KR101137687B1 - Quality Tester of Solar Cell Module - Google Patents

Abstract

The present invention measures the voltage applied between the solar cell strings of the solar cell module generated by the light source, and analyzes the magnitude difference between the measured voltages of the solar cell strings and quantifies the quality degree of the solar cell module according to the analysis result. The present invention relates to a quality inspection apparatus for a solar cell module, including: a voltage measuring unit measuring a voltage applied between a solar cell string of the solar cell module; A current measuring unit measuring a current flowing in the solar cell string; Analyze the magnitude difference between the voltage between the solar cell string measured by the voltage measuring unit and the voltage between the solar cell string that changes according to the magnitude change of the current flowing through the solar cell string using the current measured by the current measuring unit By including a control unit for calculating the degree of quality of the battery module, there is an effect that can maximize the accuracy during quality inspection of the solar cell module.

Description

Quality tester of solar cell module {Quality Tester of Solar Cell Module}

The present invention relates to a quality inspection apparatus of a solar cell module, and in particular, to measure the voltage across the string of the solar cell of the solar cell module generated by the light source and to analyze the magnitude difference between the measured voltage between the string of the solar cell In accordance with the present invention relates to a solar cell module quality inspection apparatus that can be expressed by indicating the quality degree of the solar cell module.

Today, due to the finiteness of fossil fuels, there is a growing interest in developing alternative energy. Representative alternative energy is a solar cell that can generate electrical energy by using sunlight, which is a clean energy source.

Solar cell is a device that converts light energy transmitted from the sun to the earth into electric energy. The development of solar cell is getting full of energy with the development of technology to grow single crystal silicon. Is being developed.

A solar cell is a device that converts sunlight directly into electricity, and is basically a diode composed of a p-n junction. In the process of converting sunlight into electricity by solar cells, when solar light is incident on the pn junction of solar cells, electron-hole pairs are generated, and electrons move to n layers and holes move to p layers by the electric field. Thus, photovoltaic power is generated between the pn junctions. At this time, when a load such as a specific system is connected to both ends of the solar cell, current flows to generate power and supply the produced power to the load.

As described above, a solar cell structure having a p-n junction diode is called a solar cell and a form in which a plurality of solar cells are electrically connected is called a solar cell module.

1, a solar cell string 10 formed by connecting solar cell 12 in series using a ribbon having conductivity on a module substrate, as shown in FIG. 1. ) Is composed of an array structure formed by connecting a certain number in series or in parallel. In addition, the solar cell module includes connection terminals for collecting power generated from each solar cell string 10 through a conductive bus bar 5 and delivering the same to a load 20 such as a specific system. The terminal box 30 provided with B, C, and D is provided. The terminal box 30 includes a bypass diode BD for preventing the photovoltaic cell from being burned out due to hot spots caused by shadows, dust, and solar cell defects. , B, C, D) is configured in a circuit.

Such a solar cell module undergoes a procedure of inspecting the quality of the module prior to shipping the product after the manufacturing process, in which a quality inspection method using an electroluminescence (EL) camera or an infrared ray (IR) camera is mainly used. .

The EL camera quality inspection method is a method of inspecting the quality of a solar cell module by using a characteristic of generating light when the solar cell 12 receives current. The EL camera quality inspection method supplies current through the connection terminals A and D of the solar cell module, and then checks the light intensity of the solar cells 12 constituting the solar cell module through EL camera photographing. In this way, the quality of the solar cell module is checked. At this time, a defective solar cell emits weaker light than a normal cell because current does not flow smoothly.

The IR camera quality inspection method is a method of inspecting the quality of the solar cell module by using a characteristic of generating heat when the solar cell 12 receives current. In this IR camera quality inspection method, by supplying a current through the connection terminals (A, D) of the solar cell module, and then confirm the temperature of the solar cells 12 constituting the solar cell module through the IR camera, It is a way to inspect the quality of solar cell modules. At this time, a defective solar cell emits a lower temperature than a normal cell because current does not flow smoothly.

However, such a conventional solar cell module quality inspection method is a method of confirming the intensity or temperature of light emitted from the solar cell 12 through camera photography, which is dependent on the visual ability of the inspector, and thus has a high probability of false positives. Moreover, since the electrical characteristics of the solar cell module do not unconditionally affect the power generation efficiency, there is a problem in that the accuracy is poor in quality inspection.

The present invention has been made to solve the problems described above, by measuring the voltage across the string of the solar cell of the solar cell module generated by the light source and analyzes the magnitude difference between the measured voltage between the string of the solar cell It is an object of the present invention to provide a quality inspection apparatus for a solar cell module that can quantify the quality of the solar cell module according to the results.

In order to achieve the object as described above, the solar cell module quality inspection apparatus according to an embodiment of the present invention, the voltage measuring unit for measuring the voltage across the solar cell string of the solar cell module; A current measuring unit measuring a current flowing in the solar cell string; Analyze the magnitude difference between the voltage between the solar cell string measured by the voltage measuring unit and the voltage between the solar cell string that changes according to the magnitude change of the current flowing through the solar cell string using the current measured by the current measuring unit It is preferable to include a control unit for calculating the degree of quality of the battery module.

The controller may include a graph generation module configured to generate a magnitude change of a voltage between the solar cell strings according to the magnitude change of the current flowing in the solar cell string as a graph having an I-V curve; A graph analysis module for analyzing a graph having an I-V curve shape generated by the graph generation module and calculating magnitude differences between voltages of the solar cell strings that change according to the magnitude change of the current flowing in the solar cell strings; It is preferable to include a quality calculation module for calculating a predetermined multiple of the magnitude difference value between the voltage between the solar cell strings calculated by the graph analysis module to the quality of the solar cell module.

The graph analysis module preferably analyzes a graph in the form of an I-V curve generated through the graph generation module through a graph analysis algorithm of a point, line, or plane method.

When the graph analysis module is analyzed using a point-based graph analysis algorithm, the graph analysis module corresponds to a current value in every section or a certain section of each IV curve representing a voltage between solar strings that changes according to the magnitude of the current. Comparing the magnitude between the voltage values on each IV curve to calculate the difference value, and by calculating the average value of the calculated difference value, the magnitude between the voltage between the solar cell string that changes in accordance with the magnitude change of the current flowing in the solar cell string It is desirable to calculate the difference.

In addition, the graph analysis module, when the analysis using a linear graph analysis algorithm, in each section or a certain section of each IV curve representing the voltage between the strings of solar cells that change according to the change in the magnitude of the current of each IV curve By comparing the lengths and calculating the difference, it is preferable to calculate the magnitude difference between the voltages between the strings of the solar cells that change according to the magnitude change of the current flowing through the string.

In addition, the graph analysis module, when the analysis using a surface-based graph analysis algorithm, each IV curve in every section or a certain section of each IV curve representing the voltage between the string of solar cells that changes according to the change in the magnitude of the current By calculating the area formed by each IV curve by integrating, and calculating the difference value by comparing the size of the calculated area, it is possible to measure the magnitude difference between the voltages between the strings of the solar cells that change according to the magnitude of the current flowing through the solar cell strings. It is preferable to calculate.

In addition, the quality inspection apparatus of the solar cell module according to the present invention, the size difference between the voltage between the solar cell string changes according to the quality degree of the solar cell module and the magnitude of the current flowing through the solar cell string under the control of the controller. It is preferable that the display further comprises a display for displaying a graph of the IV curve form.

The voltage measuring unit may be in contact with each connection terminal configured in the terminal box installed in the solar cell module or to connect the connection terminals between the respective connection terminals in order to sense voltage between the solar cell strings constituting the solar cell module. It is preferable to include a plurality of probes (Prove) in contact with both ends of the bypass diode.

According to the quality inspection apparatus of the solar cell module according to the present invention, the voltage across the string of the solar cell of the solar cell module generated by the light source is measured and the magnitude difference between the measured voltage between the string of the solar cell is analyzed and the result of the analysis. Accordingly, by quantifying the quality degree of the solar cell module, there is an effect that can maximize the accuracy during quality inspection of the solar cell module.

1 is a plan view showing a typical solar cell module.
Figure 2 is a block diagram schematically showing the configuration of a quality inspection apparatus of a solar cell module according to an embodiment of the present invention.
Figure 3 is a block diagram schematically showing the configuration of the control unit in the quality inspection device of the solar cell module according to the present invention.
Figure 4 is an exemplary view showing a result of calculating the quality level of each solar cell module in the solar cell module quality inspection apparatus according to the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail a quality inspection apparatus of a solar cell module according to an embodiment of the present invention.

2, in the solar cell module quality inspection apparatus according to an embodiment of the present invention, the load 20 is connected, the voltage applied between the solar cell string of the solar cell module generated by an artificial or natural light source The voltage measuring unit 100 measuring (V _AB , V _BC , V _CD ), the current measuring unit 110 measuring the current I _AD flowing through the solar cell string 10, and the voltage measuring unit 100. The magnitude of the current flowing in the solar cell string 10 using the voltage between the string (V _AB , V _BC , V _CD ) and the current (I _AD ) measured through the current measuring unit 110 measured through) A control unit 120 for calculating a degree of quality of the solar cell module by analyzing a magnitude difference between voltages of the solar cell strings that change according to the change, and a display unit for displaying the quality degree of the solar cell module under control of the control unit 120 ( 130). In addition, the communication unit 140 for transmitting the measurement values of the voltage measuring unit 100 and the current measuring unit 110 to a separate computer device and the like, and generates various operation control signals in accordance with the input from the user. It is preferable to further include an input unit 150 configured as a switch for transferring to the control unit 120. In addition, the voltage measuring unit 100, the current measuring unit 110, the control unit 120, the display unit 130, the communication unit 140 and the input unit 150, it is more preferable to further include a power supply for supplying operating power, respectively. Do.

Here, the voltage measuring unit 100 controls a plurality of probes for sensing the voltage between the solar cell strings 10 constituting the solar cell module, and digitally processes the data sensed through the plurality of probes. It is preferable to include an A / D (Analog / Digital) converter and the like delivered to (120). For example, the probe is in contact with each connection terminal (A, B, C, D) configured in the terminal box 30 installed in the solar cell module, or connected between each connection terminal (A, B, C, D) It is preferable to sense the voltage V _AB , V _BC , V _CD between the solar cell strings 10 by contacting both ends of each bypass diode BD.

The current measuring unit 110 may include a current sensing sensor such as a hall effect sensor, an A / D converter, etc., which digitally processes data sensed through the current sensing sensor and transmits the digital signal to the controller 120. It is preferable to make. For example, the current sensing sensor may be any one of the connection terminals A and D to which the load 20 is connected among the connection terminals A, B, C, and D configured in the terminal box 30 installed in the solar cell module. Is installed on the side, the current (I _AD ) flowing in the solar cell string 10 is connected to each other in series, that is to sense the current flowing to the solar cell module as a whole by the load 20 connected to the solar cell module.

Meanwhile, as illustrated in FIG. 3, the control unit 120 includes the magnitudes of the voltages V _AB , V _BC , and V _CD between the strings of the solar cells according to the magnitude change of the current I _AD flowing in the solar cell string 10. The graph generation module 122 generates a change in the form of an IV curve, and the current flowing through the solar cell string 10 by analyzing the graph in the form of the IV curve generated through the graph generation module 122. _The solar cell calculated by the graph analysis module 124 and the graph analysis module 124 that calculate the magnitude difference between the voltages V _AB , V _BC , V _CD between the strings of the solar cells that change according to the size change of _AD ). And a quality calculation module 126 that calculates a constant multiple of magnitude difference values between voltages V _AB , V _BC , and V _CD between strings.

Here, the graph analysis module 124 uses the graph analysis algorithm (Algorithm), such as a point, line or dimension method, on the graph of the IV curve shape generated by the graph generation module 122. The magnitude difference between the voltages V _AB , V _BC , and V _CD between the strings of the solar cells that changes according to the magnitude change of the current I _AD flowing in the solar cell string 10 is calculated.

When the graph analysis module 124 analyzes a graph using a point-based graph analysis algorithm, the graph analysis module 124 changes according to the magnitude of the current I _AD based on the current axis I or the voltage axis V. Compute the difference value by comparing the magnitudes of the voltage values on the respective IV curves corresponding to the current values in all or a certain interval of each IV curve representing the voltage (V _AB , V _BC , V _CD ) between the solar cell strings, By calculating the average value of the calculated difference, the magnitude difference between the voltages V _AB , V _BC , V _CD between the strings of the solar cells that changes with the magnitude change of the current I _AD flowing in the solar cell string 10 is calculated. Will be calculated.

In this case, when the graph analysis module 124 calculates a difference value by comparing magnitudes between voltage values on respective IV curves corresponding to the current value, the graph analysis module 124 sets one of the respective IV curves as a reference IV curve and sets the reference. It is preferable to calculate by subtracting the voltage values on the remaining IV curves from the voltage values on the IV curves. Here, the graph analysis module 124 preferably sets the I-V curve having the maximum voltage value among the I-V curves as the reference I-V curve.

In addition, when the graph analysis module 124 analyzes the graph by using a graph analysis algorithm of the line method, the graph analysis module 124 changes according to the magnitude change of the current I _AD based on the current axis I or the voltage axis V. The current flowing through the solar cell string 10 by calculating the difference value by comparing the lengths of the respective IV curves in all sections or in certain sections of the IV curves representing the voltages V _AB , V _BC , and V _CD between the solar cell strings. The magnitude difference between the voltages V _AB , V _BC , and V _CD between the strings of solar cells that changes with the size change of (I _AD ) is calculated.

In this case, when the graph analysis module 124 compares the lengths of the respective IV curves and calculates the difference value, the graph analysis module 124 sets one of the respective IV curves as the reference IV curve, and the other IV curves in the length of the set reference IV curve. It is preferable to calculate by subtracting length, respectively. Here, the graph analysis module 124 preferably sets the I-V curve having the maximum length among the I-V curves as the reference I-V curve.

In addition, when the graph analysis module 124 analyzes the graph by using a graph-based graph analysis algorithm, the graph analysis module 124 changes according to the magnitude of the current I _AD based on the current axis I or the voltage axis V. The area formed by each IV curve is calculated by integrating each IV curve in every section or a certain section of each IV curve representing the voltage (V _AB , V _BC , V _CD ) between the solar cell strings, and the calculated size of the area. By calculating the difference value by calculating the difference, it is to calculate the size difference between the voltage (V _AB , V _BC , V _CD ) between the strings of the solar cell that changes according to the magnitude change of the current (I _AD ) flowing in the solar cell string (10) do.

In this case, when the graph analysis module 124 calculates the magnitude difference value of the area formed by each IV curve, the graph analysis module 124 sets any one of the IV curves as the reference IV curve, and the rest of the area formed by the set reference IV curve. It is preferable to subtract the area formed by the IV curve, respectively. Here, the graph analysis module 124 preferably sets the I-V curve having the largest area among the respective I-V curves as the reference I-V curve.

For example, the magnitude difference between the voltages (V _AB , V _BC , V _CD ) between the strings of solar cells is calculated for each solar cell module by using graph analysis algorithms of point, line, and plane methods, and the sun according to the calculation result. When calculating the quality level for each battery module, it is as shown in FIG. Referring to Figure 4, a solar cell string between a voltage (V _AB, V _BC, V _CD) size, the greater the difference there is become larger the value representing the quality degree of the solar cell module, a solar cell string between a voltage (V _AB, V _BC between Since the smaller the size difference between the _CDs ), the higher the quality of the solar cell module is, the higher the numerical value representing the quality of the solar cell module, the lower the quality of the solar cell module.

The controller 120 may be, for example, a micro controller unit (MCU).

Meanwhile, the display unit 130 displays a graph in the form of an IV curve generated through the graph generation module 122 of the controller 120.

Quality inspection apparatus of the solar cell module according to the present invention is not limited to the above-described embodiment can be carried out in various modifications within the range allowed by the technical idea of the present invention.

5: bus bar 10: solar cell string
12: solar cell 20: load
30: terminal box 100: voltage measuring unit
110: current measuring unit 120: control unit
122: graph generation module 124: graph analysis module
126: quality calculation module 130: display unit
140: communication unit 150: input unit

Claims (8)

delete A voltage measuring unit measuring a voltage applied between the solar cell strings of the solar cell module; A current measuring unit measuring a current flowing in the solar cell string; Analyze the magnitude difference between the voltage between the solar cell string measured by the voltage measuring unit and the voltage between the solar cell string that changes according to the magnitude change of the current flowing through the solar cell string using the current measured by the current measuring unit It includes a control unit for calculating the degree of quality of the battery module,
The control unit may include a graph generation module configured to generate a magnitude change of a voltage between the solar cell strings according to a change in the magnitude of the current flowing in the solar cell string as a graph having an IV curve;
A graph analysis module configured to analyze a graph of an IV curve form generated by the graph generation module and calculate a magnitude difference between voltages of the solar cell strings that change according to the magnitude change of the current flowing in the solar cell strings;
And a quality calculation module for calculating a predetermined multiple of magnitude difference values between voltages of the solar cell strings calculated through the graph analysis module to a quality degree of the solar cell module.
The method of claim 2,
The graph analysis module,
Checking the quality of the solar cell module, characterized in that the graph of the IV curve form generated by the graph generation module is analyzed through a graph analysis algorithm (Algorithm) of the point (Point), line (Line) or plane (Dimension) method Device.
The method of claim 3,
The graph analysis module,
When the analysis is performed using a point-based graph analysis algorithm, voltage values on respective IV curves corresponding to current values in all sections or certain sections of each IV curve representing voltages between solar strings that change according to the magnitude of the current. Computing the difference value by comparing the magnitude of the difference, and by calculating the average value of the calculated difference value, it is characterized by calculating the magnitude difference between the voltage between the solar cell string that changes in accordance with the magnitude change of the current flowing through the solar cell string Quality inspection device of solar cell module.
The method of claim 3,
The graph analysis module,
In the case of the analysis using the linear graph analysis algorithm, the difference value is calculated by comparing the lengths of the IV curves in all sections or in certain sections of the IV curves representing the voltages between the strings of solar cells that change according to the magnitude of the current. By doing so, the magnitude difference between the voltages between the solar cell strings that change in accordance with the magnitude change of the current flowing in the solar cell strings, the quality inspection device of the solar cell module.
The method of claim 3,
The graph analysis module,
In the case of analysis using the planar graph analysis algorithm, each IV curve is formed by integrating each IV curve in all sections or a certain section of each IV curve representing the voltage between the strings of solar cells that change according to the magnitude of the current. Computing the area, and calculating the difference value by comparing the size of the calculated area, the size difference between the voltage between the solar cell string that changes in accordance with the magnitude change of the current flowing in the solar cell string Module quality inspection device.
The method according to any one of claims 2 to 6,
According to the control of the controller further comprises a display unit for displaying the magnitude difference between the quality of the solar cell module and the voltage difference between the voltage between the solar cell string changes according to the magnitude change of the current flowing in the solar cell string in the form of an IV curve. Quality inspection device of a solar cell module, characterized in that.
The method according to any one of claims 2 to 6,
The voltage measuring unit,
In order to sense the voltage between the strings of the solar cells constituting the solar cell module to contact each connection terminal configured in the terminal box installed in the solar cell module, or to contact both ends of each bypass diode connecting between each connection terminal Quality inspection apparatus of a solar cell module, characterized in that comprises a plurality of probes (Prove).

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