below the current threshold value. explained. However, the present invention is not limited to this, and an electronic component that can set a current threshold value in advance and can output an operation signal to the first auxiliary relay 21 when the current value detected by the CT sensor 17 falls below the current threshold value. I just need it.

  According to at least one embodiment described above, the solar cell module 2 is configured not to sequentially alert the maintenance inspector about the malfunction of the solar cell module 2, but to alert the maintenance inspector only at night. The configuration of the monitoring device 10 can be simplified. In addition to this, when installing the solar cell monitoring device 10, complicated connection work is eliminated, so that the manufacturing cost of the solar cell monitoring device 10 can be reduced.

In addition, since the CT sensor 17 is provided for each cell string 12, it is possible to recognize which cell string 12 in the entire solar cell module 2 is defective. For this reason, maintenance workability | operativity can also be facilitated, simplifying the structure of the solar cell monitoring apparatus 10. FIG.
Furthermore, the connection box 4 is arranged at the uppermost part in the gravitational direction of the gantry 5 that supports the solar cell module 2. For this reason, the maintenance inspector can easily recognize the display of the indicator lamp 6. Moreover, the visibility from a distant place improves further by providing the indicator lamp 6 in the upper end part of the solar cell module 2. FIG.

  Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention. These embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the spirit of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and are also included in the invention described in the claims and the equivalents thereof.

DESCRIPTION OF SYMBOLS 1 ... Solar power generation device, 2 ... Solar cell module, 3 ... Substation (external device), 4 ... Connection box, 5 ... Mount, 6 ... Indicator light, 10 ... Solar cell monitoring apparatus, 11 ... Solar cell, 12 ... Cell string, 17 ... CT sensor (electric quantity detection unit), 18 ... Undercurrent relay (abnormality detection unit), 21 ... First auxiliary relay, 22 ... Second auxiliary relay, 23 ... Light sensor (nighttime determination unit)

Claims (6)

An electric quantity detection unit for detecting an electric quantity accompanying the power generation of the solar battery cell;
An abnormality detection unit for detecting an abnormality based on the electric quantity detected by the electric quantity detection unit;
A night determination unit for determining whether it is night or not,
A solar cell monitoring device that turns on an indicator lamp when an abnormality is detected by the abnormality detection unit and the night determination unit determines that it is nighttime.   The solar cell monitoring apparatus according to claim 1, further comprising a power storage device that charges electric power generated from the solar battery cell and supplies the charged electric power to an indicator lamp.   3. The abnormality detection unit according to claim 1, wherein the abnormality detection unit detects an abnormality when an average value in a predetermined period in the value of the electric quantity detected by the electric quantity detection unit deviates from a predetermined threshold value. Solar cell monitoring device.   The solar cell monitoring device according to any one of claims 1 to 3, wherein the nighttime determination unit determines whether it is nighttime based on a value of the amount of electricity detected by the amount of electricity detection unit.   The solar cell monitoring device according to any one of claims 1 to 4, wherein the electric quantity detector detects an electric quantity generated from a cell string in which a plurality of the solar cells are connected in series.   The solar cell monitoring apparatus according to any one of claims 1 to 5, wherein the indicator lamp is provided at an uppermost portion in a gravity direction of a gantry supporting the solar battery cell.

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