JP2016025758A - Photovoltaic power generation system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a technique for achieving improvement of determination accuracy in a photovoltaic power generation system.SOLUTION: The photovoltaic power generation system comprises: a first detection section 6 for detecting an electrical output value of a power conditioner; a second detection section 7 for detecting an electrical output value of each solar cell unit; and abnormality determination means 9 for determining abnormality of the solar cell unit on the basis of the respective detection values detected by the first detection section and the second detection section. The abnormality determination means includes: a first output determination section for determining whether or not a first output value detected by the first detection section is within a stable output range determined within a predetermined range from rated power of the power conditioner; a second output determination section for determining whether or not a second output value detected by the second detection section is within a normal output range determined within a predetermined range from rated power of each solar cell unit; and an abnormality determination section for determining abnormality of the photovoltaic power generation system on the basis of a situation in which the first output value is within the stable output range and the second output value is not within the normal output range.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a photovoltaic power generation system.

  In a photovoltaic power generation system, electrical parameters (current, voltage, power, etc.) are measured for each unit constituting a solar cell array (meaning a solar cell string or sub-array, hereinafter referred to as a solar cell unit). For example, if a reduction in output of about 20% is observed for any of the electrical parameters to be compared, it is determined that there is an abnormality in the solar cell unit from which the electrical parameter is detected. A technique for issuing an alarm is disclosed (Patent Document 1).

  However, the technique disclosed in Patent Document 1 has a problem in that the abnormality determination cannot be performed accurately because the electrical parameters of the respective solar cell units to be compared are values that cause fluctuations as needed. It was.

Japanese Patent No. 2874156

  The object of the present invention is to solve the above-mentioned problems, measure the electrical parameters (current, voltage, power, etc.) of the solar cell strings and subarrays constituting the solar cell array, and based on these measured values, the solar cell strings and subarrays In a solar power generation system provided with a means for performing an abnormality determination, it is to provide a technique for improving the determination accuracy as compared with the conventional technique.

  The present invention made in order to solve the above problems is a photovoltaic power generation including a plurality of solar cell units and a power conditioner that collects DC power generated by these solar cell units and outputs it as AC power. In the system, the first detection unit that detects the output value of the power conditioner, the second detection unit that detects the output value of each of the solar cell units, and the first detection unit and the second detection unit Based on each detected value, it comprises an abnormality determining means for determining an abnormality of the solar cell unit, and the abnormality determining means is configured such that the first output value detected by the first detecting unit is a rated output of the power conditioner. And a second output value detected by the second detector is a rated output of each of the solar cell units. The first output determiner determines whether or not the stable output range is within a predetermined range. From A second output determination unit for determining whether or not the output is within a normal output range determined within a fixed range; the first output value is within the stable output range; and the second output value is a normal output range It has an abnormality determination part which determines abnormality of a photovoltaic power generation system based on what is not in.

  According to a second aspect of the present invention, in the photovoltaic power generation system according to the first aspect, the abnormality determining means is configured on the condition that the first output value is within the stable output range continuously for a predetermined time. The abnormality is determined.

    The invention according to claim 3 is the photovoltaic power generation system according to claim 1, wherein the abnormality determination means extracts a plurality of output values of each solar cell unit, calculates an average value, and sets the second output value as the second output value, The abnormality is determined based on the fact that the average value is not within the normal output range.

  In the present invention, in a solar power generation system including a plurality of solar cell units and a power conditioner that collects DC power generated by these solar cell units and outputs the power as AC power, the output of the power conditioner A first detection unit that detects a value; a second detection unit that detects an output value of each of the solar cell units; and the solar detection unit based on the detection values detected by the first detection unit and the second detection unit. An abnormality determining means for determining an abnormality of the battery unit is provided, and the abnormality determining means has a stable output in which the first output value detected by the first detector is set within a predetermined range from the rated output of the power conditioner. A normal output in which the first output determination unit for determining whether or not the range is within the range and the second output value detected by the second detection unit are determined within a predetermined range from the rated output of each of the solar cell units. range A second output determination unit that determines whether or not the first output value is within the stable output range and the second output value is not within the normal output range. Adopting a configuration with an abnormality determination unit that determines abnormalities in the power generation system, and performing abnormality determination based on values that do not fluctuate, such as the rated output of the power conditioner and the rated output of each solar cell unit. Compared with the conventional technique in which abnormality determination is performed by comparing electrical parameters that cause fluctuations, it is possible to achieve an improvement in determination accuracy.

  According to a second aspect of the present invention, the abnormality determining means is configured to determine the abnormality on the condition that the first output value is within the stable output range for a predetermined time. Alternatively, as in the invention described in claim 3, the abnormality determination means extracts a plurality of output values of each solar cell unit, calculates an average value, and sets it as a second output value. By adopting a configuration in which the abnormality is determined based on the fact that it is not within the normal output range, further improvement in determination accuracy can be realized.

1 is an overall configuration schematic diagram of a photovoltaic power generation system of the present invention. It is the structure schematic inside a connection box. It is a structure schematic of an abnormality determination means. It is a flowchart of Example 1,2. 2 is a graph for explaining Example 1; 6 is a graph for explaining Example 2;

  Preferred embodiments of the present invention are shown below.

As shown in FIG. 1, the photovoltaic power generation system of this embodiment is
A plurality of solar cell units 1;
A current collection box 2 for collecting direct current generated in each solar cell unit 1;
A plurality of junction boxes 3 for connecting each solar cell unit 1 and the current collector box 2;
A power conditioner 4 for converting the direct current generated in each solar cell unit 1 and collected in the current collector box 2 into alternating current;
The cubicle 5 transforms a high-voltage generated voltage into 100V or 200V.

  As the solar cell unit, a solar cell module, a solar cell string in which a plurality of solar cell modules are connected in series, or a solar cell array in which a plurality of solar cell strings are connected in parallel can be used. In this embodiment, a solar cell string (hereinafter referred to as string 1) is used as the solar cell unit 1, and two parallel solar cell strings are connected to one junction box 3.

The cubicle 5 includes a first detector 6 that measures an electrical output value (current or voltage) of the power conditioner 4.
In the power conditioner 4, control (maximum output tracking control) is performed to adjust the power so that each string 1 can obtain the maximum output. The first detection unit 6 may be provided in the power conditioner 4.
However, in the solar power generation system, when the rated output of the power conditioner 4 is the maximum output of the solar power generation system and the total output of the string 1 is larger than the rated output of the power conditioner 4, the power conditioner 4 Output exceeding the rated output cannot be performed, and the output of each string 1 when the power conditioner 4 is output at the rated output becomes the rated output of each string 1.
Here, the maximum output of each string 1 is a value obtained by “maximum output = maximum output operating voltage × maximum output operating current”, and the maximum output operating voltage means a voltage at which the maximum output of each string is obtained. The maximum output operating current means a current at which the maximum output of each string can be obtained.
The output voltage of each string can be adjusted by changing the ON duty of PWM control.

  As shown in FIG. 2, a second detector 7 for measuring the electrical output value (current or voltage) of each string and a measuring means 13 are installed inside each junction box 3 for a predetermined time (for example, Every 10 minutes), the electrical average output value (current or voltage) of each string is sampled. In addition, the 2nd detection part 7 may be provided in the current collection box.

  The inside of the current collection box 2 is connected to the first detection unit 6 and the second detection unit 7 through the communication line 8, and based on the detection values detected by the detection units 6 and 7, An abnormality determining means 9 for determining an abnormality of the battery unit is provided.

  As shown in FIG. 3, the abnormality determination unit 9 includes a first output determination unit 10, a second output determination unit 11, and an abnormality determination unit 12.

In the first output determination unit 10, the first output value detected by the first detection unit 6 is a stable output range determined within a predetermined range from the rated output of the power conditioner 4 (for example, the rated output of the power conditioner 4). 90% of the first output), and the second output determination unit 11 uses the second output value detected by the second detection unit 7 as the rated output (= power conditioner) of each string 1. Is determined to be within a normal output range (for example, 95% of the rated output of the string) determined from the predetermined output range.
In the present embodiment, the determination operation by the abnormality determination unit 12 is started on the condition that the first output value has been within the stable output range for a predetermined time, and the abnormality determination unit 12 Based on the fact that one output value is within the stable output range and the second output value is not within the normal output range, an abnormality of the photovoltaic power generation system is determined.

  Furthermore, in the abnormality determination unit 12, a plurality of output values of each solar cell unit are extracted to calculate an average value to be a second output value, and even when the average value is not within the normal output range, It is also possible to add a function for determining an abnormality in the photovoltaic system.

  In the present embodiment, the abnormality determination means 9 is provided inside the current collection box 2, but the installation location of the abnormality determination means 9 is not particularly limited. For example, the inside of the power conditioner 4 or the cubicle 5, or It can also be provided in a dedicated housing.

  Hereinafter, the present invention will be described in detail with reference to the first and second embodiments according to the flow of FIG. In addition, in FIGS. 4-6 used for description of an Example, each following term means the following technical matter, respectively.

<Terminology in FIGS. 4 to 6>
"PV maximum output" ... Maximum output of all strings "ST maximum output" ... Maximum output of each string "ST output" ... Output of each string "PCS rated output" ... Maximum output of the inverter “PCS output”: Output of the inverter “ST rated output”: Output of the string when the inverter is at maximum output
(If PCS rated output ≥ PV maximum output, ST maximum output)
“Stable output”: PCS output that exceeds a specified percentage of the PCS rated output (eg 90%)
“Stable section”: A section where stable output continues for a specified time (eg, 30 minutes).

As described above, in the photovoltaic power generation system, the rated output of the power conditioner 4 is the maximum output of the photovoltaic power generation system, and the total output of the string 1 is larger than the rated output of the power conditioner 4. The output exceeding the rated output of the inverter 4 cannot be performed.
In Example 1 below, the maximum output of all the strings (the total value of the maximum outputs of each string 1) is less than the rated output of the power conditioner, and the power generation amount of each string 1 is all in the power conditioner 4. This is an example of a case that can be converted into alternating current and output, and in Example 2 below, the maximum output of all the strings (the total value of the maximum output of each string 1) is larger than the rated output of the power conditioner. This is an example of a case where the maximum output of the photovoltaic power generation system is the rated output of the power conditioner 4.
In the case of Example 2, the conversion efficiency (= (output electric energy / incident solar energy × 100) (%)) can be increased by performing output at the rated output of the power conditioner 4, and By increasing the operating time at the rated output of the power conditioner 4, the amount of power sold can be increased. Therefore, it is desirable to output at the rated output of the power conditioner 4 as much as possible.

Example 1
In this embodiment, as shown in FIG. 5A, the output (PCS output) of the inverter is a stable output (eg, 90% or more of the rated PCS output), and this stable output is maintained for a predetermined time (example) : 30 minutes) The abnormality determination is started when the “stable section” is established.

  As shown in FIG. 5B, the output of each string (ST output) is sampled in units of strings by the second detector 7 provided inside each connection box 3 and accumulated as sampling data.

  Abnormality determination is based on these sampling data, the average value of the ST output output in the “stable section” is calculated as the second output value, and this average value and the rated output (ST rated output) of each string are used. It is done by comparison.

  In this embodiment, the normal output range of each string is set to 95% or more of the ST rated output, and when the average value of the ST output falls below the normal output range, abnormality determination is performed on the string.

  In this embodiment, the average value of the ST output output in the “stable section” is calculated, and the average value is compared with the rated output (ST rated output) of each string to perform abnormality determination. Abnormality determination can also be performed by comparing each ST output value sampled in the “stable section” with the ST rated output without obtaining an average value.

(Example 2)
In this embodiment, as shown in FIG. 6A, the maximum output of all strings (PV maximum output)> PCS rated output, but as described above, in the photovoltaic power generation system, the maximum output of the power conditioner The maximum output of the photovoltaic power generation system is equal to the PCS rated output.

  Also in this embodiment, the output of the inverter (PCS output) becomes a stable output (eg, 90% or more of the rated PCS output), and this stable output continues for a predetermined time (eg, 30 minutes). When the “section” is established, the abnormality determination is started.

  As shown in FIG. 6B, the output of each string (ST output) is sampled in units of strings by the second detector 7 provided inside each connection box 3 and accumulated as sampling data.

  The abnormality determination is performed by calculating an average value of the ST outputs output in the “stable section” from these sampling data and comparing the average value with the rated output (ST rated output) of each string.

  In the present embodiment, since ST maximum output> ST rated output, the output from any of the strings is reduced, and the ST rated output of other strings may be increased. For this reason, in this embodiment, the normal output range of each string is set to 95% or more and 105% or less of the ST rated output. If the average value of ST output falls below the normal output range in any string, an abnormality is determined for the string. On the other hand, in any string, the average value of ST output is If it exceeds the normal output range, it is determined that an abnormality has occurred in any of the other strings.

  In this embodiment, the average value of the ST output output in the “stable section” is calculated, and the average value is compared with the rated output (ST rated output) of each string to perform abnormality determination. Abnormality determination can also be performed by comparing each ST output value sampled in the “stable section” with the ST rated output without obtaining an average value.

1 Solar cell unit (string)
2 current collection box 3 connection box 4 power conditioner 5 cubicle 6 first detection unit 7 second detection unit 8 communication line 9 abnormality determination unit 10 first output determination unit 11 second output determination unit 12 abnormality determination unit 13 measurement unit

Claims (3)

A plurality of solar cell units;
A photovoltaic power generation system equipped with a power conditioner that collects DC power generated by these solar cell units and outputs it as AC power,
A first detector for detecting an output value of the inverter;
A second detector for detecting an output value of each of the solar cell units;
An abnormality determination means for determining an abnormality of the solar cell unit based on each detection value detected by the first detection unit and the second detection unit;
The abnormality determining means is
A first output determination unit that determines whether or not the first output value detected by the first detection unit is within a stable output range determined within a predetermined range from the rated output of the power conditioner;
A second output determination unit that determines whether the second output value detected by the second detection unit is within a normal output range determined within a predetermined range from the rated output of each of the solar cell units;
The first output value is within the stable output range;
And,
Based on the second output value not within the normal output range,
A solar power generation system comprising an abnormality determination unit that determines an abnormality of a solar power generation system. The abnormality determining means includes
On condition that the first output value was within the stable output range continuously for a predetermined time,
The solar power generation system according to claim 1, wherein the abnormality determination is started. The abnormality determining means includes
A plurality of output values of each solar cell unit are extracted and an average value is calculated as a second output value,
The photovoltaic power generation system according to claim 1, wherein the abnormality is determined based on an average value not being within the normal output range.