KR101993056B1 - Solar simulator - Google Patents

Abstract

The present invention relates to a solar simulator, and more particularly, to a solar simulator that includes a plurality of reflector parts, each of which is provided on one side, the other side, the front side, and the rear side of a lens part and transmits a part of artificial solar light diffused toward the outside of the lens part, The artificial solar light can be transmitted uniformly and the power generation efficiency of the solar cell can be accurately measured.

Description

Solar simulator {Solar simulator}

The present invention relates to an artificial sunlight which is uniformly scattered over the entire solar cell of a solar cell through a plurality of reflector parts which are provided on one side, the other side, the front side and the rear side of the lens part and which transmit some artificial sunlight diffused in the outward direction of the lens part, To a solar simulator capable of precisely measuring the power generation efficiency of a solar cell.

The total amount of photovoltaic power generation is increasing every year according to the axis of world power. The solar cell, which is a core component of the photovoltaic power plant, is measured by a solar simulator that can evaluate the characteristics of the solar cell and is sold at a price per watt .

The solar simulator is a test device that measures the current and voltage characteristics of a solar cell using a light source similar to solar energy and verifies the efficiency based on the measurement result. Recently, a solar simulator that emits artificial solar light similar to solar light Korean Patent Registration No. 10-1359961.

However, in the case of Korean Patent Registration No. 10-1359961, when a lens for collecting artificial sunlight emitted from a lamp transmits artificial sunlight condensed by a solar battery, So that uniform artificial solar light can not be transmitted to the entire solar cell of the solar cell, and thus the power generation efficiency of the solar cell can not be accurately measured.

Korean Registered Patent Publication No. 10-1359961

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a solar cell module, which is provided with a plurality of reflector parts, each of which is provided on one side, the other side, the front side, and the rear side of a lens part, The present invention aims to provide a solar simulator capable of precisely measuring the power generation efficiency of a solar cell because uniform artificial solar light can be transmitted to the entire solar cell of the battery.

According to an aspect of the present invention, there is provided a lighting system comprising: a lamp for emitting artificial sunlight; A reflector for reflecting artificial sunlight emitted from the lamp; A lens unit for condensing the artificial sunlight reflected by the reflector; A plurality of reflection plate parts provided on one side, the other side, the front side and the rear side of the lens part and having a reflection layer formed on the inside thereof; And a sub-lamp provided inside each of the plurality of reflection plates to emit light.

An initial setting solar cell moving unit for intermittently moving the initial setting solar cell in the forward, backward, left and right directions in a state that the initial setting solar cell receiving the artificial sunlight condensed by the lens unit is seated on the top; And a control unit for controlling the initial setting cell moving unit.

The measuring unit measures the current value output from the initial setting solar cell, which is axially coupled to one side, the other side, the front side, and the rear side of the lens unit, respectively. And an angle adjusting unit for adjusting the angles of the plurality of reflection plates by rotating the lower portions of the plurality of reflection plates in the vertical direction of the lens unit, It is preferable to control the angle adjusting unit according to the value.

Alternatively, the upper portion of the plurality of reflection plates may be coupled to one side, the other side, the front side, and the rear side of the lens unit, respectively, and measure the current value output from the initial setting solar cell; And an angle adjusting unit for adjusting the angles of the plurality of reflection plates by rotating the lower portions of the plurality of reflection plates in the vertical direction of the lens unit, It is preferable to control the brightness of the angle adjusting unit and the brightness of the sub lamp according to the value.

In addition, the initial setting solar cell moving part includes a left and right moving plate part on which a solar cell for measuring a current value is mounted on one side of the upper part, and the initial setting solar cell is provided on the other side of the upper part so as to be movable forward, Left and right moving parts for moving the left and right moving plate parts left and right; A front and rear moving plate provided on the other side of the upper side of the left and right moving plate so as to be movable back and forth; a back and forth moving member for moving the front and rear moving plate back and forth; A left and right moving plate on which the solar cell is mounted, and left and right moving members for moving the left and right moving plates to move left and right.

The present invention relates to an artificial sunlight which is uniformly scattered over the entire solar cell of a solar cell through a plurality of reflector parts which are provided on one side, the other side, the front side and the rear side of the lens part and which transmit some artificial sunlight diffused in the outward direction of the lens part, So that it is possible to precisely measure the power generation efficiency of the solar cell.

1 is a partially cut-away front view schematically showing a solar simulator according to an embodiment of the present invention,
2 is a partially cut-away front view schematically showing a reflection process of artificial sunlight,
3 is a bottom view schematically showing one example of a plurality of reflection plate portions,
4 is a partially enlarged side view schematically showing an example of the initial setting cell moving part and the angle adjusting part,
5 is a plan view schematically showing an example of the initial setting cell moving section,
6 is a plan view schematically showing a process of moving the initial setting solar cell forward, backward and leftward,
7 is a block diagram schematically showing a control state of the control unit,
8 is a partially enlarged side view schematically showing a state in which a solar cell to be measured is positioned in a lower direction of the lens unit by the left and right moving plate unit.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings. It is to be understood that the scope of the present invention is not limited to the following embodiments, and various modifications may be made by those skilled in the art without departing from the technical scope of the present invention.

FIG. 1 is a partially cut-away front view schematically showing a solar simulator according to an embodiment of the present invention, and FIG. 2 is a partially cutaway front view schematically showing a reflection process of artificial sunlight.

1, a solar simulator according to an embodiment of the present invention includes a lamp 10, a reflector 20, a lens portion 30, a plurality of reflector portions 40, and an auxiliary lamp 50 .

First, the lamp 10, the reflector 20, and the lens unit 30 may be provided on the body 5.

The body 5 may include one body 51 and the other body 52, for example.

The one side body 51 may be installed in various ways such as a bolt fixing vertically to one side of the upper side of the fixing plate part 511 which is fixed horizontally on the ground.

The other body 52 may be formed on the other side opposite to the one side of the one body 51 so as to communicate with the body 51.

The lamp 10 may be provided on the lower side of the one body 51.

The lamp 10 may be composed of various types such as a xenon lamp that emits artificial sunlight most similar to sunlight.

The reflector 20 is composed of one reflector 201 and the other reflector 202 and can reflect artificial sunlight emitted from the lamp 10.

The one side reflector 201 may be provided on the upper side of the one side body 51.

The one side reflector 201 may be inclined downward toward one side of the one side body 51 from the upper side of the one side reflector 201 toward the lower side.

The other reflector 202 may be provided on the upper side of the other body 52 in a symmetrical manner with respect to the one reflector 201.

The lens unit 30 may include a lens fixing body 301 and a lens 302.

The lens fixing body 301 is formed in a variety of shapes such as a rectangle and is connected to the other body 52 of the body 5 so as to be positioned in the lower direction of the other body reflector 202, And bolts are fastened to the lower portion.

The lens 302 is fixed to the inside of the lens fixing body 301 in a variety of ways such as bolts and the like, so that the artificial sunlight reflected by the reflector 20 can be condensed.

The lens 302 may be composed of various types such as a collimator lens that transmits artificial sunlight to parallel artificial sunlight.

The lens 302 transmits the collected artificial sunlight to an initial setting solar cell and a solar cell, which will be described later, which are positioned below the lens 302.

3 is a bottom view schematically showing an example of a plurality of reflection plate portions.

1 to 3, the plurality of reflection plate portions 40 are respectively provided on one side, the other side, the front side and the rear side of the lens fixing body 301 of the lens portion 30, 30 can be turned on by the initial setting cell and the solar cell, respectively.

Although not shown in the drawing, a plurality of reflection layers, such as aluminum foil, may be formed on the inner side of the plurality of reflection plates 40.

Next, the auxiliary lamp 50 may include various types of LEDs, such as LEDs, disposed inside the plurality of reflector portions 40 to emit light.

FIG. 4 is a partially enlarged side view schematically showing an example of the initial setting cell moving portion and an example of the angle adjusting portion, and FIG. 5 is a plan view schematically showing an example initial setting cell moving portion.

Next, the initial setting cell moving unit 60 and the control unit may be further provided.

In a state where the initial setting solar cell 71 receiving the artificial sunlight condensed by the lens unit 30 is mounted on the initial setting solar cell moving unit 60, (60) can move the initial setting solar cell (71).

The controller may receive the power from the power supply unit and control the initial setting cell moving unit 60.

The initial setting cell moving unit 60 may include a left and right moving plate 610, a left and right moving unit 620, and a front and rear left and right moving unit 630 as shown in FIGS. 4 and 5.

The left and right moving plate portions 610 may be provided on the other side of the fixing plate portion 511 so as to be movable leftward and rightward from one side of the fixing plate portion 511 in the other direction.

A solar cell 7 to measure a current value may be mounted on one side of the upper portion of the left and right moving plate 610.

A protruding protrusion 611 protruding upward from the left and right moving plate 610 may be formed on one side of the left and right moving plate 610.

The solar cell 7 can be seated inside the protruding step 611.

The initial setting solar cell 71 may be provided on the other side of the left and right moving plate 610 so as to be movable forward, backward, left and right.

The left and right moving parts 620 are composed of a lead screw 621 and a driving motor 622 and can move the left and right moving plate parts 610 left and right.

The leadscrew 621 may be extended laterally to a predetermined length from one side to the other side of the fixing plate 511.

The lead screw 621 is vertically formed at a lower center portion of the left and right moving plate portion 610 and is fixed to the upper portion of the fixing plate portion 511 in a left- And can be screwed to the body 611.

The driving motor 622 is fixed to the upper portion of the fixing plate 511 in such a manner that the driving motor 622 is fixed to the upper portion of the fixing screw 511 horizontally by bolts and the like, .

The front and rear left and right moving parts 630 may include a front and rear moving plate 631, a back and forth moving member 632, a left and right moving plate 633, and a left and right moving member 634.

The front and rear moving plate 631 may be provided on the other side of the upper side of the left and right moving plate 610 so as to be movable back and forth from the front side to the rear side of the left and right moving plate 610.

The back-and-forth moving member 632 may include a back-and-forth moving lead screw 632a and a back-and-forth moving driving motor 632b.

The front and rear moving lead screws 632a may be formed to extend longitudinally from the front side of the left and right moving plate portions 610 to a rear side in a predetermined length.

The front and rear moving lead plates 632a are vertically formed at a lower center portion of the front and rear moving plate 631 so that they can be moved back and forth from the front side of the left and right moving plate 610 to the other side of the upper side of the left and right moving plate 610 The movable body 631a can be screwed to the front and rear movable bodies 631a.

The driving motor 632b for back and forth movement is fixed to the upper portion of the left and right moving plate 610 in such a manner as to be horizontally bolted to the upper portion of the front and rear moving lead screws 632a, (632a).

The left and right moving plate 633 may be provided at an upper portion of the front and rear moving plate 631 so as to be movable leftward and rightward from one side of the front and rear moving plate 631 toward the other side.

A protruding protrusion 631a may be formed on the upper edge of the left and right moving plate 633 to have a rectangular shape protruding upward from the left and right moving plate 633.

The initial setting solar cell 71 can be seated inside the projecting step 633a of the left and right moving plate 633. [

The left and right moving member 634 may include a left and right moving lead screw 634a and a left and right driving motor 634b.

The left and right moving lead screws 634a may be formed to extend in the left and right direction from the one side of the back and forth moving plate 631 to the other side.

The left and right moving lead screws 634a are vertically formed at a lower center portion of the left and right moving plates 633 so that they can be moved leftward and rightward from one side of the back and forth moving plate 631 to the upper side of the back and forth moving plate 631 And can be screwed to the left and right moving bodies 633b which are seated.

The left and right movement driving motors 634b are fixed to the upper portion of the back and forth moving plate 631 in various manners such as bolt fixing in a state of being coupled to the other side of the left and right moving lead screws 634a on the opposite side, The lead screw 634a can be rotated in the forward and reverse directions.

FIG. 6 is a plan view schematically showing a process of moving the initial setting solar cell forward, backward, leftward, and rightward.

6, the front and rear left and right moving units 630 move the initial setting solar cells 71 so that the initial setting solar cells 71 are moved in a zigzag manner at intervals of an intermittent time period, And can be intermittently moved in the front, rear, left, and right directions of the lens unit 30. [

7 is a block diagram schematically showing a control state of the control unit.

4, the upper portions of the plurality of reflection plate portions 40 may be axially coupled to one side, the other side, the front side, and the rear side, respectively, of the lens fixing body 301 of the lens portion 30.

As shown in FIG. 7, the measuring unit 70 measures a current value output from the initial setting solar cell 71; The plurality of reflector portions 40 are provided in the upper direction of the plurality of the reflector portions 40 so that the lower portions of the plurality of the reflector portions 40 are rotated in the vertical direction of the lens portion 30, And an angle adjusting unit 80 for adjusting the angle.

The angle adjuster 80 may be of various types, for example, a cylinder.

The upper portion of the cylinder that can form the angle adjusting portion 80 may be axially coupled to one side, the other side, the front side and the rear side of the lens fixing body 301 of the lens portion 30, respectively.

The lower portion of the cylinder, which can form the angle adjusting portion 80, can be axially coupled to the lower portions of the plurality of reflection plate portions 40, respectively.

The control unit 90 compares the current value of the initial setting solar cell 71 measured by the measuring unit 70 with the reference current value for initial setting previously set in the controller 90, Uniformly distributed artificial solar light is transmitted to the initial setting solar cell 71 irrespective of the position of the initial setting solar cell 71 which is intermittently moved in the same manner as the initial setting solar cell 71, The brightness of the angle regulating unit 80 and the sub-ramp 50 can be controlled so as to generate a current value.

When the current value of the initial setting solar cell 71 measured by the measuring unit 70 is less than the initial reference current value, the control unit 90 controls the initial setting solar cell 71 The angle regulating unit 80 is supplied with power from the power supply unit 910 to rotate the lower portions of the plurality of reflector units 40 up and down to transmit a larger amount of artificial solar light to the plurality of reflector units 40 Respectively.

In addition, the amount of power supplied from the power supply unit 910 to the sub-lamp 50 may be increased under the control of the controller 90 so that the intensity of light emitted by the sub-lamp 50 increases.

When the current value of the initial setting solar cell 71 measured by the measuring unit 70 exceeds the reference current value for initial setting, the initial setting solar cell 71 is controlled by the control unit 90, The angle adjusting unit 80 receives power from the power supply unit 910 and rotates the lower portions of the plurality of reflection plate units 40 up and down to transmit a smaller amount of artificial solar light to a plurality of the reflection plate units 40, respectively.

In addition, the amount of power supplied from the power supply unit 910 to the sub-lamp 50 may be reduced under the control of the controller 90 so that the intensity of light emitted by the sub-lamp 50 is reduced .

8 is a partially enlarged side view schematically showing a state in which a solar cell to be measured is positioned in a lower direction of the lens unit by the left and right moving plate unit.

The angle adjusting unit 80 adjusts the angle of the solar cell 7 to be measured in the downward direction of the lens unit 30 with the initial angle of the plurality of the reflector units 40 being set, The left and right moving plate portions 610 can be moved in the other direction of the fixing plate portion 511 as shown in FIG.

Thus, the artificial sunlight condensed by the lens unit 30 can be uniformly transmitted to the entire solar cell of the solar cell 7, and the measurement unit 70 can measure the current The value can be measured.

The current value output from the solar cell 7 measured by the measurement unit 70 is output to a display such as a monitor by a control of the control unit 90 on the screen in letters or numbers, It can be printed out as a number.

The present invention constructed as described above is characterized in that a part of artificial solar light, which is provided on one side, the other side, the front side and the rear side of the lens unit 30 and diffused outwardly of the lens unit 30, Uniform artificial solar light can be transmitted to the entire solar cell of the solar cell 7 through a plurality of the reflection plate portions 40 that transmit the solar cell 7 and the advantage of being able to accurately measure the power generation efficiency of the solar cell 7 .

10; Lamp, 20; Reflector,
30; A lens portion 40; Half wave plate,
50; Auxiliary lamp.

Claims (5)

A lamp for emitting artificial sunlight;
A reflector for reflecting artificial sunlight emitted from the lamp;
A lens unit for condensing the artificial sunlight reflected by the reflector;
A plurality of reflection plate parts provided on one side, the other side, the front side and the rear side of the lens part and having a reflection layer formed on the inside thereof;
An auxiliary lamp provided inside the plurality of reflection plates to emit light;
An initial setting solar cell moving unit for intermittently moving the initial setting solar cell in the forward, backward, left and right directions in a state that the initial setting solar cell receiving the artificial sunlight focused by the lens unit is seated on the upper part;
And a control unit for controlling the initial setting cell moving unit.
A lamp for emitting artificial sunlight;
A reflector for reflecting artificial sunlight emitted from the lamp;
A lens unit for condensing the artificial sunlight reflected by the reflector;
A plurality of reflection plate parts each having an upper part axially coupled to the one side, the other side, the front side and the rear side of the lens part, and a reflection layer formed on the inner side;
An auxiliary lamp provided inside the plurality of reflection plates to emit light;
A measuring unit for measuring a current value output from an initial setting solar cell to which the lens unit collects artificial solar light;
An angle adjusting unit for adjusting the angles of the plurality of reflection plate parts by rotating the lower part of the plurality of reflection plate parts in the vertical direction of the lens part, respectively;
And a control unit for controlling the angle adjusting unit according to a current value of the initial setting solar cell measured by the measuring unit.
A lamp for emitting artificial sunlight;
A reflector for reflecting artificial sunlight emitted from the lamp;
A lens unit for condensing the artificial sunlight reflected by the reflector;
A plurality of reflection plate parts each having an upper part axially coupled to the one side, the other side, the front side and the rear side of the lens part, and a reflection layer formed on the inner side;
An auxiliary lamp provided inside the plurality of reflection plates to emit light;
A measuring unit for measuring a current value output from an initial setting solar cell to which the lens unit collects artificial solar light;
An angle adjusting unit for adjusting the angles of the plurality of reflection plate parts by rotating the lower part of the plurality of reflection plate parts in the vertical direction of the lens part, respectively;
And a control unit for controlling the brightness of the angle adjusting unit and the sub lamp according to a current value of the initial setting solar cell measured by the measuring unit.
The method according to claim 1,
The initial setting solar cell moving part includes a left and right moving plate part on which a solar cell for measuring a current value is mounted on one side of the upper part, and the initial setting solar cell is provided on the other side of the upper part so as to be movable forward,
Left and right moving parts for moving the left and right moving plate parts left and right;
A front and rear moving plate provided on the other side of the upper side of the left and right moving plate so as to be movable back and forth; a back and forth moving member for moving the front and rear moving plate back and forth; A left and right moving plate on which the solar cell is mounted, and left and right moving members for moving the left and right moving plates to move left and right. delete

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