KR101801785B1 - A performance test apparatus for both sides electricity generating solar cell - Google Patents

Abstract

The present invention relates to a device for measuring the performance of a double-sided power generation solar cell, and more particularly, to a device for measuring the performance of a double-sided power generation solar cell, And more particularly, to a double-sided power generation solar cell performance measuring apparatus capable of increasing the accuracy and reliability of the double-sided performance measurement.
A power supply jig provided on the frame for supporting the double-sided power generation solar cell in close contact with both sides of the double-side power generation solar cell and energizing the current and voltage of the double-side power generation solar cell to the measurement unit; A second light source provided on the other side of the power supply jig for irradiating light to the rear surface of the double-side power generation solar cell and having a variable wavelength and light intensity; Surface power generation solar cell, and the light emitted from the second light source is transmitted through the back surface of the double-side power generation solar cell, or the light emitted from the first light source and transmitted through the double- And a light source reflecting member which is made of the same material as that of the back sheet of the solar cell module, to provide.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a double-

The present invention relates to an apparatus for measuring the performance of a double-sided power generation solar cell, and more particularly, to a system for measuring the performance of a double-side power generation solar cell having improved performance measurement on both sides of the solar cell, ≪ / RTI >

Recently, as concerns about environmental problems and energy depletion have increased, there is a growing interest in using solar energy as a substitute for energy, which has no problem of environmental pollution, has infinite resources, and is energy efficient.

Solar cells that utilize such solar energy can be divided into solar cells that generate the steam necessary to rotate the turbine using solar heat and solar cells that convert sunlight (photons) into electrical energy using the properties of semiconductors have.

Among them, research on a photovoltaic cell (hereinafter referred to as a "solar cell") that converts light energy into electric energy by absorbing light and generating electrons and holes is actively conducted.

Generally, such a solar cell generally includes a process for manufacturing a solar cell substrate such as a silicon wafer, a process for etching a substrate for a solar cell to form a pn junction, a process for forming a back junction and an antireflection film coating, And a test process of inspecting the performance and the performance of the manufactured solar cell.

Here, the test process for checking the quality and performance of the manufactured solar cell is performed by the solar cell test apparatus.

1 is a front view schematically showing an example of a conventional solar cell inspection apparatus.

When the solar cell 10 is brought into a space defined by a dark room 20, a probe electrically connected to an inspection unit (not shown) is connected to the terminal of the solar cell 10 And the at least one light source unit 30 installed on the upper side of the dark room irradiates the solar cell 10 with light, the inspection unit (not shown) irradiates the solar cell 10 with a current value and a voltage By measuring the value, the positive part and the electricity generation performance test of the solar cell 10 are carried out.

However, the conventional solar cell inspection apparatus has the following problems.

In the solar photovoltaic market, development and commercialization of double-sided power generation solar cells are progressing in order to develop the solar cell technology and improve the power generation performance.

In the case of a double-sided power generation solar cell, it is necessary to perform a performance test in consideration of the back incident light in addition to the performance measurement of the solar cell according to the front incident light as in the conventional technology described above. (1), there is a problem that it is impossible to accurately measure the performance of a double-side power generation solar cell.

2, in order to measure the performance of the double-sided power generation solar cell, one of the upper light sources 30 and one of the reflection sheet 40 on which the solar cell 10 is placed in the single- 3, and the light source 30 is provided on both sides of the solar cell 10, and in the simulator, the front light source 30 is set to 1 sun, And the second method of measuring the light source 30 by changing the intensity of light by about 1/3 of sun is used.

The first method is to measure the performance of the entire surface of the solar cell 10 using the light emitted from the light source 30 after the light source 30 is installed only above the solar cell 10, The light generated by the back surface of the solar cell 10 due to the light of the light source 30 transmitted through the reflection sheet 40 on which the solar cell 10 is placed is reflected to the back surface of the solar cell 10 , And the two-sided performance of the solar cell 10 is measured.

At this time, the reflection sheet 40 on which the solar cell 10 is placed is provided in several different reflectivities, and the performance of the back surface of the solar cell 10 according to the reflectivity is measured while replacing the reflection sheet 40.

However, in the first method, the measurement is performed without taking into account the material of the back sheet of the actual solar cell module, so that there is a problem that the accuracy of the performance measurement of the back surface of the solar cell 10 is low.

The back sheet constituting the back surface of the solar cell module may be made of various materials such as glass, synthetic resin, or metal. In this case, the reflection sheet 40 may be simply measured with different reflectivity without considering the characteristics of the back sheet material , There was a problem that it was difficult to increase the accuracy of measurement of the backside performance of the solar cell according to the back sheet material.

In the second method, a light source 30 having a different intensity of light is disposed above and below the solar cell 10, and the two-sided performance of the solar cell 10 using the light emitted from each light source 30 .

At this time, the light source 30 above the solar cell 10 replaces sunlight, and the light source 30 below the solar cell 10 replaces the light reflected from the bottom where the solar cell module is actually installed.

At this time, the intensity of the light source 30 disposed above the solar cell 10 is 1sun corresponding to the sunlight, and the intensity of the light source disposed below the solar cell 10 is 1 / The measurement is performed without considering the characteristics of the external environment in which the solar cell module is installed. In particular, it is difficult to increase the accuracy of the performance measurement of the solar cell backside.

That is, since the light source 30 irradiated to the front surface of the solar cell 10 is a light source considering the intensity of the sun, the light reflected to the rear surface of the solar cell 10 may have a wavelength and / However, it is difficult to increase the accuracy of measurement of the backside performance of the solar cell 10 by measuring the intensity of the light source arbitrarily set to 1/3 sun in a state where the actual environment is not considered.

Meanwhile, in order to increase the accuracy of the measurement of the two-sided performance of the double-side power generation solar cell, both the first method and the second method should be considered. However, the first method and the second method can not be performed by one equipment, There is a problem that it is difficult to increase the satisfaction of the measurer by causing the trouble of the measurement operation.

Korea Publication No. 10-2010-0009844

SUMMARY OF THE INVENTION The present invention has been made in order to solve the problems described above, and it is an object of the present invention to provide a solar cell capable of providing various measurement conditions similar to an environment in which a double- And an apparatus for measuring the performance of a double-sided power generation solar cell with high reliability.

It is another object of the present invention to provide a device for measuring the performance of a double-sided electric power generating gantry cell in which the measurement operation using the various measurement conditions described above can be performed in one device, thereby improving the convenience of the measurement operation.

In order to achieve the above-described object, the present invention provides a solar cell module comprising: a frame; a frame mounted on the frame, which supports the double-sided power generation solar cell in close contact with both surfaces of the double-sided power generation solar cell, A first light source provided on one side of the power supply jig for irradiating light to the front surface of the double-side power generation solar cell, a second light source provided on the other side of the power supply jig for irradiating light to the rear surface of the double- A second light source which is capable of varying the light emitted from the first light source, a second light source which is arranged between the second light source and the double-side power generation solar cell, and which transmits the light irradiated from the second light source to the rear surface of the double- A light source reflecting member which is made of the same material as that of the back sheet of the solar cell module so as to reflect the light transmitted through the battery to the back surface of the double- Thereby providing a power generation solar cell performance measuring device.

At this time, the battery cell is composed of a first energizing jig and a second energizing jig which are respectively in contact with both surfaces of a double-sided power generation solar cell, and the frame has a first opening hole with both sides opened to allow light of the second light source to pass therethrough A first frame hinged to one side of the first frame and pivoted toward the first frame, the first frame including a plurality of first conductive jigs across the first opening, And a second frame formed with a plurality of second electrifying jigs across the second opening and forming a second opening hole having an opening.

Also, a light source reflector mounting portion in which a light source reflector is mounted is provided between the second light source and the frame, and the light source reflector attachment portion forms an aperture hole so that a second light source below the light source is passed, It is preferable that the light source is mounted so as to correspond to the aperture of the light source reflecting member mounting portion.

Further, it is preferable that a jig is formed on a surface opposite to the double-sided power generation solar cell so that the adhesion of the one or more current-carrying jigs to the double-side power generation solar cell is enhanced.

The apparatus for measuring the performance of a double-side power generation solar cell according to the present invention has the following effects.

First, a light source reflection member made of a material used as a back sheet of an actual solar cell module can be provided at a portion corresponding to the back surface of the solar cell, so that the performance measurement on the rear surface of the solar cell module in a state suitable for the actual installation environment .

Accordingly, there is an effect that the accuracy and reliability of the performance measurement on the back surface of the solar cell can be increased.

Secondly, the light source irradiating the rear surface of the solar cell is provided as a light source that can change the wavelength and intensity, so that the light value similar to the reflectance of the bottom installed on the solar cell module is adjusted, It is possible to increase the accuracy and reliability of the performance measurement on the back surface of the solar cell.

Third, since the measurement conditions similar to the actual environment can be considered in a single equipment, the convenience of measuring the performance of the double-sided solar cell can be improved.

1 is a conceptual view showing a conventional single-sided power generation type solar cell inspection apparatus
2 is a conceptual diagram showing a state in which a reflection paper is provided on a conventional single-sided power generation type solar cell inspection apparatus to measure the performance of the back surface of the solar cell
FIG. 3 is a conceptual diagram illustrating a state in which the light sources are provided on both sides of a conventional single-sided power generation type solar cell inspection apparatus to measure the performance of both solar cells
4 is a conceptual diagram illustrating a device for measuring the performance of a double-side power generation solar cell according to a preferred embodiment of the present invention.
5 is a schematic view showing a device for measuring the performance of a double-side power generation solar cell according to a preferred embodiment of the present invention
6 is a perspective view of a device for measuring the performance of a double-side power generation solar cell according to a preferred embodiment of the present invention.
7 is a front view showing an apparatus for measuring the performance of a double-side power generation solar cell according to a preferred embodiment of the present invention

It is to be understood that the words or words used in the present specification and claims are not to be construed in a conventional or dictionary sense and that the inventor can properly define the concept of a term in order to describe its invention in the best possible way And should be construed in light of the meanings and concepts consistent with the technical idea of the present invention.

Hereinafter, an apparatus for measuring the performance of a double-side power generation solar cell according to a preferred embodiment of the present invention will be described with reference to FIGS.

The double-sided power generation solar cell performance measuring device is configured to allow a light source reflecting member of the same material as the back sheet to be positioned at a position corresponding to the rear surface of the solar cell to be measured and measure the intensity of the light source irradiated to the rear surface of the solar cell And the wavelength can be controlled.

As a result, the accuracy and reliability of the performance measurement of the double-sided power generation solar cell can be enhanced since the measurement conditions can be provided in the actual use and installation and environment.

4 and 5, the apparatus for measuring the performance of a double-sided power generation solar cell comprises a first light source 100, a second light source 200, a light source reflecting member 300, 400).

The first light source 100 irradiates the front surface of the solar cell S to measure the front surface performance of the solar cell S. The first light source 100 is installed at a position corresponding to the front surface of the solar cell S.

At this time, since the front surface of the solar cell S faces upward, the first light source 100 is installed above the solar cell S.

Since the front surface of the solar cell S is a site where sunlight is actually irradiated, it is preferable that the first light source 100 corresponds to the intensity and wavelength of sunlight.

Accordingly, the first light source 100 may be provided with a constant wavelength and intensity.

For example, the first light source 100 may be a xenon lamp, a halogen lamp, or the like having the same wavelength and intensity as solar light.

Next, the second light source 200 irradiates light to the rear surface of the solar cell S, and is installed at a position corresponding to the rear surface of the solar cell S.

Since the rear surface of the solar cell S faces downward, the second light source 200 is installed below the solar cell S.

The second light source 200 corresponds to the light irradiated to the rear surface of the solar cell S by reflecting the sunlight on the bottom of the solar cell module, The wavelength and intensity of the second light source 200 should also be controlled by the control unit C, since the intensity and wavelength of the reflected light are all different.

That is, the place where the solar battery module is installed may be various such as land, concrete, water surface, etc., and the wavelength and intensity of sunlight reflected on the land, concrete, The wavelength and the intensity should be set so as to be variable.

In this case, it is preferable that the second light source 200 is provided as an LED whose color, wavelength, and intensity can be relatively easily controlled.

Next, the light source reflecting member 300 serves to improve the accuracy of the performance measurement of the rear surface of the solar cell S by the light reflected on the back surface of the solar cell S, corresponding to the back sheet constituting the rear surface of the solar cell module , And between the second light source (200) and the solar cell (S).

That is, the sunlight irradiates the entire surface of the solar cell S to form a current and a voltage on the entire surface of the solar cell S. However, after the solar cell S passes through the solar cell S, The back surface of the solar cell S is reflected from the back sheet to form current and voltage on the back surface of the solar cell S. Therefore, The light source reflecting member 300 is formed.

At this time, in order to improve the accuracy of the performance measurement of the back surface of the solar cell S using the light source reflection member 300, the material of the light source reflection member 300 is made of the same material as that of the back sheet used in the actual solar cell module .

For example, the light source reflecting member may be a material used for a back sheet such as glass, metal, or synthetic resin.

At this time, it is preferable that the shape of the light source reflection member 300 is a flat plate shape.

Next, the light-source reflector mounting portion 400 is disposed between the solar cell S and the second light source 200, in which the light-source reflecting member 300 is disposed.

In this case, the light source reflector mounting part 400 is preferably provided in the form of a panel on which the light source reflecting member 300 can be placed. In the center of the light source reflecting member mounting part 400, S are formed so as to be able to be irradiated toward the upper and lower surfaces of the substrate W.

Meanwhile, a configuration for fixing the solar cell to be measured and fixing the solar cell to the double-sided power generation solar cell performance measuring apparatus having such a configuration will be described in detail with reference to FIGS. 6 and 7. FIG.

A structure for fixing the solar cell S includes a frame 500 and a power supply jig 600.

The frame 500 constitutes a frame for fixing the solar cell S and comprises a first frame 510 and a second frame 520.

The first frame 510 provides a space in which the solar cell S is seated and corresponds to the second light source 200.

The first frame 510 forms a first aperture 511 that is opened upward and downward so that the light of the first light source 100 is directed toward the light source reflecting member 300 through the first aperture 511 Or the light of the second light source 200 is transmitted toward the solar cell S.

At this time, on both sides of the front end of the first frame 510, a seating bar 512 on which the front end of the second frame 520 is seated is preferably installed upward.

A guide bar 513 for guiding the position of the solar cell S is provided at the side end and the rear end of the first frame 510, respectively.

The guide bar 513 is configured to guide the position of the solar cell S so that the solar cell S can accurately correspond to the first aperture 511. The guide bar 513 has a structure in which the end portion of the guide bar 513 The position of the solar cell S can be guided to the first opening 511. [

At this time, it is preferable that the guide bar 513 is configured to be variable in length so as to correspond to the size of the solar cell S.

For example, as shown in FIG. 6, the length of the guide bar 513 can be adjusted while the guide bar 513 is moved forward and backward through screw tightening.

A hook 514 for restricting the rotation of the second frame 520 is provided at the center of the front end of the first frame 510.

The second frame 520 covers the solar cell S mounted on the first frame 510 and is hinged to the rear end of the first frame 510 so as to be rotatable.

At this time, a second opening 521 corresponding to the first opening 511 of the first frame 510 is formed at the center of the second frame 520.

The second opening 521 is a path through which the light of the first light source 100 is directed toward the solar cell S.

A hook groove 522 is formed at the front end of the second frame 520 so that the hook 514 of the first frame 510 can be caught and fixed.

Next, the energizing jig 600 supports the solar cell S positioned between the first frame 510 and the second frame 520, and the solar cell S, which is produced in the solar cell S by the light of the light source, Current and voltage to the measuring unit.

The electrification jig 600 is composed of a first electrification jig 610 provided in the first frame 510 and a second electrification jig 620 provided in the second frame 520.

The first electrification jig 610 has a configuration in which the rear surface of the solar cell S is seated and is provided in plural across the first opening 511 of the first frame 510.

The second energizing jig 620 has a configuration in which the front surface of the solar cell S is in close contact with the second solar cell S and is provided across the second opening 521 of the second frame 520.

At this time, the installation direction of the first electrification jig 610 and the second electrification jig 620 is preferably the same.

Meanwhile, it is preferable that a gear 700 is formed on at least one of the first electrification jig 610 and the second electrification jig 620.

The gear 700 is formed on the surface of the end portion of the electrification jig 600 facing the solar cell S to increase adhesion with the solar cell S. [

In this specification, it is assumed that the gear 700 is formed in the second electrification jig 620.

Hereinafter, a process of measuring the performance of a double-side power generation solar cell using the apparatus for measuring the performance of a double-side power generation solar cell having the above-described configuration will be described.

The solar cell S to be measured is placed on the first electrification jig 610. [

At this time, the side end portion and the rear end portion of the solar cell S are guided by the guide bar 513.

The rear surface of the solar cell S is in close contact with the first conductive jig 610, and the front surface of the solar cell S faces upward.

Next, the second frame 520 is rotated to cover the entire surface of the solar cell S.

At this time, the gear 700 of the second electrification jig 620 is in close contact with the front surface of the solar cell S, and the hook 514 is engaged with the hook groove 522, S is completed.

Next, the light source reflecting member 300 is placed on the light source reflecting member mounting portion 400.

At this time, the light source reflection member 300 is the same material as the back sheet of the solar cell module in which the solar cell S to be measured is installed. The light source reflection member 300 can be selected by the user depending on the situation such as glass, metal,

Next, the light of the first light source 100 is irradiated toward the solar cell S.

At this time, the light of the first light source 100 is irradiated toward the front surface of the solar cell S through the second opening 521 of the second frame 520.

At this time, a current is formed on the front surface of the solar cell S by the light irradiated to the front surface of the solar cell S, and the current is passed through the second energizing jig 620 to the measuring unit, ) Is performed.

The light emitted by the first light source 100 not only irradiates the entire surface of the solar cell S but also reflects the light emitted from the light source reflected at the lower side of the solar cell S Member 300 is irradiated.

At this time, the irradiated light is reflected from the light source reflecting member 30 to the rear surface of the solar cell S.

As described above, as the light from the first light source 100 is reflected to the rear surface of the solar cell S, a current is formed on the rear surface of the solar cell S, and the current flows through the first conductive jig 610, The solar cell backside performance measurement is made.

At this time, since the reflectivity of the light source reflector 300 is the same as that of the actual solar cell module, the accuracy of the performance measurement of the solar cell backside is high.

On the other hand, the performance of the back surface of the solar cell using the second light source 200 can be measured.

The second light source 200 directly irradiates the rear surface of the solar cell S to form a current on the rear surface of the solar cell S and adjusts the intensity and wavelength of the light to irradiate the rear surface.

The second light source 200 is a light source that replaces the wavelength and intensity of light reflected by the sunlight from the floor where the solar cell module is actually installed. The second light source 200 is a floor (ground, concrete, water surface) The intensity and wavelength of the sunlight reflected from the first light source 200 and the intensity and wavelength of the second light source 200 should be controlled to be equal to each other.

At this time, the data of the intensity and the wavelength value of the sunlight reflected from the bottom of each installation place are collected using a separate measuring device.

The light irradiated from the second light source 200 is transmitted through the opening hole 410 of the light source reflecting member mounting portion 400 to the back surface of the solar cell S through the light source reflecting member 300 , A current is formed on the rear surface of the solar cell S by the irradiated light.

At this time, the current is passed through the second energizing jig 620 to the measuring unit, so that the performance measurement of the rear surface of the solar cell by the second light source 200 is completed.

In measuring the performance of the rear surface of the solar cell S using the second light source 200, the light source reflector 300 mounted on the light source reflector mounting portion 400 may be removed and the measurement may be performed.

The first light source 100 and the second light source 200 may both emit light to measure the solar cell performance. The first light source 100 and the second light source 200 emit light, You may.

This is for considering various measurement conditions, and it is possible to improve the accuracy of measurement of the performance of the solar cell through the progress of measurement according to consideration of various measurement conditions.

By providing the conditions of the light source reflecting member 300 of various materials including the light sources 100 and 200 to the solar cell S fixed to the frame 500 as described above, it is possible to improve the accuracy of the measurement of the two- , It is possible to improve the convenience of the measurement operation by performing performance measurement taking into consideration various conditions with only one equipment.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art.

100: first light source 200: second light source
300: light source reflecting member 400: light source reflecting member mount
410: aperture ball 500: frame
510: first frame 511: first aperture
512: seat bar 513: guide bar
514: hook 520: second frame
521: second opening hole 522: hook groove
600: energizing jig 610: first energizing jig
620: second energizing jig 700: gear

Claims (4)

frame;
A power supply jig which is installed in the frame and is in close contact with both surfaces of the double-sided power generation solar cell to support the double-sided power generation solar cell and energizes the current and voltage of the double-
A first light source provided on one side of the power supply jig and irradiating light to the entire surface of the double-side power generation solar cell;
A second light source provided on the other side of the power supply jig and irradiating light to a rear surface of the double-side power generation solar cell, the wavelength and the intensity of light being variable;
Surface power generation solar cell, and the light emitted from the second light source is transmitted through the back surface of the double-side power generation solar cell, or the light emitted from the first light source and transmitted through the double- And a light source reflecting member, which is made of the same material as that of the back sheet of the solar cell module, is provided on the rear surface of the solar cell. The method according to claim 1,
Wherein said passage battery comprises a first energizing jig and a second energizing jig which are respectively in close contact with both surfaces of a double-
The frame includes:
A first frame forming a first opening having openings at both sides thereof to allow light from the second light source to pass therethrough, the first frame having a plurality of first conductive jigs across the first opening;
A plurality of second conductive plugs hinged to one side of the first frame and pivoted toward the first frame to form a second aperture hole having both open sides through which the light of the first light source passes, And a second frame provided with the first frame and the second frame. 3. The method according to claim 1 or 2,
A light source reflector mounting portion on which a light source reflector is mounted is provided between the second light source and the frame,
Wherein the light-source-reflecting-member mounting portion forms an aperture hole so that a second light source in a downward direction passes,
Wherein the light source reflecting member is seated so as to correspond to the opening of the light source reflecting member mounting portion. 3. The method according to claim 1 or 2,
Wherein at least one of the electrification jigs is provided with a gear on a surface facing the double-sided power generation solar cell so as to enhance adhesion to the double-sided power generation solar cell.

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