JP2001196609A - Device and method for inspecting module performance of light collecting solar battery - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a modulate performance inspecting device of a light collecting solar battery for efficiently and accurately inspecting the performance of the module assembly. SOLUTION: This device is provided with a sun tracking device 1 constituted so that the attribute of a supporting base 11 on which a module assembly MA, a standard cell assembly SA, a sum tracking sensor 9, and a CCD camera 10 are mounted can be controlled by an azimuth angle driving device 14 and an elevation angle driving device 15, and a sun tracking controller 3 for continuously controlling the attribute of the supporting base 11 so that the light receiving face of the module assembly MA can follow the moving orbit of the sun corresponding to where it in used and operating period of the sum tracking device 1, a power generating characteristic measuring device 4 for measuring the power generating characteristics of the module assembly MA and the standard cell assembly SA, and a data processor 7B for inspecting the performance of the module assembly MA by comparing this with the reference of the standard cell assembly SA.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus and a method for inspecting module performance of a concentrating solar cell for inspecting the performance of a module assembly constituting the concentrating solar cell.

[0002]

2. Description of the Related Art Conventionally, as a solar cell for converting light energy of sunlight into electric energy, a flat type solar cell in which light energy is converted into electric energy by a solar cell having a photovoltaic effect is generally known. ing. However, in this flat type solar cell, since the energy conversion efficiency of the solar cell is lower at 10 to 25% as compared with other power generation systems, it is necessary to increase the light receiving area of the solar cell to increase the power generation capacity. In addition, there is a problem that the device configuration becomes large with an increase in power generation capacity.

[0003] In recent years, concentrating solar cells capable of generating large amounts of power and capable of increasing the power generation capacity without increasing the size of the apparatus have been developed. This concentrating solar cell is provided with a condensing lens such as a Fresnel lens that converges parallel rays of sunlight about 10 to 1000 times and irradiates the light receiving surface of the solar cell with a conventional flat solar cell. Compared to batteries,
The total area of the photovoltaic cells has been reduced to 1/10 to 1/1000, and the device configuration has been significantly reduced accordingly. The concentrating solar cell has a low-voltage, large-current power generation characteristic.

[0004] Regarding a technique for inspecting the performance of a solar cell, JISC8913 defines a "method of measuring the output of a crystalline solar cell". This is a method of irradiating scattered light from a solar simulator at a predetermined irradiance to a light receiving surface of a solar cell and measuring an output voltage and an output current of the solar cell at that time.

[0005]

Meanwhile, a concentrating solar cell has a structure in which direct rays, which are parallel rays of sunlight, are condensed by a condensing lens such as a Fresnel lens and illuminated on the light receiving surface of the solar cell. Therefore, when the “method of measuring the output of a crystalline solar cell” specified in JISC8913 using the scattered light from the solar simulator as a light source, an accurate inspection result cannot be obtained.

[0006] The provisions of JISC8913 relate to performance inspection of a single solar cell, but do not specify performance inspection of a module assembly formed by connecting a plurality of solar cell assemblies.
That is, as for the performance inspection of the module assembly constituting the concentrating solar cell, an actual inspection method has not yet been established.

Accordingly, an object of the present invention is to provide an apparatus and method for inspecting a module performance of a concentrating solar cell which can efficiently and accurately inspect the performance of a module assembly constituting the concentrating solar cell. And

[0008]

Means for Solving the Problems As means for solving the above-mentioned problems, a concentrating solar cell module performance inspection apparatus according to the first invention is based on the performance of a module assembly constituting the concentrating solar cell. An apparatus for inspecting by comparing with a reference performance of a cell assembly comprising: a support base capable of mounting at least the module assembly, the reference cell assembly, a sun tracking sensor, and a CCD camera in the direction of the sun; And a sun tracking device configured to be capable of controlling the attitude in the azimuth direction and the elevation angle direction by an elevation driving device, a monitor device for displaying an image from the CCD camera, and the latitude, longitude and time of use of the installation point of the sun tracking device The sun's movement trajectory is calculated based on each input data on the date of Corrected based on al detection data,
A sun tracking control device that drives the azimuth drive device and the elevation drive device so that the light receiving surfaces of the module assembly and the reference cell assembly track the corrected movement trajectory of the sun, and outputs of the module assembly and the reference cell assembly. A power generation characteristic measurement device that inputs and measures the power generation characteristics, a thermometer that detects the cell temperature of the module assembly and the reference cell assembly, and measurement data from the power generation characteristic measurement device and temperature measurement data from the thermometer. It is characterized by comprising a data logger to be recorded and a data processing device for inspecting the performance of the module assembly based on the recorded data of the data logger.

In the module performance inspection apparatus for a concentrating solar cell according to the first aspect of the invention, when each information of the latitude, longitude and date of use is input to the sun tracking control apparatus, the sun tracking control apparatus is Calculate the sun's movement trajectory according to the installation point and the point of use, correct the calculated value based on the detection data from the sun tracking sensor, and add the light receiving surface of the module assembly and the reference cell assembly to the corrected sun's movement trajectory. The azimuth drive device and the elevation drive device are driven so as to track, and the attitude of the support base is continuously controlled. In addition, the power generation characteristic measuring device inputs the output of the module assembly and the reference cell assembly and measures the power generation characteristics, the temperature detector detects the cell temperatures of the module assembly and the reference cell assembly, and the data logger measures the power generation characteristic of the power generation characteristic measuring device. Record the data and thermometer data. Then, the data processing device checks the performance of the module assembly based on the data recorded in the data logger.

In the module performance inspection apparatus for a concentrator photovoltaic cell according to the first invention, if the apparatus is provided with a pyranometer, a direct pyranometer, a wind speed anemometer and an outside air thermometer for outputting observation data to the data logger, It is preferable because data of global solar radiation, direct solar radiation, wind speed, wind direction, and outside air temperature which affect the power generation performance of the assembly can be recorded, and the performance inspection of the module assembly can be performed more accurately.

Further, it is preferable that the data processing device is connected to a database of a module assembly production line management system via a network, because the result of the performance inspection of the module assembly can be reflected in real time on the quality control and production control of the production line. .

On the other hand, the method for inspecting module performance of a concentrating solar cell according to the second invention is a method for inspecting the performance of a module assembly using the module performance inspecting apparatus for a concentrating solar cell according to the first invention. Then, install the sun tracking device while checking the display of the monitor device so that the CCD camera captures the sun image, and input the latitude, longitude, date and time of the use location of the sun tracking device. The solar tracking control device is activated to measure the power generation amount and the IV characteristics of the module assembly and the reference cell assembly by the power generation characteristic measuring device, and the data processing device generates the power of the reference cell assembly based on the measured data. By converting the amount of light energy of sunlight from the amount of power, and obtaining the amount of power generated by the module assembly for a predetermined amount of light energy, , Module assembly of I-V
The characteristic is compared with the IV characteristic of the reference cell assembly to calculate an internal resistance value of the module assembly.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an embodiment of a module performance inspection apparatus for a concentrating solar cell according to the first invention will be described with reference to the drawings. An embodiment of a module performance inspection method will be described. In the drawings to be referred to, FIG. 1 is an exploded perspective view of a module assembly inspected by a concentrating solar cell module performance inspection apparatus according to one embodiment, and FIG. 2 is a module performance of the concentrating solar cell according to one embodiment. FIG. 3 is an exploded perspective view of a cell assembly used for an inspection apparatus, FIG. 3 is a perspective view of a cell assembly used for a module performance inspection apparatus for a concentrating solar cell according to an embodiment, and FIG. FIG. 5 is a side view schematically showing the entire configuration of the optical solar cell module performance inspection apparatus, FIG. 5 is a block diagram showing a data flow in the concentrating solar cell module performance inspection apparatus according to one embodiment, and FIG. It is a graph which shows the power generation characteristic of a cell assembly and a module assembly inspected by a module performance inspection device of a concentrating solar cell concerning one embodiment.

An apparatus for inspecting module performance of a concentrating solar cell according to one embodiment has a reference performance of a cell assembly SA based on the performance of a module assembly MA constituting the concentrating solar cell SU as shown in FIG. This is a device that performs inspection by comparing with. Therefore, first, the schematic structures of the concentrating solar cell SU, the module assembly MA, and the cell assembly SA will be described.

As shown in FIG. 1, the concentrating solar cell SU
Is, for example, 15 module assemblies MA vertically 5
It has a structure in which three rows and three rows are arranged and electrically connected to each other. The approximate dimensions of the concentrating solar cell SU are 3m in height and 4m in width.
It is about. This concentrating solar cell SU has a thickness of 0.6-0.
It has a power generation characteristic of flowing a large current of 10 A or more at a low voltage of 8 V.

In the module assembly MA, for example, eight cell assemblies SA are accommodated in a box-shaped base panel BP arranged in two columns and four rows, and the respective cell assemblies SA are electrically connected to each other. Having a structure.
A condensing lens CL is mounted on the base panel BP via a lens frame LF in order to collect and irradiate sunlight to the solar cells C of each cell assembly SA.
The condensing lens CL is composed of a flat Fresnel lens, and condenses and irradiates the solar cells C of each cell assembly SA approximately 100 times. In addition, a heat sink panel HP is attached to the lower surface of the base panel BP in order to radiate solar heat due to light collection.

The cell assembly SA is shown in FIGS.
As shown in FIG. 2, a single-crystal solar cell C for converting light energy into electric energy, and a ceramic formed with a predetermined pattern of wiring for extracting the generated current of the solar cell C to a pair of electrode terminals ET, ET. It is composed of a substrate SB, an optical axis adjuster OA that irradiates the entire surface of the solar cell C with sunlight without any optical axis deviation, and a heat spreader HS for heat radiation. The solar cell C is soldered and fixed at a predetermined position on the ceramic substrate SB together with the pair of electrode terminals ET, ET, and an optical axis adjuster OA is adhesively fixed to the upper surface of the solar cell C. Further, the ceramic substrate SB is positioned by being fitted into a housing recess S formed on the upper surface of the heat spreader HS, and is bonded and fixed to the heat spreader HS in this state. In the cell assembly SA thus configured, the heat spreader HS passes through the bottom surface of the base panel BP of the module assembly MA and the heat sink panel HP
Is assembled into the module assembly MA.

As shown in FIGS. 4 and 5, a module performance inspection apparatus for a concentrating solar cell according to an embodiment includes a sun tracking device 1, a monitor device 2, a sun tracking control device 3, a power generation characteristic measuring device 4, Temperature detectors 5A and 5B, data logger 6A,
6B and the data processing devices 7A and 7B as main parts, including a pyranometer 8A, a direct pyranometer 8B,
An anemometer 8C and an outside air thermometer 8D are additionally provided. Hereinafter, these will be sequentially described.

The sun tracking apparatus 1 has a module base MA to be inspected, a cell assembly SA having a reference performance, a sun base sensor 9, and a support base 11 on which a CCD camera 10 is aligned in the sun direction. The support base 11 is supported on the upper end of a column 13 erected on a movable carriage 12 via an azimuth drive device 14 and an elevation drive device 15 so as to be capable of controlling the attitude in the azimuth direction and the elevation direction.

The module assembly MA to be inspected
Has a structure in which eight cell assemblies SA are built in, similarly to the module assembly MA shown in FIG.
In addition, the cell assembly SA having the reference performance is described in, for example, “Japan Quality Assurance Organization (JP
A) ”means that the performance is determined to be a reference value. This cell assembly SA is mounted on the support base 11 together with another condenser lens CL configured similarly to the condenser lens CL of the module assembly MA.

As shown in FIG. 4, the support base 11 is mounted on the upper end of the column 13 so as to be tiltable about a horizontal axis O with respect to a rotary base 13A mounted rotatably about a vertical axis. . The azimuth driving device 14 for controlling the attitude of the support base 11 in the azimuth direction has a stepping motor and a gear reduction mechanism (not shown) built in the support 13, and the rotation of the stepping motor is reduced by the gear reduction mechanism. The rotary base 13A is configured to be driven to rotate. An elevation drive device 15 for controlling the attitude of the support base 11 in the elevation direction is constituted by a linear actuator which is extendably extendable between the rotary base 13A and the support base 11, and includes a linear actuator built therein. The support base 11 is tilted around the horizontal axis O when the linear actuator expands and contracts by a stepping motor that is not used.

The monitor device 2 is connected to a CCD camera 10 mounted on a support base 11 of the sun tracking device 1 via a sun tracking control device 3.
The image from the CCD camera 10 is displayed in response to the instruction. The monitor device 2 includes a sun tracking sensor 9 and a CC
It is used to confirm whether or not the sun is located within the measurement visual field of the D camera 10.

The sun tracking control device 3 is provided with
It is housed in a power supply box 16 mounted thereon, and is connected to a power supply via a breaker 16A in the power supply box 16. The input terminal of the sun tracking control device 3 is connected to the sun tracking sensor 9 and the CCD camera 10, and a notebook personal computer for inputting various information and commands is connected as the input device 17. The output terminal of the sun tracking control device 3 is connected to the monitor device 2, the azimuth drive device 14, and the elevation drive device 15.

The input device 17 inputs information on the latitude, longitude, and date of use when the sun tracking device 1 is installed, and activates the azimuth driving device 14 and the elevation driving device 15 of the sun tracking device 1. It is used for inputting commands such as stop, return to origin, and the like. Then, the sun tracking control device 3 to which each information of the latitude, longitude and date of use (date) is input from the input device 17 based on these information, It has a function of calculating a movement trajectory and correcting the calculated value based on input data from the sun tracking sensor 9. And
The sun tracking control device 3 outputs a drive signal to the azimuth drive device 14 and the elevation drive device 15 so that the light receiving surfaces of the module assembly MA and the cell assembly SA follow the corrected movement trajectory of the sun. It is configured such that the attitude of the support base 11 can be controlled.

The power generation characteristic measuring device (PPT device) 4 is disposed on the instrument box 18 side separate from the movable trolley 12. The output terminal of the cell assembly SA is connected to the input terminal of the power generation characteristic measuring device 4, and the output terminal of the module assembly MA is connected to the power supply box 16.
And a loader 19 used for measuring the IV characteristics of the cell assembly SA and the module assembly MA. Further, one data processing device 7A composed of a desktop personal computer is connected for operation management of the power generation characteristic measuring device 4. A data logger 6A is connected to an output terminal of the power generation characteristic measuring device 4.

The power generation characteristic measuring device 4 has a function of measuring the amount of generated power and the IV characteristics (see FIG. 6) as the power generation characteristics of the cell assembly SA and the module assembly MA. Note that the IV characteristics of the module assembly MA are obtained when the load 19 is connected to the output terminal of the module assembly MA and the load resistance is rapidly changed from a minimum value (several mΩ) to a maximum value (infinity). The current value I (A) and the voltage value V (V) are measured and obtained. The IV characteristics of the cell assembly SA are obtained in the same manner.

The temperature detectors 5A and 5B are composed of, for example, thermocouples. One of the temperature detectors 5A is bonded to the solar cell C of the cell assembly SA to measure the temperature, and the other temperature detector 5B is the module assembly. It is adhered to the solar cell C of MA and its temperature is measured. These temperature detectors 5A and 5B are connected to a data logger 6A so as to output temperature measurement data.

The data loggers 6A and 6B have a function of recording all input data as readable data, and are connected to each other so that data can be exchanged. The input terminal of one data logger 6A is connected to the above-mentioned power generation characteristic measuring device 4 and temperature detectors 5A and 5B, as well as a global pyranometer 8A, a direct solar radiation meter 8B, and a wind speed anemometer 8C which are erected on an instrument box 18. And an outside air thermometer 8D are connected so as to output data. An output terminal of the other data logger 6B is connected to another data processing device 7B composed of a desktop personal computer.

The pyranometer 8A and the direct pyranometer 8B
Is used to confirm the amount of solar energy at the time of performance inspection of the module assembly MA. Further, the wind speed anemometer 8C and the outside air thermometer 8D are used for collecting data such as an air volume and an outside air temperature affecting the temperature of the solar cell C of the module assembly MA.

The other data processing device 7B has a function of converting the performance of the module assembly MA into a reference temperature of 25 ° C. based on the recorded data of the data logger 6B and inspecting it. That is, the data processing device 7B converts the amount of light energy of sunlight based on the data of the amount of power generated by the cell assembly SA having the reference performance, and calculates the amount of power generated by the module assembly MA for a predetermined amount of light energy. This is converted to the amount of generated power at a reference temperature of 25 ° C. Further, the internal resistance value of the module assembly MA is calculated by comparing the IV characteristic of the module assembly MA with the IV characteristic of the reference cell assembly SA.

As shown in FIGS. 4 and 5, the data processing devices 7A and 7B are network-connected via an Ethernet 21 to a database 20 constituting a production line management system for the module assembly MA. It is configured so that the results of the performance inspection can be immediately reflected in the quality control and production control of the production line.

Next, a method of inspecting the module performance of a concentrating solar cell using the apparatus for inspecting the module performance of a concentrating solar cell according to one embodiment configured as described above will be described.
In carrying out this module performance inspection method, first, a module performance inspection device for a concentrating solar cell is installed outdoors. At this time, the direction of the mobile trolley 12 is set so that the support base 11 of the sun tracking device 1 faces the south side at the initial position. Then, from the input device 17 to the azimuth drive device 14
In addition, a start command and a stop command of the elevation drive device 15 are appropriately input, and the posture of the support base 11 is initialized while confirming the display of the monitor device 2 so that the CCD camera 10 on the support base 11 captures a solar image.

Next, the latitude of the installation location of the solar tracking device 1
The longitude and the date of use are input from the input device 17 to the sun tracking control device 3. Based on this input, the sun tracking control device 3 calculates the movement locus of the sun according to the installation point and the use time point of the sun tracking device 1, and corrects the calculated value based on the detection data from the sun tracking sensor 9. Then, the sun tracking control device 3 outputs a drive signal to the azimuth drive device 14 and the elevation drive device 15 such that the light receiving surfaces of the module assembly MA and the cell assembly SA follow the corrected movement trajectory of the sun. Thus, the attitude of the support base 11 is continuously controlled.

In the module assembly MA and the cell assembly SA, the attitudes of which are controlled so that the light-receiving surface tracks the sun, each of the condensing lenses CL condenses the solar light approximately 100 times and irradiates each solar cell C. This starts the photovoltaic power generation. Therefore, the data processing device 7
A inputs a measurement start command to the power generation characteristic measuring device 4 from A. With this input, the power generation characteristic measuring device 4 measures the power generation amount and the IV characteristics of the module assembly MA and the cell assembly SA (see FIG. 6), and outputs the measurement data to the data loggers 6A and 6B. Further, the thermometers 5A and 5B output the temperature data of the respective solar cells C of the cell assembly SA and the module assembly MA to the data logger 6A, and also have a solar radiation meter 8A, a direct solar radiation meter 8B, an anemometer 8C, and an outside air temperature. The total 8D outputs each observation data to the data logger 6A.

The data logger 6A receives the measurement data from the power generation characteristic measuring device 4 and the temperature data from the temperature detectors 5A and 5B, and also receives a pyranometer 8A, a direct pyranometer 8B,
After inputting and recording each observation data from the wind speed anemometer 8C and the outside air thermometer 8D, the data processing device 7B is instructed to analyze the data and inspect the performance of the module assembly MA.

The data processor 7B, which has received the data analysis command, analyzes the data recorded in the data loggers 6A and 6B and converts the performance of the module assembly MA into a reference temperature of 25 ° C. for inspection. That is, the data processing device 7B converts the amount of light energy of sunlight based on the data on the amount of generated power of the cell assembly SA having the reference performance. Then, for example, the power generation amount of the module assembly MA with respect to the light energy amount of 1000 W / m ² is calculated, and this is converted into the power generation amount at the reference temperature of 25 ° C. Further, the internal resistance value of the module assembly MA is calculated by comparing the IV characteristic of the module assembly MA with the IV characteristic of the reference cell assembly SA.

Here, when the amount of power generated by the module assembly MA is equal to or less than a predetermined reference value, that is, the amount of power generated by the module assembly MA for a light energy of 1000 W / m ^{2 at} a reference temperature of 25 ° C. is equal to or lower than a predetermined reference value. In this case, the data processing device 7B determines that the power generation performance of the module assembly MA is poor.
If the internal resistance value of the module assembly MA is equal to or larger than the predetermined reference value, the data processing device 7B determines that the internal resistance value of the module assembly MA is defective. Then, the data processing device 7B transmits the determination result of the power generation performance and the internal resistance value of the module assembly MA to the database 20 constituting the manufacturing line management system of the module assembly MA in the Ethernet 2 format.
1 via

Thus, the module assembly MA
In the production line management system, the result of the performance inspection of the module assembly MA can be used for quality control and production control in real time.

[0039]

As described above, in the concentrating solar cell module performance inspection apparatus according to the first invention, information on the latitude, longitude and date of use is input to the sun tracking control device. Then, the sun tracking control device calculates the movement trajectory of the sun according to the installation location and the time of use, corrects the calculated value based on the detection data from the sun tracking sensor, and adds the module assembly to the corrected movement trajectory of the sun. Further, the azimuth driving device and the elevation driving device are driven so that the light receiving surface of the reference cell assembly tracks, and the attitude of the support base is continuously controlled. In addition, the power generation characteristic measuring device inputs the output of the module assembly and the reference cell assembly and measures the power generation characteristics, the temperature detector detects the cell temperatures of the module assembly and the reference cell assembly, and the data logger measures the power generation characteristic of the power generation characteristic measuring device. Record the data and thermometer data. Then, the data processing device checks the performance of the module assembly based on the data recorded in the data logger. Therefore, according to the concentrating solar cell module performance inspection apparatus of the first invention, it is possible to efficiently and accurately inspect the performance of the module assembly constituting the concentrating solar cell.

In the concentrating solar cell module performance inspection apparatus according to the first aspect of the present invention, when the apparatus includes a solar radiation meter, a direct radiation pyrheliometer, a wind speed anemometer, and an outside air thermometer for outputting observation data to a data logger, Data on global solar radiation, direct solar radiation, wind speed, wind direction, and outside temperature that affect the power generation performance of the module assembly can be recorded, and the performance inspection of the module assembly can be performed more accurately.

When the data processing device is connected to the database of the module assembly manufacturing line management system via a network, the result of the performance inspection of the module assembly is reflected on the quality control and production control of the manufacturing line in real time. Can be.

On the other hand, according to the method for inspecting module performance of a concentrating solar cell according to the second invention, since the apparatus for inspecting module performance of a concentrating solar cell according to the first invention is used, the performance of the module assembly can be reduced. In addition to being able to accurately and accurately inspect, the power generation amount and the IV characteristics of the module assembly and the reference cell assembly are measured, and the light energy of sunlight is converted from the power generation amount of the reference cell assembly. A module for calculating an internal resistance value of the module assembly by calculating an amount of power generated by the module assembly with respect to a predetermined amount of light energy and comparing an IV characteristic of the module assembly with an IV characteristic of the reference cell assembly. The quality of the power generation performance of the assembly and the quality of the internal resistance can be determined.

[Brief description of the drawings]

FIG. 1 is an exploded perspective view of a module assembly inspected by a module performance inspection apparatus for a concentrating solar cell according to an embodiment corresponding to the first invention.

FIG. 2 is an exploded perspective view of a cell assembly used in a concentrating solar cell module performance inspection apparatus according to one embodiment.

FIG. 3 is a perspective view of a cell assembly used in a concentrating solar cell module performance inspection apparatus according to one embodiment.

FIG. 4 is a side view schematically showing an overall configuration of a concentrating solar cell module performance inspection apparatus according to one embodiment.

FIG. 5 is a block diagram showing a data flow in the concentrating solar cell module performance inspection apparatus according to one embodiment.

FIG. 6 is a graph showing power generation characteristics of a cell assembly and a module assembly inspected by the module performance inspection apparatus for a concentrating solar cell according to one embodiment.

[Description of Signs] 1: Sun tracking device 2: Monitor device 3: Sun tracking control device 4: Power generation characteristic measuring device 5A: Temperature detector 5B: Temperature detector 6A: Data logger 6B: Data logger 7A: Data processing device 7B: Data processing device 8A: Global pyranometer 8B: Direct pyranometer 8C: Wind speed anemometer 8D: Outside air temperature meter 9: Sun tracking sensor 10: CCD camera 11: Support base 14: Azimuth angle drive device 15: Elevation angle drive device 20: Database MA: Module assembly SA: Reference cell assembly SU: Concentrating solar cell

 ────────────────────────────────────────────────── ─── Continued on the front page (72) Inventor Ken Uchiyama 1-13-1 Aoi Higashi, Hamamatsu City, Shizuoka Prefecture Honda Motor Co., Ltd. Hamamatsu Factory F-term (reference) 5F051 BA11 KA09

Claims (4)

[Claims] An apparatus for inspecting the performance of a module assembly constituting a concentrating solar cell by comparing the performance with a reference performance of a reference cell assembly, wherein at least the module assembly, the reference cell assembly,
A sun tracking device comprising a support base on which a sun tracking sensor and a CCD camera can be mounted aligned in the sun direction and capable of controlling the attitude in an azimuth direction and an elevation direction by an azimuth drive device and an elevation drive device, and the CCD camera A monitor device that displays an image from, and calculates the movement locus of the sun based on each input data of the latitude, longitude, and date of use of the installation point of the sun tracking device, and calculates the calculated value from the sun tracking sensor. A sun tracking control device that drives the azimuth drive device and the elevation drive device so that the light receiving surfaces of the module assembly and the reference cell assembly track the corrected movement trajectory of the sun based on the detected data. A power generation characteristic measuring device for inputting the output of the assembly and the reference cell assembly and measuring the power generation characteristics thereof. A temperature detector for detecting a cell temperature of the module assembly and the reference cell assembly; a data logger for recording measurement data from the power generation characteristic measuring device and temperature detection data from the temperature detector; and a recording data of the data logger. An apparatus for inspecting module performance of a concentrating solar cell, comprising a data processing apparatus for inspecting the performance of the module assembly. 2. The inspection apparatus according to claim 1, further comprising: a pyranometer, a direct pyranometer, a wind speed anemometer, and an outside air thermometer for outputting observation data to the data logger. A module performance inspection device for concentrating solar cells. 3. The inspection apparatus according to claim 1, wherein the data processing apparatus is network-connected to a database configuring a production line management system of the module assembly. A module for testing the performance of optical solar cells. 4. A method of inspecting the performance of a module assembly using the module performance inspection apparatus of a concentrating solar cell according to claim 1, wherein the CCD camera captures a solar image. Install the sun tracking device while checking the display,
The solar tracking control device is started by inputting the longitude and the date of the date of use, and the power generation characteristic measuring device measures the power generation amount and the IV characteristic of the module assembly and the reference cell assembly, and the measurement is performed. Based on the data, the data processing device converts the amount of light energy of sunlight from the amount of power generated by the reference cell assembly to determine the amount of power generated by the module assembly with respect to a predetermined amount of light energy, and the IV characteristics of the module assembly. A method for inspecting module performance of a concentrating solar cell, comprising: calculating the internal resistance value of the module assembly by comparing the I.V. characteristics with the IV characteristics of the reference cell assembly.