Source: https://patents.google.com/patent/JP6087200B2/en
Timestamp: 2020-06-06 05:49:42
Document Index: 27757277

Matched Legal Cases: ['art 24', 'art 24', 'art 21', 'art 21', 'art 24', 'art 24', 'art 22', 'art 24', 'art 24', 'art 22', 'art 23', 'art 24', 'art 221']

JP6087200B2 - Abnormality detection device for solar power generation system, abnormality detection method, and solar power generation system - Google Patents
Abnormality detection device for solar power generation system, abnormality detection method, and solar power generation system Download PDF
JP6087200B2
JP6087200B2 JP2013092989A JP2013092989A JP6087200B2 JP 6087200 B2 JP6087200 B2 JP 6087200B2 JP 2013092989 A JP2013092989 A JP 2013092989A JP 2013092989 A JP2013092989 A JP 2013092989A JP 6087200 B2 JP6087200 B2 JP 6087200B2
JP2013092989A
JP2014216501A (en
2013-04-25 Application filed by 京セラ株式会社 filed Critical 京セラ株式会社
2013-04-25 Priority to JP2013092989A priority Critical patent/JP6087200B2/en
2014-11-17 Publication of JP2014216501A publication Critical patent/JP2014216501A/en
2017-03-01 Publication of JP6087200B2 publication Critical patent/JP6087200B2/en
238000010248 power generation Methods 0.000 title claims description 91
230000002159 abnormal effects Effects 0.000 claims description 13
The present invention relates to an abnormality detection device, an abnormality detection method, and a solar power generation system for a solar power generation system.
In recent years, the demand for photovoltaic power generation systems using natural energy has been increasing. When large-scale systems such as a mega solar system exceeding 1 MW are increasing, when the system is stopped due to some trouble or the power generation amount is reduced, it is required to promptly detect the problem and prompt the countermeasure.
Conventionally, there are the following methods for detecting an abnormality in a photovoltaic power generation system. That is, as a first method, in a photovoltaic power generation system, the power generation of the system is performed from a power conditioner or a current / voltage / power generation measuring device connected to the system by converting DC power from a solar cell to AC power. There was a method for acquiring and displaying information such as quantity, operating status, or error occurrence.
In addition, as a second method, there is a method of making a determination based on information from a power conditioner or a measuring device, weather observation data such as a pyranometer / thermometer, time information, and the like. In the second method, the approximate power generation amount can be estimated based on the current solar radiation amount, temperature, etc., with respect to the installation conditions such as the rated power generation amount and direction / tilt angle of the solar cell used in the system. Therefore, when the actual power generation amount is smaller than the power generation amount estimated based on these pieces of information, it is determined that some abnormality has occurred in the solar cell (for example, Patent Document 1).
JP 2011-216811 A
Conventionally, in the first method described above, since the power generation amount of the solar power generation system varies depending on the weather, the amount of solar radiation, the season, or the time zone, it has not been possible to determine whether the power generation amount of the solar cell is appropriate. . In other words, the amount of power generation itself is the same except for information such as power conditioners or measuring devices that are clearly abnormal, such as equipment failures, or in cases where the power generation amount is zero despite the daytime. It was difficult to judge whether it was appropriate.
In the second method, it is possible to determine whether or not the power generation amount of the solar cell is appropriate, but it is necessary to acquire meteorological observation data. In general, there are not always meteorological stations, so a pyranometer is installed at the same time. However, a pyranometer is expensive and requires regular calibration and maintenance, so it is not always a simple abnormality detection method.
Accordingly, an object of the present invention made in view of such circumstances is an abnormality detection device and an abnormality detection method for a solar power generation system that can easily determine whether the power generation amount of the solar power generation system is appropriate in the solar power generation system. And providing a photovoltaic power generation system.
In order to solve the above problems, an abnormality detection device for a solar power generation system according to the present invention is an abnormality detection device for a solar power generation system including a plurality of solar cell strings, and the plurality of solar cells at a predetermined time. A current measuring unit for measuring output currents related to the strings, a system initial value that is a reference value of the output current of the photovoltaic power generation system, and a current measured value obtained from the current measuring unit and the system initial value; A control unit that detects an output abnormality of the solar cell string based on the current, and the control unit has a current in the current measurement values for a plurality of days from a reference date of the solar power generation system for each solar cell string. A maximum value is extracted at each predetermined time to set the system initial value, and for each solar cell string, at each predetermined time The ratio of the current measurement value to the first average value of all solar cell strings related to the current measurement value is the ratio of the current maximum value to the second average value of all solar cell strings related to the current maximum value. If the division result is equal to or less than a predetermined first threshold value, it determined that abnormal output of the solar cell string.
Moreover, the abnormality detection apparatus of the photovoltaic power generation system according to the present invention is:
The controller does not determine that the output of the solar cell string is abnormal when the ratio of the first average value to the second average value is equal to or less than a predetermined second threshold at each predetermined time.
The current measuring unit measures output currents related to the plurality of solar cell strings at the reference time of the photovoltaic power generation system,
The control unit has a predetermined ratio of the current measurement value to a first average value of all the solar cell strings related to the plurality of current measurement values at the reference time of the photovoltaic power generation system for each solar cell string. When the threshold value is 3 or less, it is determined that the solar cell string is initially defective.
An abnormality detection method for a solar power generation system according to the present invention is an abnormality detection method for a solar power generation system including a plurality of solar cell strings and an abnormality detection device that detects an output abnormality of the solar cell string. A step in which the current measuring unit of the abnormality detecting device measures output currents related to the plurality of solar cell strings at each predetermined time; and a control unit of the abnormality detecting device is configured to output current from the solar power generation system. setting a system default is the reference value, look including the steps of: detecting an output abnormality of the solar cell strings on the basis of the current measurement value acquired from the current measurement unit and said system default, The control unit has a maximum current value in the current measurement values for a plurality of days from a reference date of the photovoltaic power generation system for each solar cell string. The system initial value is extracted and extracted at each predetermined time, and the current with respect to the first average value of all the solar cell strings related to the current measurement value is set for each solar cell string at each predetermined time. When the result of dividing the ratio of the measured value by the ratio of the maximum current value to the second average value of all the solar cell strings related to the maximum current value is equal to or less than a predetermined first threshold value, Judged as abnormal output .
The solar power generation system according to the present invention is a solar power generation system including a plurality of solar cell strings and an abnormality detection device that detects an output abnormality of the plurality of solar cell strings, and the abnormality detection device includes: A current measuring unit that measures output currents related to the plurality of solar cell strings at predetermined times, and a system initial value that is a reference value of the output current of the photovoltaic power generation system, and from the current measuring unit A control unit that detects an output abnormality of the solar cell string based on the acquired current measurement value and the system initial value, and the control unit includes a reference date of the solar power generation system for each solar cell string Each of the measured current values for a plurality of days is extracted at each predetermined time and the system initial value is set. The ratio of the current measurement value to the first average value of all the solar cell strings related to the current measurement value at the predetermined time for the pond string is calculated as the second average of the all solar cell strings related to the current maximum value. If the result of division by the proportion of the current maximum value for the value is equal to or less than a predetermined first threshold value, you determined that abnormal output of the solar cell string.
According to the abnormality detection device, abnormality detection method, and solar power generation system of the present invention, it is possible to easily determine whether the power generation amount of the solar power generation system is appropriate.
It is a functional block diagram of a photovoltaic power generation system including an abnormality detection device according to an embodiment of the present invention. It is a figure which shows the measurement data table of FIG. It is a figure which shows the system initial value of FIG. It is a figure which shows the collation data of FIG. It is a flowchart figure which shows the update process of the measurement data table which concerns on one Embodiment of this invention. It is a flowchart figure which shows the abnormality detection process of the solar cell string after the system operation | movement which concerns on one Embodiment of this invention. It is a flowchart figure which shows the setting process of the system initial value which concerns on one Embodiment of this invention. It is a flowchart figure which shows the initial failure detection process of the solar cell string at the time of system operation which concerns on one Embodiment of this invention.
FIG. 1 is a functional block diagram of a photovoltaic power generation system including an abnormality detection device according to an embodiment of the present invention. The solar power generation system includes a plurality of solar cell strings 1, an abnormality detection device 2, a connection box 3, a power conditioner 4, a commercial power system 5, and a load device 6. FIG. 1 shows a state in which three solar cell strings (1-1, 1-2, 1-3) are provided for simplicity. In the following, each solar cell string 1 will be described assuming that the power generation amount is substantially the same under the same environment.
The solar cell string 1 is obtained by connecting a plurality of solar cell modules that generate power using sunlight in series to increase the output voltage, and outputs a direct current. The solar cell string 1 is connected to the abnormality detection device 2.
The abnormality detection device 2 is a power control device such as an EMS (Energy Management System) device, and detects an abnormality in the output current of the connected solar cell string 1. The abnormality detection device 2 includes a plurality of current measurement units 21, a storage unit 22, a notification unit 23, and a control unit 24.
The current measuring unit 21 is connected to each of the plurality of solar cell strings 1 and measures the output current generated by the corresponding solar cell string 1.
The storage unit 22 stores a measurement data table 211, a system initial value 222, and verification data 223.
Here, the measurement data table 221 will be described with reference to FIG. The measurement data table 221 is obtained by accumulating the measured current value of each solar cell string 1 and the average value of all the solar cell strings related to the measured current value over a plurality of days every predetermined time. Used to set the value 222. In the present embodiment, the measurement data table 221 includes a measurement date 2211, a time 2212, a current measurement value 2213, and a first average value 2214.
The measurement date 2211 indicates the date when the output current of the solar cell string 1 was measured with the predetermined reference date as the first day when the solar power generation system was operated. In the following description, the reference date (or reference time) will be described as being the operating day (or operating time) of the photovoltaic power generation system. it can. In FIG. 2, “the first day”, “second day”, and “d day” are shown as measurement days 2211 for the sake of simplicity.
Time 2212 indicates a predetermined time when the current measurement unit 21 measures the output current. Here, the predetermined time is a time when a plurality of arbitrary times are selected from the time zone during the day of sunrise. For example, in this embodiment, measurement is performed every hour from 8 o'clock to 17 o'clock. In FIG. 2, for the sake of simplicity, “8:00 (8:00)”, “9:00 (9:00)”, and “17:00 (17:00)” are shown.
The measured current value 2213 indicates the measured current value of each solar cell string 1 associated with the measurement date 2211 and the time 2212. The value of the current measurement value 2213 in FIG. 2 is indicated by “S [string number] − [measurement date] − [time]”.
The first average value 2214 indicates the average value of all the solar cell strings 1 according to the current measurement value 2213 associated with the measurement date 2211 and the time 2212. The value of the first average value 2214 in FIG. 2 is indicated by “Ave− [measurement date] − [time]”.
Next, the system initial value 222 will be described with reference to FIG. The system initial value 222 indicates a reference value of the output current of each solar cell string 1 at each predetermined time in the solar power generation system, and the controller 24 reduces the amount of power generation over time of the solar power generation system. Used to detect. In the present embodiment, the system initial value 222 includes a time 2221, a current maximum value 2222, and a second average value 2223.
A time 2221 indicates a time corresponding to the time 2212 of the measurement data table 221.
The maximum current value 2222 is associated with the time 2221 and indicates the maximum value of the current measurement values for a plurality of days from the operating day of the solar power generation system for each solar cell string 1. In the present embodiment, the maximum current value 2222 is obtained by extracting the maximum value in the current measurement value 2213 from the first day to the d-th day of the measurement data table 221 for each solar cell string 1.
As already described, the power generation amount of the solar power generation system varies depending on the weather, the amount of solar radiation, the season, or the time zone. The current measurement values for a plurality of days may include a case where the power generation amount is reduced due to environmental conditions such as bad weather. However, in determining the system initial value 222, which is the reference value of the output current of the photovoltaic power generation system, the amount of power generation that has decreased due to such environmental conditions should not be considered. Further, the power generation amount of the solar power generation system may vary depending on the installation conditions (for example, location conditions, surrounding environment, etc.). For this reason, the system initial value 222 which is the reference value of the output current of the photovoltaic power generation system cannot be immediately determined based on, for example, the rating of the solar cell module. Therefore, by extracting the maximum value of the current measurement values 2213 for a plurality of days for each solar cell string 1, the current measurement value having the least environmental influence over a plurality of days, in other words, the most ideal for photovoltaic power generation over a plurality of days. A measured current value in a typical environment is defined as a system initial value 222. The value of the current maximum value 2222 in FIG. 3 is indicated by “S [string number] −0− [time]”.
The second average value 2223 indicates the average value of all the solar cell strings 1 according to the maximum current value 2222 associated with the time 2221.
Next, the collation data 223 will be described with reference to FIG. The collation data 223 is stored in advance in the storage unit 22 and is used by the control unit 24 to determine an output abnormality of the solar cell string 1. In the present embodiment, the collation data 223 includes a time zone 2231, a first threshold 2232, a second threshold 2233, and a third threshold 2234. The values of these pieces of information included in the verification data 223 may be configured so that the operator can change after the operation of the solar power generation system.
The time zone 2231 indicates a plurality of time zones obtained by arbitrarily dividing the time zone in which the day is out of the day. In this embodiment, it is divided into five time zones every two hours.
The first threshold 2232 is a value between 0 and 1 associated with the time zone 2231, and is used by the control unit 24 to detect an abnormality in the output current of the solar cell string 1 due to a change over time after the system is operated. It is done. Preferably, the first threshold 2232 is set to a higher value for a time zone in which the amount of solar radiation is considered to be large. For example, in the present embodiment, the first threshold 2232 is “0. 0” in a time zone “11: 00 to less than 13:00 (less than 13:00 and less than 13:00)”, which is considered to have the largest amount of solar radiation in one day. “9” is set to a high value, and the first time in the morning and evening hours “less than 9:00 (less than 9:00)” and “15:00 (after 15:00)”, which are considered to have less solar radiation. The threshold value 2232 of “0.7” is set to a low value.
The second threshold 2233 is a value between 0 and 1 and is used by the control unit 24 to determine weather irregularities when measuring the output current of the solar cell string 1. In the present embodiment, the second threshold 2233 is set to a constant value (“0.3”) regardless of the time zone 2231, but a different value may be set for each time zone 2231.
The third threshold 2234 is a value between 0 and 1 associated with the time zone 2231, and is used by the control unit 24 to detect an abnormality in the output current of the solar cell string 1 due to an initial failure or the like during system operation. Used. Preferably, the third threshold 2234 is set to a higher value for a time zone in which the amount of solar radiation is considered to be large. For example, in the present embodiment, the third threshold 2234 is set to a high value of “0.7” in the time zone “11: 00 to less than 13:00” that is considered to have the largest amount of solar radiation in the day. The third threshold 2234 is set to a low value of “0.5” in the time zone “less than ˜9: 00” and “15:00” in the morning and evening when the amount of solar radiation is considered to be small.
Returning to the description of FIG. When the control unit 24 determines whether or not the output current of the solar cell string 1 is abnormal, the notification unit 23 notifies the operator of the determination result. The notification unit 23 may be a display panel such as a speaker or a liquid crystal display, for example. You may substitute by alert | reporting, such as blinking by light emitting elements, such as LED.
The control unit 24 controls the operation of the entire abnormality detection device 2. Moreover, the control part 24 can acquire the present time, and measures the elapsed time from the time of a solar power generation system operation.
Further, the control unit 24 updates the content of the measurement data table 221 and stores it in the storage unit 22. Specifically, the control part 24 acquires the current measurement value corresponding to each solar cell string 1 from the current measurement part 21 from the current measurement part 21 at every predetermined time after the operation of the photovoltaic power generation system. Subsequently, the control unit 24 calculates a first average value that is an average value of all the solar cell strings 1 according to the acquired plurality of current measurement values. Subsequently, the control unit 24 associates the acquired plurality of current measurement values and the calculated first average value with the measurement date 2211 and the time 2212, and measures the measurement data as the current measurement value 2213 and the first average value 2214, respectively. The data is accumulated in the table 221 and stored in the storage unit 22.
Further, the control unit 24 sets the system initial value 222 based on the measurement data table 221. Specifically, the control unit 24 sets the maximum current measurement value 2213 for a plurality of days (for example, d days) from the first day included in the measurement data table 221 at each predetermined time for each solar cell string 1. Each current maximum value is extracted. Then, the control part 24 calculates the 2nd average value which is an average value of all the solar cell strings 1 concerning the extracted electric current maximum value for every predetermined time. Then, the control unit 24 sets the system initial value 222 with the extracted current maximum value and the second average value as the current maximum value 2222 and the second average value 2223, respectively, for each solar cell string 1 at a predetermined time. And stored in the storage unit 22.
In addition, the control unit 24 detects an abnormality in the output current of the solar cell string 1 due to a change with time after the system is operated by collating with the collation data 223 based on the measurement data table 221 and the system initial value 222. Specifically, the control unit 24 measures the current measurement value 2213 (that is, “Sm−pt”) related to the latest measurement date 2211 (p day) and the latest time 2212 (time t) in the measurement data table 221. ) And the first average 2214 (ie, “Ave-pt”). Subsequently, as shown in Expression (1), the control unit 24 for each solar cell string 1, the ratio of the current measurement position 2213 to the extracted first average value 2214 (that is, “Sm−pt” / “ Ave-pt ”) divided by the ratio of the maximum current value 2222 to the second average value 2223 at time t (ie,“ Sm-0-t ”/“ Ave-0-t ”). A is calculated.
Subsequently, the control unit 24 collates the calculation result A of Expression (1) with the collation data 223, and determines whether or not the calculation result A is equal to or less than the first threshold 2232 corresponding to the time zone 2231 to which the time t belongs. to decide. Then, when the calculation result A is equal to or less than the first threshold 2232, the control unit 24 determines that the output current of the corresponding solar cell string 1 is abnormal. On the other hand, when the calculation result A is larger than the first threshold value 2232, the control unit 24 determines that the output current of the corresponding solar cell string 1 is normal.
Preferably, after extracting the current measurement value 2213 and the first average value 2214, the control unit 24 extracts the system initial value 222 with respect to the second average value 2223 at time t as shown in Expression (2). The value of B, which is the ratio of the first average value 2214, is calculated.
Subsequently, the control unit 24 collates the calculation result B of Expression (2) with the collation data 223 and determines whether or not the calculation result B is equal to or less than the second threshold 2233. When the calculation result B is equal to or less than the second threshold value 2233, the control unit 24 determines that the weather is unsatisfactory because the power generation amount is small as a whole system, and does not make a determination regarding the output abnormality of the solar cell string 1. On the other hand, when the calculation result B is larger than the second threshold value 2233, the control unit 24 continues the output abnormality detection operation of the solar cell string 1. By doing so, it is possible to prevent erroneous determination that the output current of the solar cell string 1 is abnormal in spite of the fact that the power generation amount of the entire system is reduced due to bad weather or the like.
Moreover, the control part 24 detects the initial failure of the solar cell string 1 at the time of system operation (time u). Specifically, the control unit 24 acquires current measurement values corresponding to the solar cell strings 1 from the plurality of current measurement units 21 at time u. Subsequently, the control unit 24 calculates a first average value related to the plurality of acquired current measurement values. Subsequently, as shown in Expression (3), the control unit 24 calculates a value of C that is a ratio of the current measurement value to the first average value.
Subsequently, the control unit 24 collates the calculation result C of Expression (3) with the collation data 223, and determines whether or not the calculation result C is equal to or less than the third threshold 2234 corresponding to the time zone 2231 to which the time u belongs. to decide. For example, when the time u is 9:30, the time zone 2231 to which the time belongs is “9: 00 to less than 11:00”, and the corresponding third threshold 2234 is “0.6”. When the calculation result C is equal to or less than the third threshold value 2234, the control unit 24 determines that the corresponding solar cell string 1 has an initial failure.
In the connection box 3, a plurality of solar cell strings 1 are connected in parallel via the abnormality detection device 2, and a DC current is boosted and input to the power conditioner 4.
The power conditioner 4 converts the DC power input from the connection box 3 into AC power. The power conditioner 4 is connected to the commercial power system 5 and supplies the converted AC power and the AC power supplied from the commercial power system 5 to the load device 6. The power conditioner 4 can sell the converted AC power to the power company.
FIG. 5 is a flowchart showing update processing of the measurement data table 221 according to an embodiment of the present invention. First, the control unit 24 sets the value of p to 1 as a date for measuring the output current of the solar cell string 1 after the operation of the photovoltaic power generation system (step S100). In the description of FIG. 5, the measurement date is described as the p-th day.
Subsequently, the control unit 24 determines whether or not the current time corresponds to any one of predetermined times (step S101). Here, the predetermined time is a time when a plurality of arbitrary times are selected from the sunrise time zone of the day, and corresponds to the time 2212 of the measurement data table 221 in FIG. If it is determined that one of the predetermined times is applicable, the process proceeds to step S102. On the other hand, if it is determined that none of the predetermined times corresponds, step S101 is repeated until the predetermined time is satisfied.
Subsequently, the control unit 24 acquires current measurement values corresponding to the solar cell strings 1 from the plurality of current measurement units 21 at any one of predetermined times (step S102).
Subsequently, the control unit 24 calculates a first average value related to the acquired plurality of current measurement values (step S103).
Subsequently, the control unit 24 associates the acquired plurality of current measurement values and the calculated first average value with the measurement date 2211 that is the p-th day and the time 2212 that is the same as the measurement time, and each of the current measurement values 2213. And it accumulates in the measurement data table 221 as the 1st average value 2214, and memorize | stores it in the memory | storage part 22 (step S104).
Subsequently, the control unit 24 determines whether one day has elapsed since the system was operated (step S105). If it is determined that one day has passed, the process proceeds to step S106. On the other hand, if it is determined that one day has not elapsed, the process returns to step S101.
If it is determined in step S105 that one day has elapsed since the system was activated, the control unit 24 increments the value of p (step S106) and returns to step S101.
FIG. 6 is a flowchart showing a system initial value 222 setting process according to an embodiment of the present invention. First, the control unit 24 sets the current that is the maximum value in the current measurement values 2213 for a plurality of days (for example, d days) included in the measurement data table 221 for each solar cell string 1 at a predetermined time. Each maximum value is extracted (step S200).
Then, the control part 24 calculates the average value (henceforth a 2nd average value) of all the solar cell strings 1 concerning the extracted electric current maximum value for every predetermined time (step S201).
Subsequently, the control unit 24 sets the system initial value 222 as the current maximum value 2222 and the second average value 2223, respectively, at each predetermined time for each solar cell string 1 as the current maximum value 2222 and the second average value 2223. Set and store in the storage unit 22 (step S202).
FIG. 7 is a flowchart showing an abnormality detection process of the solar cell string 1 due to a change with time after the system operation according to an embodiment of the present invention. It is assumed that the system initial value 222 is set by the process shown in FIG. First, the control unit 24 extracts the current measurement value 2213 and the first average value 2214 relating to the latest measurement date 2211 (p day) and the latest time 2212 (time t) in the measurement data table 221 (step S300). .
Subsequently, as shown in Expression (2), the control unit 24 calculates a value B, which is a ratio of the extracted first average value 2214 to the second average value 2223 at the time t of the system initial value 222 ( Step S301).
Subsequently, the control unit 24 collates the calculation result B in step S301 with the collation data 223, and determines whether or not the calculation result B is equal to or less than the second threshold 2233 (step S302). If it is determined that the calculation result B is greater than the second threshold 2233, the process proceeds to step S303. On the other hand, if it is determined that the calculation result B is equal to or less than the second threshold 2233, the process proceeds to step S311.
In step S302, when it is determined that the calculation result B is larger than the second threshold value 2233, the control unit 24 sets the value of m as 1 as the number related to the plurality of solar cell strings 1 (step S303). In the description of FIG. 7, the photovoltaic power generation system includes n solar cell strings 1, and each solar cell string 1 is referred to as an mth solar cell string 1 -m.
Subsequently, as shown in the equation (1), the control unit 24 calculates the ratio of the current measurement position 2213 to the extracted first average value 2214 for the m-th solar cell string 1-m at the second time t. A, which is a value divided by the ratio of the maximum current value 2222 to the average value 2223, is calculated (step S304).
Subsequently, the control unit 24 collates the calculation result A in step S304 with the collation data 223, and determines whether or not the calculation result A is equal to or less than the first threshold 2232 corresponding to the time zone 2231 to which the time t belongs ( Step S305). When it is determined that the calculation result A is equal to or less than the first threshold 2232, the process proceeds to step S306. On the other hand, if it is determined that the calculation result A is larger than the first threshold 2232, the process proceeds to step S309.
In step S305, when it is determined that the calculation result A is equal to or less than the first threshold 2232, the control unit 24 determines that the output current of the m-th solar cell string 1-m is abnormal (step S306). Alternatively, when it is determined in step S305 that the calculation result A is larger than the first threshold 2232, the control unit 24 determines that the output current of the mth solar cell string 1-m is normal (step S309). ).
Subsequently, the notification unit 23 notifies the operator of the determination result by the control unit 24 (step S307).
Subsequently, the control unit 24 increments the value of m and determines whether the value of m is larger than n (step S308). If it is determined that the value of m is greater than n, the process ends. On the other hand, if it is determined that the value of m is less than or equal to n, the process returns to step S304.
On the other hand, if it is determined in step S302 that the calculation result B is equal to or less than the second threshold 2233, the control unit 24 determines that the weather is irregular because the power generation amount is small as a whole system (step S310). In this case, the control unit 24 does not make a determination regarding the output abnormality of the solar cell string 1.
Subsequently, the notification unit 23 notifies the operator of the determination result by the control unit 24 (step S311), and ends the process.
As described above, according to the present embodiment, the system initial value that is the reference value of the output current at the beginning of the operation of the solar power generation system based on the current measurement values of the solar cell string 1 for a plurality of days from the operation day of the solar power generation system. By setting 222 and detecting an output abnormality of the solar cell string 1 based on the current output current and the system initial value 222, it is possible to easily determine whether or not the power generation amount of the solar power generation system is appropriate. . Moreover, since abnormality of an output current is detected about each solar cell string 1, specification of an abnormal part is easy. In addition, since it becomes easy to identify an abnormal part, it is possible to perform quick maintenance, and it is possible to suppress a period of operation while the power generation amount is reduced.
FIG. 8 is a flowchart showing an initial failure detection process for the solar cell string 1 during system operation according to an embodiment of the present invention. First, the control unit 24 acquires current measurement values corresponding to the respective solar cell strings 1 from the plurality of current measurement units 21 during operation of the photovoltaic power generation system (time u) (step S400).
Subsequently, the control unit 24 calculates a first average value based on the acquired plurality of current measurement values (step S401).
Then, the control part 24 sets the value of m as 1 as the number which concerns on the some solar cell string 1 (step S402). In the description of FIG. 8, the solar power generation system is assumed to include n solar cell strings 1, and each solar cell string 1 is described as an mth solar cell string 1 -m.
Subsequently, as shown in Expression (3), the control unit 24 calculates a value C, which is a ratio of the current measurement value related to the m-th solar cell string 1-m with respect to the first average value at time t ( Step S403).
Subsequently, the control unit 24 collates the calculation result C in step S403 with the collation data 223, and determines whether or not the calculation result C is equal to or less than the third threshold 2234 corresponding to the time zone 2231 to which the time u belongs. (Step S404). When the calculation result C is equal to or smaller than the third threshold value 2234, the process proceeds to step S405. On the other hand, when the calculation result C is larger than the third threshold value 2234, the process proceeds to step S408.
When determining that the calculation result C is equal to or less than the third threshold value 2234 in step S404, the control unit 24 determines that the m-th solar cell string 1-m is an initial failure (step S405). Alternatively, when it is determined in step S404 that the calculation result C is larger than the third threshold 2234, the control unit 24 determines that the output of the m-th solar cell string 1-m is normal (step S408).
Subsequently, the notification unit 23 notifies the operator of the determination result by the control unit 24 (step S406).
Subsequently, the control unit 24 increments the value of m, and determines whether or not the value of m is larger than n (step S407). If the value of m is larger than n, the process is terminated. On the other hand, when the value of m is n or less, the process returns to step S403.
Thus, by measuring the output current of each solar cell string 1 when the solar system is operating and comparing the measured current value with the average value of all the solar cell strings 1 related to the current measured value, The initial failure of the solar cell string 1 can be detected.
Next, a modification of the embodiment of the present invention will be described. In the configuration according to the above-described embodiment, the abnormality detection device 2 according to the modified example roughly determines the cause of the output abnormality of the solar cell string 1 and notifies the operator.
The control unit 24 of the abnormality detection device 2 according to the modified example accumulates the determination result related to the output abnormality of the solar cell string 1 for each solar cell string 1 in the measurement data table 221 together with the current measurement value 2213 and stores it in the storage unit 22. Remember me. The control unit 24 determines the cause of the output abnormality based on the output abnormality occurrence state.
For example, the control unit 24 of the abnormality detection device 2 according to the modified example, when an output abnormality has occurred in a specific time zone over a plurality of consecutive days in one solar cell string 1, the time zone indicates that solar cell string. It is judged that the solar radiation for 1 is blocked and shaded. Further, for example, when the output abnormality occurs in all time zones of the day over a plurality of consecutive days in one solar cell string 1, the control unit 24 according to the modification determines that the solar cell string 1 is faulty. To do. The notification unit 23 of the abnormality detection device 2 notifies the operator of the cause of the output abnormality determined by the control unit 24.
As described above, according to the modification, the cause of the output abnormality can be specified based on the state of occurrence of the output abnormality of the solar cell string 1. In addition, by notifying the operator of the cause of the output abnormality, it is possible to take appropriate maintenance measures according to the cause of the occurrence, and further increase the period during which the power generation amount is reduced as it is operated. Can be suppressed.
Although the present invention has been described based on the drawings and examples, it should be noted that those skilled in the art can easily make various modifications and corrections based on the present disclosure. For example, the functions included in each means, each step, etc. can be rearranged so that there is no logical contradiction, and a plurality of means, steps, etc. can be combined or divided into one. .
For example, it is conceivable to integrate the abnormality detection device 2 according to the present invention into another device such as a power conditioner having a multi-string configuration capable of connecting a plurality of solar cell strings 1 in parallel or a connection box.
Further, for example, when the abnormality detection device 2 according to the present invention is deployed for home use, it is conceivable to integrate it into a HEMS (Home Energy Management System) device.
DESCRIPTION OF SYMBOLS 1 Solar cell string 2 Abnormality detection apparatus 3 Junction box 4 Power conditioner 5 Commercial power system 6 Load apparatus 21 Current measurement part 22 Storage part 23 Notification part 24 Control part 221 Measurement data table 222 System initial value 223 Collation data 2211 Measurement date 2212 Time 2213 Current measurement value 2214 First average value 2221 Time 2222 Current maximum value 2223 Second average value 2231 Time zone 2232 First threshold 2233 Second threshold 2234 Third threshold
An abnormality detection device for a solar power generation system including a plurality of solar cell strings, each of which measures an output current according to each of the plurality of solar cell strings at a predetermined time, and an output of the solar power generation system set the system initial value is a reference value of the current, and a control unit for detecting an output abnormality of the solar cell strings on the basis of the current measurement value acquired from the current measurement unit and said system default, the The control unit extracts the current maximum value in the current measurement value for a plurality of days from the reference date of the photovoltaic power generation system for each solar cell string, and sets the system initial value for each predetermined time. For each solar cell string, at each predetermined time, the power with respect to a first average value of all the solar cell strings according to the current measurement value. When the result of dividing the ratio of the measured value by the ratio of the maximum current value to the second average value of all the solar cell strings related to the maximum current value is equal to or less than a predetermined first threshold value, It determined to output abnormality, the abnormality detection apparatus for photovoltaic systems.
The control unit does not determine that the output of the solar cell string is abnormal when the ratio of the first average value to the second average value is equal to or less than a predetermined second threshold at each predetermined time. The abnormality detection device according to claim 1 .
The current measuring unit measures output currents related to the plurality of solar cell strings at the time of reference of the solar power generation system, and the control unit is configured to measure each of the solar cell strings at the time of reference of the solar power generation system. when the ratio of the current measurement value for the first mean value of the total solar cell string according to the current measurement value is equal to or less than a predetermined third threshold value, determines that the initial failure of the solar cell string according to claim 1 or 2 The abnormality detection device described in 1.
An abnormality detection method for a photovoltaic power generation system, comprising: a plurality of solar cell strings; and an abnormality detection device that detects an output abnormality of the solar cell string, wherein the current measurement unit of the abnormality detection device has a predetermined time Measuring each of the output currents related to the plurality of solar cell strings, a step of setting a system initial value that is a reference value of the output current of the photovoltaic power generation system by the control unit of the abnormality detection device, Detecting an output abnormality of the solar cell string based on a current measurement value obtained from a current measurement unit and the system initial value, and the control unit includes the solar power generation system for each solar cell string. A maximum current value in the current measurement values for a plurality of days from the reference date of the system is extracted at each predetermined time, and the initial system And the ratio of the current measurement value to the first average value of all the solar cell strings related to the current measurement value at each predetermined time for each solar cell string, An abnormality detection method for a solar power generation system, in which an output abnormality of the solar cell string is determined when a result obtained by dividing by a ratio of the maximum current value to a second average value of the battery string is equal to or less than a predetermined first threshold value .
A solar power generation system comprising: a plurality of solar cell strings; and an abnormality detection device that detects an output abnormality of the plurality of solar cell strings, wherein the abnormality detection device is configured to output the plurality of solar cells at a predetermined time. A current measuring unit for measuring output currents related to the strings, a system initial value that is a reference value of the output current of the photovoltaic power generation system, and a current measured value obtained from the current measuring unit and the system initial value; A control unit that detects an output abnormality of the solar cell string based on the current, and the control unit has a current in the current measurement values for a plurality of days from a reference date of the solar power generation system for each solar cell string. A maximum value is extracted at each predetermined time to set the system initial value, and for each solar cell string, at each predetermined time The ratio of the current measurement value to the first average value of all solar cell strings related to the current measurement value is the ratio of the current maximum value to the second average value of all solar cell strings related to the current maximum value. If the division result is equal to or less than a predetermined first threshold value, you determined that abnormal output of the solar cell strings, photovoltaic systems.
JP2013092989A 2013-04-25 2013-04-25 Abnormality detection device for solar power generation system, abnormality detection method, and solar power generation system Active JP6087200B2 (en)
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