KR101447919B1 - Solar cell module comprising test cell, solar cell module testing apparatus and testing method using the same - Google Patents

Abstract

The present invention relates to a solar cell module comprising a test cell and a solar cell module testing apparatus and a testing method using the same. The solar cell module comprising a test cell, of the present invention, comprises: a plurality of solar cells for receiving light to generate electric current; and a test cell which is located at one end of the solar cell and generates current by receiving the light to test the plurality of solar cells. According to the present invention, by having a separate test cell in the solar cell module through a patterning process, a test for the degree of stabilization for each solar cell module can be performed even the plurality of solar cell modules are overlapped, thereby a time needed for testing the degree of stabilization for the solar cell module can be reduced.

Description

TECHNICAL FIELD [0001] The present invention relates to a solar cell module having a test cell, a solar cell module testing apparatus using the solar cell module,

The present invention relates to a solar cell module having a test cell, a solar cell module testing apparatus and a testing method using the same, and more particularly, to a solar cell module having a test cell capable of testing physical properties of the solar cell module, A test apparatus capable of testing the solar cell module, and a test method.

Solar cells are devices that convert solar energy directly into electrical energy, and are used in a variety of fields, from small electronic devices to large-scale power generation. Such a solar cell has various kinds depending on the material, and is mainly used in a module form.

The CIGS solar cell module is fabricated by sequentially depositing a substrate, a back electrode, a light absorbing layer, a buffer layer, a transparent electrode, and an antireflection film, and is divided into a plurality of solar cells through a patterning process. Such a plurality of solar cells is formed continuously in one direction. In addition, electric terminals connected to the outside are provided at both ends of the solar cell so that the current generated in the cell flows to the adjacent solar cell and is output to the outside.

The stability test of the solar cell module thus manufactured is carried out by various methods such as Korean Patent Laid-Open No. 10-2012-0119361 (solar cell and its manufacturing method, published on Oct. 31, 2012, precedent) have. However, as in the prior art, there is a problem that the stabilization degree test of the solar cell module requires a long time for the stabilization degree test because only one solar cell module is tested at a time.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and provides a solar cell module having a test cell, a solar cell module test apparatus and a test method using the same, so as to reduce the time required for the stability test of the solar cell module There is a purpose.

In order to achieve the above object, a solar cell module provided with a test cell according to the present invention includes: a plurality of solar cells; And a test cell located at one end of the solar cell and generating light by receiving light for testing the plurality of solar cells.

At this time, it is preferable that the plurality of solar cells are formed by arranging the solar cells continuously formed in one direction in parallel and the test cells are formed at one end of the plurality of solar cells in a shape continuously formed in one direction And the test cell is electrically separated from the plurality of solar cells.

The solar cell and the test cell may be manufactured using a CIGS (CuInGaSe ₂ ) compound.

In order to achieve the above object, a solar cell module testing apparatus of the present invention includes a plurality of solar cells for generating current by receiving light to generate a current for testing the plurality of solar cells, A solar cell module holder for holding a plurality of solar cell modules provided with test cells; A light source for irradiating the plurality of solar cell modules with light; And a measuring unit electrically connected to the plurality of solar cell modules and measuring a degree of stabilization of the plurality of solar cell modules, wherein each of the plurality of test cells is exposed to the light source, Modules are stacked and mounted.

At this time, it is preferable that the plurality of solar cells are formed by arranging the solar cells continuously formed in one direction in parallel and the test cells are formed at one end of the plurality of solar cells in a shape continuously formed in one direction And the test cell is electrically separated from the plurality of solar cells.

The solar cell and the test cell may be manufactured using a CIGS (CuInGaSe ₂ ) compound.

It is also preferable that the remaining part of the solar cell module is covered with a covering plate so that only the test cell is exposed to the light source in the solar cell module located at the uppermost position of the plurality of solar cell modules.

According to another aspect of the present invention, there is provided a solar cell module testing apparatus comprising: a plurality of solar cell modules formed in parallel in a row, Mounted solar cell module mount; A light source for irradiating the plurality of solar cell modules with light; And a measuring device electrically connected to the plurality of solar cell modules and measuring a degree of stabilization of the plurality of solar cell modules, wherein a part of the plurality of solar cell units is exposed to the light source, And a plurality of solar cell modules are stacked and mounted.

In order to achieve the above object, a method of testing a solar cell module according to the present invention is a method for testing a plurality of solar cell cells at one end of a plurality of solar cell cells generating light by receiving light, A plurality of solar cell modules provided with cells are overlapped and mounted on a solar cell module holder; A second step of irradiating a plurality of the overlapped solar cell modules with light; And measuring the current generated in the test cell in order to measure the degree of stabilization of the plurality of solar cell modules. In the first step, the plurality of solar cell modules are stacked so that only each of the test cells is exposed to light .

At this time, it is preferable that the plurality of solar cells are formed by arranging the solar cells continuously formed in one direction in parallel and the test cells are formed at one end of the plurality of solar cells in a shape continuously formed in one direction And the test cell is electrically separated from the plurality of solar cells.

According to another aspect of the present invention, there is provided a method for testing a solar cell module, the method comprising: a plurality of solar cell modules formed in parallel in a plurality of solar cells, Step 1, which is stacked on the solar cell module holder; A second step of irradiating a plurality of the overlapped solar cell modules with light; And measuring the current generated in the test cell in order to measure the degree of stabilization of the plurality of solar cell modules. In the first step, the plurality of solar cell modules are stacked so that only each of the test cells is exposed to light .

In addition, in the solar cell module located at the uppermost position of the plurality of solar cell modules, the remaining portions may be covered with a covering plate so that only a part of each of the plurality of solar cells is exposed to the light source.

According to the present invention, since independent test cells are provided in the solar cell module through the patterning process, the stabilization degree test can be performed for each solar cell module even if the plurality of solar cell modules are stacked so as to overlap with each other. There is an effect. It also has the effect of drastically lowering the power required for testing.

1 is a perspective view illustrating a solar cell module having a test cell according to the present invention.
2 is a cross-sectional view illustrating a solar cell module having a test cell according to the present invention.
3 is a block diagram showing a solar cell module testing apparatus of the present invention.
FIG. 4 is a view showing a solar cell module stacked when testing a plurality of solar cell modules according to the present invention. FIG.
5 is a view showing a solar cell module stacked in a different manner when testing a plurality of solar cell modules according to the present invention.
FIG. 6 is a view showing a solar cell module stacked in another manner when testing a plurality of solar cell modules according to the present invention. FIG.

Preferred embodiments of the present invention will be described more specifically with reference to the accompanying drawings.

1, a solar cell module testing apparatus 100 having a test cell 220 according to the present invention includes a solar cell module 200 having a test cell 220, . As shown in FIG. 3, the solar cell module 100 includes a solar cell module holder 110, a light source 120, and a measuring device 130.

A plurality of solar cell modules 200 are mounted on a solar cell module mount 110 at one time, and the solar cell module 200 is configured to mount dozens of solar cell modules 200 as needed. 1, the solar cell module 200 equipped with the test cell 220 is mounted without the general solar cell module 200 being mounted on the solar cell module 110 mounted on the solar cell module mount 110 .

The solar module module holder 110 may be formed in various shapes to mount the solar cell module 200. For example, a plurality of grooves may be formed to slide and mount the plurality of solar cell modules 200 have. At this time, the solar cell module 200 is mounted on the solar cell module cradle 110 as if the drawer 110 is inserted into a drawer. The plurality of grooves formed in the solar cell module holder are formed such that the solar cell module 200 that is sandwiched at the lowest point at which the solar cell module 200 can be inserted is protruded from the other solar cell modules 200.

That is, the solar cell module 200 inserted at the uppermost end of the plurality of grooves formed in the solar cell module mount 110 is inserted into the grooves at the deepest and the solar cell module 200 sandwiched at the second upper end is inserted into the test cell 220 The solar cell module 200 is inserted into the groove at a lower position than the solar cell module 200 at the uppermost position. Therefore, when light is irradiated from an upper light source, the solar cell module 200 located at the uppermost stage covers the solar cell 210 of the second solar cell module 200 to generate current in the solar cell 210 The test cell 220 may be exposed to a light source to generate a current.

The remaining solar cell modules 200 are sequentially inserted into the remaining grooves like the second solar cell module 200 so that only the test cells 220 of the respective solar cell modules 200 are exposed to the light source 110).

In addition to the above-described shape, the solar cell module holder 110 may have a plurality of stepped shapes at one end of the plate on which the solar cell module 200 can be placed. The test cell 220 is exposed to the light source and the plurality of solar cell modules 200 are overlapped with each other so that the solar cell module 200 is mounted on the solar cell module mount 110).

At this time, the height of one step of the staircase is formed at the height of one solar cell module 200, and the width of one step is formed to have the same width as the width of the test cell 220. Therefore, when the solar cell module 200 is mounted on the solar cell module holder 110 so as to be in close contact with the step shape, only the test cells 220 among the plurality of overlapping solar cell modules 200 are naturally exposed to the light source So that the solar cell module 200 can be mounted.

The solar cell module 200 provided with the test cell 220 of the present invention is further provided with a test cell 220 for testing at one end of a conventional thin film solar cell module 200. The test cell 220 receives light in the same manner as the other solar cell 210, and current is generated. When one solar cell module 200 is manufactured, the test cell 220 is manufactured in the same process.

Even so, the test cell 220 does not refer to the test cell 220 as a solar cell 210 located at one end of the solar cell 210 formed in the solar cell module 200, Likewise, it is manufactured so as to be independent from other solar cell 210 without being electrically connected thereto.

2, the plurality of solar cells 210 formed on the solar cell module 200 electrically connect the adjacent solar cells 210 with molybdenum (Mo) used as the rear electrode 202, , The test cell 220 is not electrically connected to another adjacent solar cell 210. That is, when the solar cell module 200 is manufactured, the rear electrode 202 of the test cell 220 is electrically connected to the adjacent solar cell 210 through the rear electrode 202, 210). ≪ / RTI >

2, the solar cell module 200 according to the present invention includes a back electrode 202, a light absorbing layer 203, a buffer layer 204, a transparent electrode 205, and an antireflection film on a substrate 201, The thin film solar cell module 200 which is sequentially deposited is used, and the light absorption layer 203 receives CIGS (CuInGaSe ₂ ) compound as a region that generates light by generating electron-hole pairs by receiving light.

Therefore, the test cell 220 operates independently from the other solar cell 210. [ Therefore, both ends of the test cell 220 in the longitudinal direction are electrically connected to the measuring device 130 separately from the other solar cell 210. For this purpose, terminals for electrical connection with the measuring device 130 may be formed at both ends of the test cell 220.

As shown in FIG. 4, the solar cell module 200 having the test cell 220 is mounted on the solar cell module mount 110 in a state where a plurality of the solar cell modules 200 are overlapped with each other. At this time, when the plurality of solar cell modules 200 are stacked, the solar cell modules 200 are stacked so that the test cells 220 are exposed to the light source 120, (110).

A cover plate P covering the remaining solar cell 210 is placed on the uppermost solar cell module 200 so that only the test cell 220 is exposed to the light source 120. Therefore, the solar cell module 200 located at the uppermost position is also exposed to the light source 120 alone.

The test cell 220 of each solar cell module 200 is exposed to the light source 120 and receives light from the test cell 220 because the solar cell module 200 is mounted on the solar cell module mount 110 A current is generated. The current generated in the test cell 220 is transmitted to the measuring device 130 to measure the degree of stabilization of the test cell 220 in the measuring device 130.

To this end, the light source 120 irradiates light toward the solar cell module holder 110.

The measuring device 130 is electrically connected to the test cells 220 of the plurality of solar cell modules 200 mounted on the solar cell module cradle 110 and receives light from the light source 120 to receive the test cell 220, And the degree of stabilization of the test cell 220 is measured.

The degree of stabilization of the test cell 220 measured by the measuring device 130 may be regarded as the degree of stabilization of the solar cell module 200 provided with the test cell 220. This is because when the solar cell module 200 is manufactured, the test cell 220 is manufactured together and the back electrode 202 is separated from the other solar cell 210 and electrically independent of each other. This is because it is free.

As described above, since a plurality of solar cell modules 200 are mounted on the solar cell module mount 110, in order to test a plurality of the solar cell modules 200, the entire solar cell module 200 is unfolded to be exposed to light You do not have to leave. Therefore, the size of the light source 120 does not need to be larger than the size of the solar cell module 200, and the light source 120 may be used to irradiate only the exposed test cell 220, It is possible to measure the degree of stabilization of the liquid crystal panel 200.

5, the solar cell module 200 is mounted on the solar cell module holder 110 of the solar cell module testing apparatus 100 of the present invention, It is possible to mount the solar cell module 200 as shown in FIG.

5, a plurality of solar cell modules 200 are staggeredly mounted on the solar cell module cradle 110 so that a part of the solar cell cells 210 are exposed to the light source 120. As shown in FIG. The uppermost solar cell module 200 also includes a plurality of solar cell modules 200 mounted on the solar cell module base 110 with the shielding plate P placed so that only a part of the solar cell 210 is exposed to the light source 120. [ .

At this time, a part of the solar cell 210 exposed to the light source 120 exposes a part of each solar cell 210, and receives light only in the exposed solar cell 210 to generate a current. The measuring device 130 measures a current generated in each of the exposed solar cells 210 and confirms the degree of stabilization of the corresponding solar cell module 200.

In this case, the test cell 220 may not be separately provided in the solar cell module 200. In this case, since a part of the solar cell 210 of each solar cell module 200 is exposed to the light source 120, the degree of stabilization of each solar cell 210 can be directly measured.

6, the solar cell module 200 may be staggeredly mounted on the solar cell module mount 110 such that a part of the solar cell 210 and the test cell 220 are exposed to the light source 120 . 4 and 5, only the test cell 220 and a part of each solar cell 210 are exposed to the light source 120 by using the shielding plate P in the uppermost solar cell module 200, . In this case, the degree of stabilization is measured using the solar cell module 200 provided with the test cell 220, which has been described with reference to FIG.

In this case, the measuring device 130 is electrically connected to the test cell 220 and electrically connected to the solar cell 210, respectively. At this time, the measuring device 130 measures the measured value measured in the test cell 220 and the measured value measured when a part of the solar cell 210 is exposed to light in one solar cell module 200 . Therefore, the measured two measured values can be used as an indicator for determining the degree of stabilization of the solar cell module 200.

As described above, a method of measuring the degree of stabilization of the solar cell module 200 using the solar cell module 200 provided with the test cell 220 is as follows. First, a plurality of solar cell modules 200 are mounted on a solar cell module platform 110 in a state where a plurality of solar cell modules 200 are overlapped with each other, as in any of the drawings shown in FIGS. In this state, light is irradiated to the test cell 220 or the solar cell 210 of each of the exposed solar cell modules 200 using the light source 120, and the test cell 220 is irradiated with the light, Or the current generated in the solar cell 210 is measured.

At this time, the degree of stabilization of the solar cell module 200 can be confirmed by using the measured current.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It should be understood that the scope of the present invention is to be understood as the scope of the following claims and their equivalents.

100: solar cell module test apparatus 110: solar cell module holder
120: light source 130: measuring instrument
200: solar cell module 210: solar cell
220: test cell 201: substrate
202: rear electrode 203: light absorbing layer
204: buffer layer 205: transparent electrode
P: Cover plate

Claims (20)

delete delete delete delete 1. A solar cell module comprising: a plurality of solar cell modules mounted on one end of a plurality of solar cells for receiving light and generating test cells for receiving current and generating current for testing the plurality of solar cells;
A light source for irradiating the plurality of solar cell modules with light; And
And a measuring device electrically connected to the plurality of solar cell modules and measuring the degree of stabilization of the plurality of solar cell modules,
Wherein the plurality of solar cell modules are stacked and mounted on the solar cell module holder so that only each of the test cells is exposed to the light source. The method of claim 5,
The solar cell module is formed by arranging solar cell cells formed continuously in one direction in parallel,
Wherein the test cells are formed at one end of the plurality of solar cells in a shape continuously formed in one direction. The method of claim 5,
Wherein the test cell is electrically isolated from the plurality of solar cells. The method of claim 5,
Wherein the measuring device is electrically connected to both ends of the test cell. The method of claim 5,
The solar cell module is the solar cell module, the test device characterized in that the manufacturing CIGS (CuInGaSe ₂₎ compound is used. The method of claim 5,
Wherein only the test cell is exposed to the light source in the solar cell module located at the uppermost stage where the plurality of solar cell modules are overlapped, and the remaining portion is covered with the shielding plate. 1. A solar cell module comprising: a plurality of solar cell modules mounted in parallel on a plurality of solar cells arranged in parallel;
A light source for irradiating the plurality of solar cell modules with light; And
And a measuring device electrically connected to the plurality of solar cell modules and measuring the degree of stabilization of the plurality of solar cell modules,
Wherein the plurality of solar cell modules are stacked and mounted on the solar cell module holder so that a part of the plurality of solar cell cells is exposed to the light source. The method of claim 10,
Wherein a plurality of solar cell modules are overlapped and a remaining portion of the plurality of solar cell modules is covered with a shielding plate so that only a part of each of the plurality of solar cell portions is exposed to the light source. A plurality of solar cell modules having a test cell for receiving a light and generating a current to test a plurality of solar cell cells are stacked on a solar cell module holder Stage 1;
A second step of irradiating a plurality of the overlapped solar cell modules with light; And
And measuring the current generated in the test cell to measure the degree of stabilization of the plurality of solar cell modules,
Wherein the plurality of solar cell modules are overlapped to expose only the respective test cells in the first step. 14. The method of claim 13,
The solar cell module is formed by arranging solar cell cells formed continuously in one direction in parallel,
Wherein the test cells are formed at one end of the plurality of solar cells in a shape continuously formed in one direction. 14. The method of claim 13,
Wherein the test cell is electrically isolated from the plurality of solar cells. 14. The method of claim 13,
Wherein the third step is performed by a measuring device electrically connected to both ends of the test cell. 14. The method of claim 13,
The solar cell module CIGS (CuInGaSe ₂₎ compound is used method the solar cell module, it characterized in that the test is made. 14. The method of claim 13,
Wherein the test cell is exposed to the light source in the solar cell module located at the uppermost stage where the plurality of solar cell modules are overlapped, and the remaining portion is covered with the closure plate. delete delete

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