JP2019140886A - Solar cell module deterioration diagnosis system - Google Patents

Abstract

To provide a failure diagnosis method and the like that accurately identify a failure location of a solar cell module without requiring information on a solar cell module having no failure location and have high identification efficiency.SOLUTION: A failure diagnosis method includes: cutting off connection between a solar cell module 1 on which deterioration diagnostic is to be performed and a power conditioner 2; generating optimum application voltage and current corresponding to the solar cell module 1 by controlling a constant voltage power supply 3 using an application power supply control device 9; switching a solar cell module 1 to be applied depending on a flight of an unmanned aircraft 7 via an application power supply switching device 10; making the solar cell module 1 generate electroluminescent light-emission; imaging it by a near infrared camera 4 mounted on the flying unmanned aircraft 7 using a transceiver 8; storing it in a personal computer 5; and identifying a deterioration situation in the solar cell module 1 using a picture analysis program 6 in the personal computer 5. In the case of a small scale photovoltaic power generation facility that can be imaged from a vehicle for high lift work or the like, imaging is performed by a worker on the vehicle for high lift work.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a diagnostic apparatus for specifying a deterioration state of a solar cell module used in an inspection / maintenance work for a photovoltaic power generation facility.

  Due to the global movement of global environmental protection, a large amount of solar power generation facilities have been installed. Many cases of failures and malfunctions such as poor output of solar cells due to poor construction and aging have been reported. So far, fault diagnosis methods for solar cells have been developed.

For example, the technique described in Patent Document 1 is a method for diagnosing a failure of a solar cell string in which solar cell modules are connected in series. A signal generator and a waveform observation device are connected to one end of a solar cell string having no failure location. In the first connection configuration in which the other end of the solar cell string is an open end, and in the second connection configuration in which the signal generator and the waveform observation device are connected to one end of the solar cell string that is a fault location diagnosis target, The difference between the observation signal (output signal reflected from the solar cell string) in the first connection form and the observation signal from the waveform observation apparatus in the second connection form is the time when the rise and fall of the signal waveform exceed the threshold value. and T _a and T _b, the second connection configuration, the distance from the signal generator to the open end and L _a, or failure point from a signal generator The distance _{L C of,} and requests by _{L C = (T a / T} b) × L A.

JP 2009-21341 A

  In the method described in Patent Document 1, not only the observation signal from the solar cell string that is the fault location diagnosis target in the second connection mode, but also the observation signal from the solar cell string without the fault location in the first connection mode is required. . That is, it is necessary to prepare a solar cell string to be compared.

However, generally, the observation signal of the actually installed solar cell string is greatly influenced by the installation environment. Therefore, for example, when performing failure diagnosis of an aged solar cell string, it is difficult to prepare a solar cell string to be compared.

  Moreover, the failure diagnosis for identifying the failure location in the solar cell module is more problematic than the failure diagnosis for diagnosing the presence or absence of the solar cell string and the number of solar cell modules. Exists. Hereinafter, a solar cell module in which a plurality of solar cells are connected in series and fixed to a substrate is referred to as a “solar cell module”. Moreover, what connected the some solar cell module in series is called "solar cell string."

  A first problem peculiar to failure diagnosis of a solar cell module is that a high resolution is required for the failure diagnosis method. In the case of failure diagnosis of a solar cell module having one solar cell module, the signal transmission distance is shorter than that of failure diagnosis of a solar cell string having a plurality of solar cell modules. Therefore, a short observation signal can be obtained. Therefore, unless a very high-speed pulse generation / waveform observation apparatus is prepared, the failure of the adjacent solar battery cell cannot be distinguished.

  In addition, the measurement is performed for each string unit, and much time and operation are required for measurement of a large-scale photovoltaic power generation system such as a mega solar.

  Therefore, an object of the present invention is to provide a deterioration diagnosis system that accurately specifies a deterioration state of a solar cell module and does not require information on a solar cell module that does not have a failure portion, and has high work efficiency.

  In order to achieve the above object, a solar cell module deterioration diagnosis system according to the present invention applies a voltage to a plurality of solar cell strings to perform electroluminescence light emission, and to take a picture of the electroluminescence light emission. An infrared camera, a personal computer that accumulates and processes imaged images from the near-infrared camera, and an image analysis program that diagnoses deterioration of the solar cell module using the captured image in the electronic computer.

  An unmanned aerial vehicle equipped with the near-infrared camera, and a transceiver that controls flight of the unmanned aerial vehicle, receives imaging data from the near-infrared camera, and transmits the data to the electronic computer.

  It is characterized by having an applied power supply control device for controlling a constant voltage power supply so as to obtain an optimum applied voltage and current for each solar cell module.

  It is characterized by having an applied power supply control device for controlling a constant voltage power supply so as to obtain an optimum test voltage and current of the bypass diode suitable for each solar cell module.

  It has an applied power supply switching device that enables power supply to an arbitrary solar cell string.

  Aged comparison data is displayed in the image analysis program.

  A mark that can be identified by photographing by the near-infrared camera is installed on a photovoltaic power generation facility for deterioration diagnosis.

  A deteriorated solar cell module can be identified by connecting to a plurality of solar cell strings, causing electroluminescence emission, and analyzing the image captured by the near-infrared camera. Even in a large-scale photovoltaic power generation facility such as a mega solar facility, it is possible to efficiently identify the deterioration state of the solar cell module. In addition, it is possible to check the bypass diode of the solar cell module by applying an optimal test voltage and current to the solar cell string.

It is a figure which shows the whole structure of the solar cell module deterioration diagnostic system which concerns on embodiment of this invention. It is a circuit connection diagram of photovoltaic power generation equipment. It is a circuit connection diagram at the time of implementation of the present invention. It is a figure which shows the structure of a solar cell module. Example of voltage waveform by applied power supply controller It is a figure which shows the structure of an applied voltage switching apparatus. It is a figure which shows the relationship between electroluminescence light emission intensity and the deterioration degree of a solar cell module. It is a figure which shows the example of an image which image | photographed electroluminescence light emission with the said near-infrared camera. It is a figure which shows the example of a display which compared the deterioration condition of the solar cell module over time. It is a circuit connection diagram at the time of bypass diode inspection of a solar cell module. It is a figure which shows the example of installation of the mark which can be identified by imaging | photography with the near-infrared camera on a solar power generation facility.

  Hereinafter, the solar cell module deterioration diagnosis system according to the present invention will be described in detail with reference to the drawings. FIG. 1 is a diagram showing an overall configuration of a solar cell module deterioration diagnosis system according to an embodiment of the present invention.

  As shown in FIG. 1, the solar cell module deterioration diagnostic system disconnects the connection between the solar cell module 1 to be diagnosed for deterioration and the power conditioner 2, and connects the solar cell module 1 to the constant voltage power source 3 connected to the solar cell module side. Photographed in the sky above the near-infrared camera 4 for photographing the electroluminescence emission, the personal computer 5 for storing and processing the photographing data of the near-infrared camera 4, the image analysis program 6 for image processing the photographing data, and the solar cell module 1 In order to do this, it comprises an unmanned aerial vehicle 7 equipped with a near-infrared camera 4 and a transceiver 8 that controls the unmanned aircraft 7 to receive photographing data of the near-infrared camera 4 in real time and transmit it to the PC 5.

  FIG. 2 is a circuit connection diagram of the photovoltaic power generation facility. As shown in FIG. 2, a solar cell string 9 in which the solar cell modules 1 are connected in series within the allowable input voltage range of the power conditioner 2 is connected in parallel within the allowable input current range of the power conditioner 2. It is connected to NA2.

  FIG. 3 is a circuit connection diagram when the present invention is implemented. As shown in FIG. 3, the connection between the power conditioner 2 and each solar cell string 9 is disconnected, the constant voltage power source 3 is connected to the solar cell string 11, and the nominal open circuit voltage of the solar cell module is connected from the constant voltage power source 3. Power is supplied within the range and within the range of the nominal maximum output operating current to produce electroluminescence emission.

  FIG. 4 shows a configuration of the solar cell module 1, and the solar cell module 1 connects cells 10 that are basic units of the solar cell module in series, and the series connected cells are connected by a bypass diode 13.

It is necessary to apply a high-voltage DC voltage proportional to the number of series-connected solar cell modules 1 to the solar cell string 11, and in order to eliminate human errors at the site, applied power control to the constant voltage power source 3 The apparatus 9 is connected and controlled so as to obtain an applied voltage and current that are optimal for each solar cell module 1 and that changes smoothly as shown in FIG.

  FIG. 6 shows the configuration of the applied power source switching device, which protects against an abnormal current at the time of failure by the fuse 15 in string units, and switches the solar cell string 11 to which a voltage is applied by the changeover switch 14. The unmanned aerial vehicle 7 has a flight time limited to about 20 minutes due to the battery capacity of the unmanned aircraft 7, but by switching the solar cell string 11 to which voltage is applied by the application changeover switch 14 in accordance with the flight of the unmanned aircraft 7, 1 A much larger number of solar cell modules 11 can be photographed in one flight.

Electroluminescence emission is in the near-infrared band, and is taken by the near-infrared camera 4 after sunset to avoid the influence of sunlight during the day.

  FIG. 7 shows the relationship between the electroluminescence emission intensity and the deterioration of the cells 12 in the solar cell module 1. The greater the degree of deterioration of the cell 12, the weaker the intensity of electroluminescence emission.

  FIG. 8 shows an example of the captured image. The intensity of the emission intensity can be confirmed by the degree of deterioration of the cell 12, which is stored in the personal computer 5, and the deterioration of the solar cell module 1 is specified by the image analysis program 6.

  FIG. 9 is a display example in which the specified deterioration status is compared over time. As shown in FIG. 7, the start determination of the inspection work or the like of the solar cell module 1 is facilitated by comparing with time.

  The near-infrared light emission state needs to be photographed from the upper part of the solar cell module 1, and can usually be photographed by using an aerial work vehicle in a small-scale photovoltaic power generation facility.

  In the case of a large-scale solar power generation facility such as a mega solar where it is difficult for an aerial work vehicle to travel, the near-infrared camera 4 is mounted on the unmanned aerial vehicle 7 and all the solar modules 1 are leaked by the operation of the transceiver 8 Fly on a flight route that allows you to shoot without any problems. At the same time, the photographing data of the near infrared camera 4 is stored in the personal computer 5 through the transceiver 8.

  Further, by connecting the solar cell module 1 as shown in FIG. 10 and controlling the applied current to be in the vicinity of the short-circuit current of the bypass diode 13, the bypass diode 13 can be inspected.

  Since it is possible to specify the deterioration of the solar cell module 1 of a large-scale photovoltaic power generation facility such as a mega solar facility only by the circuit setting of FIG. 3 and the aerial photography by the unmanned aircraft 7, it is possible to realize an inspection work with high work efficiency. Further, the bypass diode 13 of the solar cell module 1 can be inspected by the circuit setting of FIG.

  FIG. 11 is a diagram illustrating an installation example of the mark 17 that can be identified by photographing with the near-infrared camera 4 on the solar power generation facility. The identification mark 17 is installed on the solar cell array 16, and the specific accuracy of the solar cell module 1 is improved by the mark information from the photographing data of the near infrared camera 4.

  This solar cell module deterioration diagnosis system can be used for inspection and maintenance work of photovoltaic power generation facilities.

DESCRIPTION OF SYMBOLS 1 Solar cell module 2 Power conditioner 3 Constant voltage power supply 4 Near-infrared camera 5 Personal computer 6 Image analysis program 7 Unmanned aircraft 8 Transceiver 9 Applied power supply control apparatus 10 Applied power supply switching apparatus 11 Solar cell string 12 Cell 13 Bypass diode 14 Changeover switch 15 Fuse 16 Solar cell array 17 Identification mark

Claims (6)

A solar cell module deterioration diagnosis system for use in inspection and maintenance work of solar power generation equipment, applying a voltage to a plurality of solar cell strings and causing electroluminescence emission,
A near-infrared camera for photographing the electroluminescence emission;
A personal computer for storing and processing images captured by the near-infrared camera;
And an image analysis program for diagnosing the deterioration of the solar cell module using a photographed image stored in the personal computer. A component device according to claim 1;
An unmanned aerial vehicle equipped with the near-infrared camera;
A solar cell module deterioration diagnosis system, comprising: a transceiver that performs flight control of the unmanned aircraft, receives image data from the near-ultraviolet camera, and transmits the data to the electronic computer.   3. A solar cell module deterioration diagnosis system comprising: the component device according to claim 1; and an applied power source control device for controlling an applied voltage and current to the solar cell module.   3. A solar cell module deterioration diagnosis system comprising: the component device according to claim 1; and an applied power source switching device capable of switching and connecting an applied power source to the solar cell module.   3. The solar cell module deterioration diagnosis system according to claim 1, wherein aged comparison data is displayed in the image analysis program.   The solar cell module deterioration diagnosis system according to claim 1 or 2, wherein a mark that can be identified by photographing with the near-infrared camera is installed on a photovoltaic power generation facility.