CN111865217A - Double-sided photovoltaic cell testing device - Google Patents

Abstract

The invention discloses a double-sided photovoltaic cell testing device, which comprises a solar simulator, a testing power supply, a cell bracket, a mirror reflection plate, a reflection cover and a darkroom, wherein the cell bracket is used for mounting a double-sided photovoltaic cell and is connected with the testing power supply; the solar simulator is positioned right in front of the front side of the double-sided photovoltaic cell, the mirror reflection plate is arranged behind the double-sided photovoltaic cell, and part of radiation of the solar simulator is collected and reflected into the reflection cover; the reflector is arranged right behind the back of the double-sided photovoltaic cell, and the inner surface of the reflector is parabolic. The invention enables the front side and the back side of the double-sided photovoltaic cell to be radiated by light simultaneously during testing, measures the overall electrical performance of the double-sided photovoltaic cell, and eliminates the deviation of a test result caused by two-step test fitting.

Description

Double-sided photovoltaic cell testing device

Technical Field

The invention relates to the technical field of photovoltaic cell power testing, in particular to a double-sided photovoltaic cell testing device.

Background

Along with the gradual approach of the flat price on-line, high-efficiency power generation technologies such as double-sided photovoltaic cells and the like are gradually started. Due to the power generation characteristics of the bifacial photovoltaic cell, there is output from both the front and back sides. The existing method can only measure the single-side power of the photovoltaic cell once when testing the photovoltaic cell, and can only measure one side of the photovoltaic cell every time when testing the double-side photovoltaic cell, and the measurement needs to be carried out twice, then the total output power of the double-side photovoltaic cell is calculated through formula fitting, and the test result has certain deviation with the actual output power of the double-side photovoltaic cell.

How to accurately calibrate the power of the double-sided photovoltaic cell becomes a current difficulty, which causes great divergence in power calibration of buyers and sellers, and restricts the commercialization route of the product; in addition, the final nominal value of the power of the double-sided photovoltaic cell directly influences the system design of a terminal power station, and serious fire hazards and the like can be caused due to improper design. In the actual power generation of the bifacial photovoltaic cell, the irradiance of the back surface cannot reach the intensity in the standard state. And because of the weak light effect of the silicon material battery, the power of the photovoltaic battery does not change linearly with the light intensity, so the power of the double-sided photovoltaic battery measured by the measuring method has a certain error with the actual work of the double-sided photovoltaic battery. Therefore, how to provide a test method for improving the power accuracy of the double-sided photovoltaic cell becomes a problem to be solved urgently in the field.

Disclosure of Invention

The invention aims to provide a double-sided photovoltaic cell testing device to correct errors of double-sided photovoltaic cell testing results caused by nonlinear change of double-sided photovoltaic cell power along with light intensity.

The purpose of the invention is realized as follows:

a double-sided photovoltaic cell testing device is characterized in that: the solar simulator is arranged in the middle of the inner wall of the left side plate of the darkroom, the reflecting cover is arranged in the middle of the inner wall of the right side plate of the darkroom and is opposite to the solar simulator, the battery bracket for placing the double-sided photovoltaic battery is arranged in the middle of the darkroom and between the solar simulator and the reflecting cover, the test power supply is connected with the battery bracket through a lead, and the center of the reflecting cover, the center of the double-sided photovoltaic battery and the center of the solar simulator are on the same straight line, so that the back and the front of the double-sided photovoltaic battery are uniformly radiated by the solar simulator; one ends of two mirror reflection plates with completely same structures and symmetrically arranged are respectively hinged in the middle of the inner walls of the front side plate and the rear side plate of the darkroom between the battery bracket and the reflection cover, the other ends of the two mirror reflection plates extend to the middle, the two mirror reflection plates respectively form acute angles with the included angles of the front side plate and the rear side plate of the darkroom, and the reflection surfaces face the solar simulator.

The angle between the mirror reflection plate and the front side plate and the angle between the mirror reflection plate and the back side plate of the darkroom can be changed, the angle of the reflection light of the mirror reflection plate is changed by changing the angle between the mirror reflection plate and the front side plate and the back side plate of the darkroom, so that the radiant quantity of the solar simulator is controlled and collected and reflected to the reflection cover, and the angle control range is 0-30 degrees.

The inner surface of the reflector is parabolic, and the reflector vertically reflects incident light passing through a parabolic focus to the back of the double-sided photovoltaic cell; the inner surface of the reflector below the parabolic focus is smooth, the inner surface of the reflector above the parabolic focus is rough, and the focal length is as large as possible to improve the uniformity of the reflected light.

The bottom of the support rod of the battery support is provided with a roller with a stop switch, so that the battery support can move to fix the double-sided photovoltaic module in a darkroom as required.

The double-sided photovoltaic cell is a double-sided photovoltaic assembly or a double-sided cell piece.

The test power supply is used for testing the whole electrical parameters of the double-sided photovoltaic cell. The darkroom provides a dark environment for the test.

The mirror reflection plate is replaceable, the irradiance on the back of the double-sided photovoltaic cell can have certain difference according to different installation backgrounds in practical application, the standard is established according to TuV, and the relation between the back reflection coefficient and the installation background is shown in the following table 1. Therefore, the irradiance reflected to the reflector is controlled by replacing the specular reflection plates with different reflectivities, so that the irradiance on the back of the double-sided photovoltaic cell is regulated and controlled.

In addition, the irradiance of the back of the double-sided photovoltaic cell can also be controlled by the angle between the specular reflection plate and the front side plate and the back side plate of the darkroom. When the angle is adjusted, the change of the emission coefficient from 0 to 30 percent can be realized by combining with the replacement of the specular reflection plate, and preferably, the angle between the specular reflection plate and the front side plate and the rear side plate of the darkroom is adjusted to change the angle of the reflected light of the specular reflection plate, so that the reflected light can reach the focus of the parabola of the reflection cover as far as possible.

The invention should avoid the interference of other light sources when testing, the other materials except the mirror surface reflection plate and the reflection cover should be painted black, the whole environment is placed in a dark room to reduce the interference of stray light and improve the stability and accuracy of the test result.

During testing, part of radiation of the solar simulator is directly radiated to the front side of the double-sided photovoltaic cell; a portion of the radiation strikes the specular reflector and is reflected into the reflector, which reflects the collected radiation to the back side of the bifacial photovoltaic cell (as shown in fig. 2), so that the front and back sides of the bifacial photovoltaic module are simultaneously irradiated by the solar simulator. Therefore, the method can simultaneously and accurately measure the I-V curve of the double-sided photovoltaic cell under the condition of adopting a single solar simulator, thereby eliminating the test deviation caused by the difference between the test environment and the actual operation environment of the double-sided photovoltaic cell to the maximum extent.

Therefore, the invention enables the front side and the back side of the double-sided photovoltaic cell to be simultaneously radiated by light during testing, can accurately and conveniently measure the whole electrical performance of the double-sided photovoltaic cell, corrects the error of the power of the double-sided photovoltaic cell on the test result of the double-sided photovoltaic cell along with the nonlinear change of the light intensity, realizes the simultaneous measurement of the whole electrical performance of the front side and the back side of the double-sided photovoltaic cell, and eliminates the deviation of the test result caused by two-step test fitting.

Drawings

FIG. 1 is a schematic view of the present invention;

and (3) identifying the figure number: 1. the device comprises a solar simulator, 2, a test power supply, 3, a mirror reflector, 4, a reflector, 5, a bracket, 6, a darkroom, 7 and a lead;

fig. 2 is a top view of the optical path of the present invention.

Detailed Description

The invention is described in detail below with reference to the figures and specific examples. It is to be noted that the drawings of the present invention are provided in a very simplified and non-precise scale for convenience and clarity in order to facilitate the description of the present invention.

Example 1:

the embodiment is a testing device for testing a double-sided photovoltaic module, as shown in fig. 1, the testing device comprises a solar simulator 1, a testing power supply 2, a mirror reflector 3, a reflector 4, a battery support 5, a darkroom 6 and a lead 7, wherein the solar simulator 1 is arranged in the middle of the inner wall of the left side plate of the darkroom 6, the reflector 4 with a parabolic inner surface is arranged in the middle of the inner wall of the right side plate of the darkroom 6 and opposite to the solar simulator 1, the battery support 5 for placing the double-sided photovoltaic module is arranged in the middle of the darkroom 6 and between the solar simulator 1 and the reflector 4, the testing power supply 2 is connected with the battery support 5 through the lead 7, the center of the reflector 4, the center of the double-sided photovoltaic module and the center of the solar simulator 1 are on the same straight line, so that the radiation of the back side and the front side of the double-sided photovoltaic module is uniform, and the double-sided photovoltaic module with different sizes is fixed by moving without shielding the back side and the front side Radiation of the solar simulator of (1); the one end of two mirror reflector 3 that the structure is the same completely, the symmetry is placed articulates respectively in the middle of the inner wall of darkroom 6 front side board, posterior lateral plate between battery stand 5 and bowl 4, and the other end of two mirror reflector 3 stretches to the centre, and two mirror reflector 3 are acute angle and plane of reflection respectively with the preceding lateral plate of darkroom 6, the contained angle of posterior lateral plate and face of reflection towards solar simulator 1.

The bottom of the support rod of the battery support 5 is provided with a roller with a stop switch, so that the battery support 5 can move as required in the darkroom 6, and the battery support 5 does not shield the light of the solar simulator 1 radiated to the double-sided photovoltaic battery.

The inner surface of the reflector 4 is parabolic, and the reflector 4 vertically reflects incident light passing through a parabolic focus to the back of the double-sided photovoltaic cell; the inner surface of the reflector 4 below the parabolic focus is smooth, the inner surface of the reflector above the parabolic focus is rough, and the focal length is as large as possible to improve the uniformity of the reflected light.

The angle between the mirror reflection plate 3 and the front side plate and the rear side plate of the darkroom 6 can be changed, the angle of the reflected light of the mirror reflection plate 3 is changed by changing the angle between the mirror reflection plate 3 and the front side plate and the rear side plate of the darkroom 6, so that the radiant quantity of the solar simulator 1 is controlled and collected and reflected to the reflection cover 4, and the angle change range is 0-30 degrees.

During testing, the double-sided photovoltaic module (195.6 cm × 99.2 cm) is vertically placed on the battery support 5, the distance between the battery support 5 and the solar simulator 1 is 300cm, and the width and the height of the battery support 5 are 100cm and 200cm respectively; the two specular reflection plates 3 are arranged behind two sides of the double-sided photovoltaic module and are equal in size, and the width and the height of each specular reflection plate are 100cm and 200cm respectively; the reflector 4 is arranged right behind the double-sided photovoltaic module, the parabolic focal length of the reflector 4 is 50cm, the size radius of a port of the reflector 4 is 100cm, and the distance between the parabolic bottom of the reflector 4 and the double-sided photovoltaic module is 300 cm.

In the standard test, the front side irradiance of the bifacial cell was 1000W/m 2. Since most of the double-sided photovoltaic modules are installed in soil, the reflection coefficient is 10% in this embodiment, that is, the irradiance on the back of each double-sided photovoltaic module is 100W/m2, and the specular reflection plate with a nominal reflectivity of 50% is used to adjust the angle between the specular reflection plate and the front side plate and the back side plate of the darkroom 6 to 7 °, so that the irradiance on the back of each double-sided photovoltaic module is 100W/m 2.

During testing, the double-sided photovoltaic module is fixed on the battery bracket 5 and the lead port is connected with the testing power supply 2, so that the center of the reflecting cover 4, the center of the double-sided photovoltaic module and the center of the solar simulator 1 are on the same straight line; the testing power supply 2 is turned on, and the front side of the double-sided photovoltaic module receives radiation of the solar simulator 1; at the same time, the back of the bifacial photovoltaic module receives radiation reflected by the reflector 4. The method can simultaneously and accurately measure the I-V curve of the double-sided photovoltaic module, thereby solving the problem of test errors caused by the difference between the test environment and the actual application environment of the double-sided photovoltaic cell to the maximum extent.

Example 2:

the embodiment is a testing device for testing a double-sided battery piece, as shown in fig. 1, and the testing device comprises a solar simulator 1, a testing power supply 2, a mirror reflector 3, a reflector 4, a battery support 5, a darkroom 6 and a lead 7, wherein the solar simulator 1 is arranged in the middle of the inner wall of the left side plate of the darkroom 6, the reflector 4 with a parabolic inner surface is arranged in the middle of the inner wall of the right side plate of the darkroom 6 and opposite to the solar simulator 1, the battery support 5 for placing the double-sided battery piece is arranged in the middle of the darkroom 6 and between the solar simulator 1 and the reflector 4, the testing power supply 2 is connected with the battery support 5 through the lead 7, the center of the reflector 4, the center of the double-sided battery piece and the center of the solar simulator 1 are on the same straight line, so that the radiation of the back and the front of the double-sided battery piece is uniform, and the double-sided battery piece with different sizes is fixed by moving and does not shield a solar module from the back and the front of Radiation of the simulator; the one end of two mirror reflector 3 that the structure is the same completely, the symmetry is placed articulates respectively in the middle of the inner wall of darkroom 6 front side board, posterior lateral plate between battery stand 5 and bowl 4, and the other end of two mirror reflector 3 stretches to the centre, and two mirror reflector 3 are acute angle and plane of reflection respectively with the preceding lateral plate of darkroom 6, the contained angle of posterior lateral plate and face of reflection towards solar simulator 1.

The bottom end of the support rod of the battery support 5 is provided with a roller with a stop switch, so that the battery support 5 can move as required in the darkroom 6, and the battery support 5 does not shield the light radiated by the solar simulator 1 to the double-sided battery piece.

The inner surface of the reflector 4 is parabolic, and the reflector 4 vertically reflects incident light passing through a parabolic focus to the back of the double-sided photovoltaic cell; the inner surface of the reflector 4 below the parabolic focus is smooth, the inner surface of the reflector above the parabolic focus is rough, and the focal length is as large as possible to improve the uniformity of the reflected light.

The angle between the mirror reflection plate 3 and the front side plate and the rear side plate of the darkroom 6 can be changed, the angle of the reflected light of the mirror reflection plate 3 is changed by changing the angle between the mirror reflection plate 3 and the front side plate and the rear side plate of the darkroom 6, so that the radiant quantity of the solar simulator 1 is controlled and collected and reflected to the reflection cover 4, and the angle change range is 0-30 degrees.

In the test process, double-sided battery pieces (15.6 cm x 15.6 cm) are placed on a battery support 5, the distance between the battery support 5 and the solar simulator 1 is 30cm, the width and the height of the battery support 5 are respectively 20cm and 20cm, the double-sided battery pieces are fixed by moving the support, and other parts in the support are shielded by black cloth; the two mirror reflection plates 3 are arranged behind two sides of the double-sided cell piece and are equal in size, the width and the height of the two mirror reflection plates are respectively 20cm and 20cm, and the vertical distance between the center of each mirror reflection plate 3 and the solar simulator 1 is 35 cm; the reflector 4 is arranged right behind the double-sided cell piece, the focal length of the reflector 4 is 5cm, the size radius of a port of the reflector 4 is 10cm, and the distance between the parabolic bottom of the reflector 4 and the double-sided photovoltaic cell is 30 cm.

In the standard test, the front irradiance of the double-sided cell piece is 1000W/m 2. The embodiment adopts the example of the reflection coefficient of 20%, namely the back irradiance of the double-sided cell is 200W/m2, the specular reflection plate 3 with the nominal reflectivity of 70% is used, and the angles of the specular reflection plate 3 with the front side plate and the back side plate of the darkroom 6 are adjusted to be 7 degrees, so that the back of the double-sided cell receives the irradiance of 200W/m 2.

During testing, the center of the reflecting cover 4, the center of the double-sided cell and the center of the solar simulator 1 are on the same straight line; and (5) turning on the test power supply 2 to measure the overall electrical performance of the double-sided battery piece. The method can simultaneously and accurately measure the I-V curve of the double-sided battery piece, thereby solving the problem of test errors caused by the difference between the test environment and the actual application environment of the double-sided battery piece to the maximum extent.

The above-mentioned embodiments are only one embodiment of the present invention, not limited thereto, and the scope of the present invention is not limited thereto, and those skilled in the art can still make modifications or equivalent substitutions to the technical solutions described in the above-mentioned embodiments, and these modifications and substitutions do not depart from the scope of the present invention, and should be included in the scope of the present invention, and the scope of the present invention is subject to the claims set forth below.

Claims (6)

1. The utility model provides a two-sided photovoltaic cell testing arrangement which characterized in that: the solar simulator is arranged in the middle of the inner wall of the left side plate of the darkroom, the reflecting cover is arranged in the middle of the inner wall of the right side plate of the darkroom and is opposite to the solar simulator, the battery bracket for placing the double-sided photovoltaic battery is arranged in the middle of the darkroom and between the solar simulator and the reflecting cover, the test power supply is connected with the battery bracket through a lead, and the center of the reflecting cover, the center of the double-sided photovoltaic battery and the center of the solar simulator are on the same straight line, so that the back and the front of the double-sided photovoltaic battery are uniformly radiated by the solar simulator; one ends of two mirror reflection plates with completely same structures and symmetrically arranged are respectively hinged in the middle of the inner walls of the front side plate and the rear side plate of the darkroom between the battery bracket and the reflection cover, the other ends of the two mirror reflection plates extend to the middle, the two mirror reflection plates respectively form acute angles with the included angles of the front side plate and the rear side plate of the darkroom, and the reflection surfaces face the solar simulator.

2. The bifacial photovoltaic cell testing device of claim 1, wherein: the angle between the mirror surface reflection plate and the front side plate and the rear side plate of the darkroom can be changed, and the angle change range is 0-30 degrees.

3. The bifacial photovoltaic cell testing device of claim 1, wherein: the inner surface of the reflector is parabolic.

4. The bifacial photovoltaic cell testing device of claim 3, wherein: the inner surface of the reflector below the parabolic focus is smooth, the inner surface of the reflector above the parabolic focus is rough, and the focal distance is as large as possible.

5. The bifacial photovoltaic cell testing device of claim 1, wherein: the bottom end of the support rod of the battery bracket is provided with a roller with a stop switch.

6. The bifacial photovoltaic cell testing device of claim 1, wherein: the double-sided photovoltaic cell is a double-sided photovoltaic assembly or a double-sided cell piece.

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