KR20180048047A - Solar simulator - Google Patents

Abstract

The present invention relates to a solar simulator. The solar simulator comprises: a light source part (20) installed in a chamber (10), and irradiating a light source; an optical integrator (40) receiving and dispersing the light source irradiated by the light source part (20), and converting the light source into a uniform light source through integration; an automatic shutter (50) automatically opening and closing the light source passing through the optical integrator (40); and a collimating lens (80) receiving the light source passing through the automatic shutter (50), and irradiating the light source to a solar cell. The automatic shutter capable of electric control is applied so as to rapidly respond to large-area irradiation, thereby capable of using a continuous light source.

Description

Solar simulator {SOLAR SIMULATOR}

The present invention relates to a solar simulator, and more particularly, to a solar simulator that artificially generates light similar to natural sunlight so that a solar cell can be tested and measured.

Since solar cells are installed outdoors and exposed to natural light or condensed sunlight for a long time, they must be able to withstand high temperatures and various weather conditions.

In order to evaluate the overall reliability of the solar cell, it is desirable to measure the property change over a long period of time in a natural environment condition at the installation site. However, it is difficult to accurately assess the characteristics of solar cells due to severe weather changes in the outdoor environment.

Therefore, the solar simulator, which is an artificial light source, is used to perform a severe environmental test and a durability test.

Such a solar simulator is an indispensable device required in the test stage of a solar cell so as to stably secure the characteristics of the solar cell which changes depending on the sunlight intensity per unit time and the ambient temperature, and to compensate the disadvantages related to installation and operation.

The solar simulator provides a solar-like environment in an environment that is difficult to implement (typically, indoor environment) through a light source similar to a solar light, thereby enabling a test solar cell to be a sample.

When testing a high efficiency solar cell, it is necessary to use a continuous light source, and a shutter is required to use a continuous light source. However, physically acting shutters have to be operated quickly because of the large size of the light source, but when the irradiation area of the light source is large, a large vibration occurs or a case may not be fast enough.

That is, in order to use a continuous light source in a large-area solar simulator, a light shielding shutter must be moved quickly. However, in a large-area solar simulator, a shutter is physically difficult to react quickly.

Patent Document 1: Korean Registered Patent No. 1545269 (Registered on August 5, 2015)

SUMMARY OF THE INVENTION An object of the present invention is to provide a solar simulator capable of using a continuous light source by applying a self-shutter so that a shutter can react quickly in large-area irradiation.

According to an aspect of the present invention, there is provided an optical integrator comprising: a light source unit disposed in a chamber for irradiating a light source; an optical integrator for dispersing a light source irradiated from the light source unit and forming a uniform light source through integration; A self shutter for automatically opening and closing a light source that has passed through the optical integrator, and a collimating lens for receiving a light source passed through the automatic shutter and irradiating the solar cell with the light source.

And a second reflection mirror for reflecting the light source irradiated from the light source unit and causing the light source to be irradiated by the optical integrator and the second reflection mirror for reflecting the light source passed through the automatic shutter so that the light source is irradiated to the collimator lens do.

The automatic shutter is an LCD shutter.

The LCD shutter is an LCD panel that injects liquid crystal between two glass substrates and transmits or blocks light by changing the liquid crystal array according to whether a voltage is supplied or not.

The light source is a XENON lamp.

An air mass filter for changing the light source into a light source having a spectrum substantially similar to sunlight is included.

The present invention can automatically open and close a light source irradiated from the light source unit by providing a self-shutter. Since the shutter can be electrically controlled by an LCD shutter, it reacts rapidly in large-area irradiation, enabling continuous light source use.

Therefore, the present invention has the effect of improving the reliability of the performance evaluation test of a large area solar cell.

1 is a view showing a solar simulator according to the present invention.
FIG. 2 is a conceptual view illustrating the operation principle of a self-shutter applied to a solar simulator according to the present invention. FIG.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The solar simulator of the present invention can measure the efficiency and voltage-current characteristics of a solar cell or a solar module by simulating sunlight in a laboratory.

Solar simulator is a solar simulator capable of large area survey.

Fig. 1 shows a solar simulator according to the present invention.

1, the solar simulator is installed in the chamber 10 and includes a light source 20, a first reflection mirror 30, an optical integrator 40, a self-shutter 50, an air mass filter 60, A second reflecting mirror 70, and a collimating lens 80.

The light source unit 20 irradiates the light source. The light source unit 20 uses a Xenon lamp 21.

The Xenon lamp 21 can realize a current-voltage characteristic similar to that of an actual photovoltaic power generation environment by using a light emission by discharge in a xenon gas.

The Xenon lamp 21 is provided with a reflector 23, which is a lamp cover, to enhance the straightness of the light source. The reflector 23 may be made of an aluminum material.

The light source unit 20 may use an LED lamp. However, in the case of an LED lamp, there is a limitation in satisfying only the solar spectrum under the condition of AM 1.5G and it is difficult to realize various spectral conditions. In the present invention, it is preferable to apply a xenon lamp to the light source part.

The first reflecting mirror 30 reflects the light source moving straight and changes the moving path of the light source.

That is, the first reflection mirror 30 reflects the light source irradiated from the light source unit 20, and causes the light source to be irradiated to the optical integrator 40 disposed perpendicularly to the light source unit 20. [

To this end, the first reflection mirror 30 is installed at an inclination at a point where the light source unit 20 and the optical integrator 40 meet vertically.

The optical integrator 40 receives and disperses a light source irradiated from the light source unit 20, and then integrates the light source into a uniform light source. The optical integrator 40 is a lens for dispersing a light source by attaching several lens cells to obtain a uniform light source through integration, in order to increase the uniformity of the light source.

The automatic shutter 50 automatically opens and closes the light source that has passed through the optical integrator 40. The self-timer is an LCD (Liquid Crystal Display) shutter. The LCD shutter enables the continuous light source to be used in a solar simulator that can cut off the light source by electrical control, not the physical operation, so that the reaction is quick and the irradiation area of the light source is large (450 mm wafer for example).

The LCD shutter may be an LCD panel that injects liquid crystal between two glass substrates and transmits or blocks light by changing the arrangement of the liquid crystal depending on whether a voltage is supplied or not.

That is, the transmittance of the light source is adjusted by adjusting the arrangement state of the liquid crystal itself.

FIG. 2 is a conceptual view showing the operation principle of the self-shutter applied to the solar simulator according to the present invention.

For example, as shown in FIG. 2, the LCD shutter may be a structure including polarizing plates 51 and 52, alignment films 53 and 54, and liquid crystal 55.

The polarizing plates 51 and 52 apply light only in a specific direction, and the alignment films 53 and 54 change the liquid crystal alignment. The liquid crystal 55 acts as a shutter in an intermediate state between the liquid and the solid, and transmits or blocks the light source according to the voltage on / off.

As shown in FIG. 2A, when the voltage is off, the liquid crystal 55 is twisted by the alignment films 53 and 54 to transmit the light source.

2 (a), when the voltage is on, the liquid crystal 55 is arranged according to the voltage direction to cut off the light source.

The LCD panel can be selected from TN LCD using Twisted Nematic liquid crystal, STN LCD using Super Twisted Nematic liquid crystal, FLCD using Ferroelectric liquid crystal, and CLCD using Cholesteric liquid crystal.

Of these, the fastest response

A plurality of the automatic shutters 50 may be arranged on the front side of the optical integrator 40 in a series structure or a parallel lamination structure. Alternatively, the automatic shutter 50 may be disposed at a plurality of inclined angles at a predetermined angle on the front side of the optical integrator 40.

And a control unit for selectively supplying a voltage to the self shutter 50. [

Although not shown, the control unit can control the presence or absence of the voltage supplied to the automatic shutter 50 and also control the intensity of the light source irradiated by the light source unit 20. [

The air mass filter 60 changes the spectrum of the light source to realize a spectrum of the light source substantially similar to the sunlight. The air mass filter 60 allows a light source having a spectrum substantially similar to the AM 1.5G sunlight to be irradiated in a wavelength range of 350 nm to 1800 nm.

The second reflecting mirror 70 reflects the light source that has passed through the automatic shutter 50 so that the light source is irradiated to the collimating lens 80 arranged perpendicularly to the second reflecting mirror 70. The second reflection mirror 70 is installed at an inclination at a point where the air mass filter 60 and the aiming lens 80 meet vertically.

The aiming lens 80 receives the light source that has passed through the automatic shutter 50 and irradiates the solar cell. The aiming lens 80 irradiates the light source in parallel to the solar cell. It is preferable that the parallelism of the light source irradiated through the aiming lens 80 is within 0.8 degree. The spatial uniformity is preferably 2% or less.

A work table 90 is provided below the collimating lens 80, and a solar cell serving as a test sample is disposed on the work table 90.

The operation of the present invention will be described below.

When the light source is irradiated by the Xenon lamp 21 of the light source unit 20, the reflector 23 enhances the linearity of the light source, and the light source that is straightened is reflected by the first reflection mirror 30, (40).

The light source illuminated by the optical integrator 40 is dispersed and made into a uniform light source through integration. This light source is automatically controlled by the automatic shutter 50 disposed on the front side of the optical integrator 40.

That is, the automatic shutter 50 controls the opening and closing of the light source by adjusting the arrangement state of the liquid crystal itself depending on whether a voltage is supplied or not.

The light source that has passed through the automatic shutter 50 passes through the air mass filter 60 provided on the front side of the automatic shutter 50 and becomes a light source having a spectrum substantially similar to the AM 1.5G sunlight.

The light source having passed through the air mass filter 60 is reflected by the second reflecting mirror 70 inclined to the front side of the air mass filter 60 so that the moving direction is directed to the collimating lens 80.

The light source irradiated with the collimating lens 80 by the second reflecting mirror 70 is irradiated in parallel to the solar cell arranged on the work table 90. [

By the above-described process, the light source can be irradiated to the solar cell and the voltage-current characteristic can be measured.

In the above-described solar simulator, since the automatic shutter automatically performs opening and closing of the light source by electrical control, it can react rapidly in the irradiation of the large-area light source, thereby enabling the use of the continuous light source.

For reference, the solar simulator can be equipped with a cooling device in the chamber. Xenon lamps have a high heating value. Therefore, a cooling device may be installed in the chamber to prevent the temperature inside the chamber receiving the radiant heat of the xenon lamp from becoming excessively high.

Best Mode for Carrying Out the Invention The present invention has been described with reference to the drawings and the specification. Although specific terms are used herein, they are used for the purpose of describing the present invention only and are not used to limit the scope of the present invention described in the meaning of the claims or the claims. Therefore, those skilled in the art will appreciate that various modifications and equivalent embodiments are possible without departing from the scope of the present invention. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

10: chamber 20: light source
21: Xenon lamp 23: reflector
30: first reflection mirror 40: optical integrator
50: Self-timer 51, 52: Polarizer
53,54: Orientation film 55: Liquid crystal
60: air mass filter 70: second reflection mirror
80: aiming lens 90: work bench

Claims (6)

A light source installed in the chamber and irradiating the light source;
An optical integrator for receiving and dispersing a light source irradiated by the light source unit and then converting the dispersed light into a uniform light source through integration;
An automatic shutter that can automatically open and close a light source that has passed through the optical integrator; And
And a collimating lens that receives the light source passed through the automatic shutter and irradiates the solar cell with the light source. The method according to claim 1,
A first reflection mirror for reflecting the light source irradiated from the light source unit and allowing the light source to be irradiated by the optical integrator; And
And a second reflecting mirror for reflecting the light source passed through the automatic shutter so that the light source is irradiated with the collimating lens. The method according to claim 1,
Wherein the automatic shutter is an LCD shutter. The method of claim 3,
Wherein the LCD shutter is an LCD panel that injects liquid crystal between two glass substrates and changes the liquid crystal arrangement according to whether a voltage is supplied or not to transmit or block light. The method according to claim 1,
Wherein the light source unit is a XENON lamp. The method according to claim 1,
And an air mass filter for changing the light source into a light source having a spectrum substantially similar to that of sunlight.

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