KR101665400B1 - Photovoltaic power generation apparatus - Google Patents

Abstract

The present invention relates to a device for generating solar power comprising a solar cell panel unit which includes a plurality of solar cells generating electricity through incident sunlight, and includes first and second cell panels in which incident sides of sunlight of the solar cells are mutually opposite to each other; a separation frame is installed between the first and second cell panels to prepare a radiant heat space between the first and second cell panels, and separates the first and second cell panels to a mutual separated direction; and a light collecting unit which collects the sunlight and transmits the same to one of the first and second cell panels. The device for generating the solar power is provided to prepare the radiant heat space between the first and second cell panels by using a separation frame; and easily discharge heat generated through the first and second cell panels to the outside through the radiant heat space, thereby preventing deterioration of the first and second cell panels caused by heat generated in a case of generating the solar power.

Description

[0001] The present invention relates to a photovoltaic power generation apparatus,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a solar power generation device, and more particularly, to a solar power generation device in which a heat dissipation space is provided between battery panels provided with sunlight incident surfaces directed in mutually opposite directions.

Power generation using solar energy includes solar power generation that generates electricity using solar light, and solar power generation that collects solar energy as a heat collecting device for heating or hot water.

Among these, solar power generation has advantages that it does not require fuel cost and noise and pollution are not generated unlike existing power plants such as thermal power and nuclear power. In addition, since solar power generation does not require large-scale power generation facilities and can generate small-scale power generation, it can be used for household use.

The photovoltaic power generation apparatus is installed in a large number in a roof, an outdoor slope portion of a building, an upper portion of a parking lot, or an area where utilization of outdoor is low. In order to increase the power generation efficiency of such a photovoltaic device, the incident amount of sunlight to the solar cell must be increased.

However, since the solar cell is required to arrange a plurality of solar cells to receive sunlight in order to produce a large amount of electric power, there is a disadvantage that a relatively large installation space is required. Korean Patent Laid-Open Publication No. 10-2012-0115072 discloses a solar photovoltaic apparatus provided with first and second solar battery panels in which sunlight incident surfaces are arranged in mutually opposite directions in order to reduce installation space.

However, since the solar power generation device is in close contact with the frame on the first and second solar panels, and cooling means for cooling the first and second solar panels is not provided, the solar panels are deteriorated by heat generated during power generation during power generation The power generation efficiency is lowered.

SUMMARY OF THE INVENTION The present invention provides a solar photovoltaic generator, which is designed to solve the above-mentioned problems, and which has a spacing frame for forming a heat dissipation space between first and second battery panels in which sunlight incident surfaces are arranged in mutually opposite directions The purpose is to do.

According to an aspect of the present invention, there is provided a solar photovoltaic device including a plurality of solar cells for generating electricity through incident sunlight, 1 and a second battery panel, and a second battery panel provided between the first and second battery panels so that a heat radiation space is provided between the first and second battery panels, And a light collecting part for collecting the solar light and making the light incident on any one of the first and second battery panels.

Wherein the spacing frame comprises a first spaced bar extending in the spacing direction of the first and second battery panels and having opposite ends fixed to the edges of the first and second battery panels, Wherein the first and second battery panels are provided at positions opposite to the first spacing bars with respect to the center of the panel, wherein both ends of the first and second battery panels are fixed to the opposite edges of the first and second battery panels, And a second spacing bar formed to extend.

The spacing frame may include a heat dissipation plate to which one of the first and second battery panels is fixed on one side and a second heat dissipation plate that is spaced apart from the other side of the heat dissipation plate and extends in a direction away from the heat dissipation plate, And a plurality of heat-radiating ribs to which the other one of the first and second battery panels is fixed.

The spacing frame may include a heat sink disposed between the first and second battery panels, a first heat sink disposed on one side of the heat sink opposite to the first heat sink, A plurality of first heat dissipating ribs to which the first battery panel is fixed at an end thereof and a plurality of second heat dissipating ribs spaced apart from each other on the other side of the heat dissipating plate facing the second battery panel, And a plurality of second heat radiating ribs to which the second battery panel is fixed.

Meanwhile, the solar photovoltaic device according to the present invention is installed on the output terminals of the first and second battery panels, through which the electricity generated through the incident sunlight is outputted, to the difference between the generated amounts of the first and second battery panels And a rechargeable battery connected to the counter electromotive force prevention circuit for charging electricity generated through the first and second battery panels.

The solar battery device according to the present invention includes a first battery connected to a first output terminal of the first battery panel through which electricity generated through sunlight incident on the solar battery is output, A second battery connected to a second output terminal of the second battery panel through which electricity generated through the sunlight incident on the solar battery is output, the second battery being connected to the first and second batteries, And a controller for supplying the electric power charged in the selected one of the first and second batteries to the external electronic device.

The photovoltaic device according to the present invention includes a plurality of first solar cells for generating electricity through incident sunlight, wherein the first solar cells have front and rear surfaces, respectively, on which light receiving surfaces for receiving the sunlight Sided battery panel and a rear surface of the both-sided battery panel. The rear surface of the both-sided battery panel is disposed at a position spaced rearward from the double-sided battery panel so that a heat- And a reflective battery panel having a plurality of second solar cells for reflecting electricity to the rear surface of the double-sided battery panel to generate electricity by the sunlight.

The solar battery device according to the present invention is provided with a heat dissipation space between the first and second battery panels by the spacing frames so that the heat generated through the first and second battery panels through the heat dissipation space is easily discharged So that the first and first battery panels are prevented from being deteriorated by heat generated during power generation.

1 is a perspective view of a photovoltaic device according to an embodiment of the present invention,
FIG. 2 is a plan view of the photovoltaic device of FIG. 1,
3 is a plan view of a photovoltaic device according to another embodiment of the present invention, and FIG.
FIG. 4 is a perspective view of a photovoltaic device according to another embodiment of the present invention, and FIG.
5 is a plan view of a photovoltaic device according to another embodiment of the present invention,
FIGS. 6 and 7 are perspective views of a structure in which the photovoltaic device according to the present invention is mounted,
FIG. 8 is a perspective view of a photovoltaic device according to another embodiment of the present invention, and FIG.
FIG. 9 is a plan view of the photovoltaic device of FIG. 8. FIG.

Hereinafter, a photovoltaic apparatus according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 and 2 show a photovoltaic device 100 according to the present invention.

Referring to FIG. 1, the solar cell generator 100 includes a plurality of solar cells for generating electricity through incident sunlight, and the first and second solar cells 100, The first and second battery panels 111 and 112 are formed to have a solar cell panel 110 having second battery panels 111 and 112 and a heat radiation space between the first and second battery panels 111 and 112, And a light collecting unit 130 for collecting the sunlight and making incident on the second battery panel 112. The light collecting unit 130 collects the sunlight and makes the first and second battery panels 111, And a charging unit 140 for charging electricity generated through the solar panel unit 110. [

The first battery panel 111 is installed in a base frame (not shown), with the sunlight incident surface facing forward. It is preferable that the first battery panel 111 has a predetermined width and is formed to have a predetermined length extending in the vertical direction and a longer length in the vertical direction than the width. The first battery panel 111 is provided with a first output terminal 113 for outputting electricity generated at the lower end to the charging unit 140.

The second battery panel 112 is installed on the base frame at a position opposite to the rear surface of the first battery panel 111, and is provided such that the sunlight incident surface faces rearward. The second battery panel 112 may have a predetermined width corresponding to the first battery panel 111 and may have a predetermined length extending in the up and down direction and a longer length in the up and down direction than the width . The second battery panel 112 is spaced rearward from the first battery panel 111 by a spacing frame 120. A second output terminal for outputting generated electricity to the charging unit 140 is connected to the lower end of the second battery panel 112 114 are provided.

The spacing frame 120 has first and second spacing bars 121 and 122 fixed between the first and second battery panels 111 and 112.

The first spacing bar 121 is fixed to the left and right edges of the first and second battery panels 111 and 112 facing each other. The first and second spacing bars 121 and 121 are spaced apart from the first and second battery panels 111 and 112, The length is extended. The first spacing bar 121 extends in the vertical direction, and preferably extends in a length corresponding to the vertical length of the first and second battery panels 111 and 112. The first spacing bar 121 may be formed of a metal such as aluminum or copper having a good thermal conductivity such as aluminum or copper so that the heat generated from the first and second battery panels 111 and 112 can be easily discharged to the heat- .

The second spacing bar 122 has front and rear ends fixed to the right edges of the first and second battery panels 111 and 112 facing each other and a second spacing bar 122 extending in the front- The length is extended. The second spacing bar 122 extends vertically in correspondence with the first spacing bar 121 and preferably has a length corresponding to the vertical length of the first and second battery panels 111 and 112. In this case, the second spacing bar 122 may be made of a metal having a high thermal conductivity such as aluminum or copper, so that the heat generated from the first and second battery panels 111 and 112 can be easily discharged to the heat- .

The first and second spacing bars 121 and 122 are fixed to the left and right ends of the first and second battery panels 111 and 112 so that the upper and lower portions of the heat dissipating space are opened. 111, 112) generates a chimney effect. That is, the high temperature air in the heat radiation space heated by the first and second battery panels 111 and 112 is discharged to the upper part of the opened heat radiation space, and the outside air flows in through the opened lower part of the heat radiation space, The cooling efficiency of the first and second battery panels 111 and 112 is improved.

The light collecting part 130 is installed on the base frame on the rear side of the second battery panel 112 and extends in an arc shape around the second battery panel 112. The light collecting unit 130 is formed with a reflecting surface for reflecting sunlight incident on the front surface of the second battery panel 112, which is opposite to the rear surface, to the second battery panel 112.

The charging unit 140 is installed on the output terminals of the first and second battery panels 111 and 112 through which the electricity generated through the incident sunlight is output and is connected to the output terminals of the first and second battery panels 111 and 112, And a rechargeable battery 142 connected to the counter electromotive force prevention circuit 141 for charging electricity generated through the first and second battery panels 111 and 112 .

The generated electricity of the first and second battery panels 111 and 112 do not coincide with each other, so that the generated electricity of the first and second battery panels 111 and 112 is overlapped or collapsed to generate counter electromotive force. The battery 142 can be charged with electricity generated from the first and second battery panels 111 and 112 without loss due to the counter electromotive force because the battery 141 blocks the counter electromotive force.

The solar battery 100 according to the present invention constructed as described above is provided with a heat dissipating space between the first and second battery panels 111 and 112 by the spacing frame 120, Since the heat generated through the second battery panels 111 and 112 is easily discharged to the outside, the first and second battery panels 111 and 112 are prevented from being deteriorated by heat generated during power generation.

3, the frame 220 and the charger 240 according to another embodiment of the present invention are provided.

Elements having the same functions as those in the previous drawings are denoted by the same reference numerals.

Referring to the drawings, the separation frame 220 further includes auxiliary separation bars 221 provided between the first and second separation bars 121 and 122.

The auxiliary spacing bars 221 are fixed to the front and rear ends of the center portions of the first and second battery panels 111 and 112 facing each other and are spaced apart from the first and second battery panels 111 and 112 in the forward and backward directions The length is extended. The auxiliary spacing bar 221 extends in the vertical direction corresponding to the first and second spacing bars 121 and 122 and preferably extends in a length corresponding to the vertical length of the first and second battery panels 111 and 112 . At this time, the auxiliary spacing bar 221 is formed of a metallic material having excellent thermal conductivity such as aluminum or copper so that heat generated from the first and second battery panels 111 and 112 can be easily discharged to the heat dissipation space. There is an advantage that the thermal contact area with the air in the heat dissipation space is expanded by the auxiliary spacing bar 221 to improve the cooling efficiency.

In the illustrated example, a structure in which one auxiliary spacing bar 221 is provided between the first and second spacing bars 121 and 122 has been described. However, the number of the auxiliary spacing bars 221 is limited to the illustrated example It is possible to install more than one.

The charging unit 240 includes a first battery 241 connected to the first output terminal 113 of the first battery panel 111 to charge the electricity and a second battery 241 connected to the second output terminal A second battery 242 connected to the first and second batteries 241 and 242 and connected to the first and second batteries 241 and 242 to charge the electricity, And a control unit 243 for supplying electricity to the external electronic device.

The first and second batteries 241 and 242 are respectively connected to the first and second output terminals 113 and 114 through first and second controllers. The first and second controllers are connected to the first and second battery panels 111, and 112 are stably supplied to the first and second batteries 241 and 242, respectively.

The controller 243 controls the charging of the first and second batteries 241 and 242 through a charging sensor (not shown) installed in the first and second batteries 241 and 242 and sensing a charged amount of the first and second batteries 241 and 242, And supplies electric power to the external electronic device by electrically connecting the battery charged with more electricity among the first and second batteries 241 and 242 to the external electronic device based on the charged amount data.

As described above, the charger 240 connects the first and second batteries 241 and 242 to the first and second battery panels 111 and 112, respectively, to generate a difference in electric power generated between the first and second battery panels 111 and 112 It is possible to prevent the charged amount of electricity from decreasing due to the counter electromotive force generated by the battery.

4, a spacer frame 320 according to another embodiment of the present invention is shown.

Referring to the drawings, the spacing frame 320 includes a heat dissipating plate 321 to which a second battery panel 112 is fixed on the rear surface, and a plurality of heat dissipating plates 321 spaced apart from each other on the entire surface of the heat dissipating plate 321. And a plurality of heat dissipating ribs 322 extending toward the front and spaced apart from each other and fixing the first battery panel 111 at the end thereof.

The heat radiating plate 321 extends in the left and right direction with a length corresponding to the width of the second battery panel 112 and extends in the vertical direction with a length corresponding to the length of the second battery panel 112 in the vertical direction. The second battery panel 112 is not shown in the figure, but is fixed to the back surface of the heat sink 321 by bonding or bolting. The heat sink 321 is preferably formed of a metallic material having excellent thermal conductivity such as aluminum or copper so that the heat generated from the second battery panel 112 can be easily discharged to the heat dissipation space.

The heat dissipating ribs 322 are spaced apart from each other along the left and right directions on the front surface of the heat sink 321 so that a plurality of heat dissipating spaces are provided in front of the heat sink 321, In the vertical direction. At this time, it is preferable that the heat dissipating ribs 322 are formed of a metallic material having excellent thermal conductivity such as aluminum or copper, like the heat dissipating plate 321. The spacing frame 320 configured as described above has a plurality of heat dissipating ribs 322 that increase the thermal contact area with the outside air of the heat dissipating space to improve the cooling efficiency for the first and second battery panels 111 and 112 There are advantages.

Although the second battery panel 112 is fixed to the rear surface of the heat sink 321 and the heat dissipating ribs 322 are formed on the front surface of the heat sink 321, The first battery panel 111 is fixed to the front surface of the heat sink 321 and a plurality of heat sink ribs 322 are formed on the rear surface of the heat sink 321. The heat sink 322 The second battery panel 112 may be fixed to an end of the second battery panel 112. [

Meanwhile, FIG. 5 illustrates a spacer frame 330 according to another embodiment of the present invention.

Referring to the drawings, the spacing frame 330 includes a heat radiating plate 331 positioned between the first and second battery panels 111 and 112, a front surface 331 of the heat radiating plate 331 facing the first battery panel 111, A plurality of first heat radiating ribs 332 extending in a direction away from the heat radiating plate 331 and having the first battery panel 111 fixed at an end thereof, And a plurality of second heat dissipation plates 331 extending in a direction away from the heat dissipation plate 331 and having the second battery panel 112 fixed to the end thereof, And a rib 333.

The heat radiating plate 331 extends in the left and right direction with a length corresponding to the width of the first and second battery panels 111 and 112 and has a length corresponding to the length of the first and second battery panels 111 and 112, . The heat radiating plate 331 is preferably formed of a metallic material having excellent thermal conductivity such as aluminum or copper so that the heat transmitted from the first and second heat radiating ribs 332 and 333 can be easily discharged to the heat radiating space.

The first heat radiating ribs 332 are spaced from each other along the left and right directions on the front surface of the heat sink 331 so as to provide a plurality of heat radiating spaces in front of the heat sink 331, And extends in the vertical direction with a length corresponding to the direction length. At this time, the first heat-radiating ribs 332 are preferably formed of a metallic material having excellent thermal conductivity, such as aluminum or copper, like the heat-radiating plate 331.

The second heat dissipating ribs 333 are spaced apart from each other along the left and right directions on the rear surface of the heat dissipating plate 331 so as to provide a plurality of heat dissipating spaces behind the heat dissipating plate 331, And extends in the vertical direction with a length corresponding to the direction. At this time, the second heat-radiating ribs 333 are preferably formed of a metallic material having excellent thermal conductivity, such as aluminum or copper, like the heat sink 331.

The spacing frame 330 configured as described above is formed by the plurality of first and second heat dissipating ribs 332 and 333 so that the thermal contact area with the outside air of the heat dissipating space is increased to increase the thermal contact area of the first and second battery panels 111 and 112 The cooling efficiency is improved.

6 shows a structure in which the solar cell generator 100 according to the present invention is fixed to a pillar installed on a road.

Referring to the drawings, the solar panel part 110 and the light collecting part 130 are fixed to the support by the base frame 210. The base frame 210 includes a plurality of first support bars 211 for fixing the spacing frame 120 and the light collecting unit 130 to each other, a plurality of second support bars 212 fixed to the support, Respectively. One end of the first support bar 211 is fixed to the spacing frame 120 and the other end thereof is fixed to the light collecting part 130 facing the spacing frame 120. The first support bars 211 are installed at left and right upper and lower right and left sides of the separation frame 120, respectively. The second support bar 212 has one end fixed to the support and the other end fixed to the rear surface of the light collecting part 130 facing the support. The plurality of second support bars 212 are spaced apart from each other along the vertical direction at the upper end of the support. As shown in the drawing, the solar power generator 100 according to the present invention is installed at the upper end of the strut of the street lamp and the sign, and can generate electricity through incident sunlight.

7 shows a structure in which the solar cell 100 according to the present invention is installed on the ground.

Referring to the drawing, the solar panel part 110 and the light collecting part 130 are supported on the ground by the base frame 220. The base frame 220 includes a fixing plate 221 fixed to the ground surface, a plurality of first supporting members 222 mounted on the upper surface of the fixing plate 221 to support the solar cell panel, And a plurality of second support members 223 which are provided on the upper surface of the rear side fixing plate 221 and support the light collecting unit 130. [ The lower end of the first support member 222 is fixed to the upper surface of the fixing plate 221 and the other end is fixed to the spacing frame 120 and extended upward. The lower end of the second support frame is fixed to the upper surface of the fixing plate 221 and the other end is fixed to the lower end of the light condensing part 130 and extends upward by a predetermined length. The solar panel part 110 and the light collecting part 130 are supported by the base frame 220 so as to be supported on the ground instead of the ground.

8 and 9 illustrate a photovoltaic device 400 according to another embodiment of the present invention.

Referring to the drawings, a solar power generator 400 includes a frame (not shown), a double-sided battery panel 410 disposed on the frame, spaced apart from each other in the front-rear direction so as to provide a heat- And a charging unit for charging the electricity generated through the double-sided battery panel 410 and the reflective battery panel 420. [

The double-sided battery panel 410 includes a plurality of first solar cells 411 that extend upward with respect to the frame and generate electricity through incident sunlight. At this time, the first solar cell 411 has front and rear surfaces on which light receiving surfaces for receiving sunlight are formed. A first terminal for drawing out the electricity generated from the first solar cells 411 to the outside is provided on the lower end of the double-sided battery panel 410.

The reflective battery panel 420 is installed in a frame spaced rearward from the double-sided battery panel 410 so as to provide the heat radiation space at the rear of the double-sided battery panel 410, Respectively.

At this time, the reflective battery panel 420 is curved in an arcuate shape about the double-sided battery panel 410, and the incident sunlight is applied to the front surface of the double-sided battery panel 410, A plurality of second solar cells 422 are provided so as to generate electricity by the sunlight.

The second solar cells 422 generate electricity by sunlight incident on the front surface of the reflective battery panel 420, and a part of the sunlight is reflected to the rear surface of the double-sided battery panel 410. In addition, a second terminal for extracting electricity generated from the second solar cells 422 to the outside is installed on the lower side of the reflective battery panel 420.

A heat radiation space is provided between the double-sided battery panel 410 and the reflective battery panel 420 configured as described above, and the heat generated by the heat generated from the double-sided battery panel 410 and the reflective battery panel 420 A chimney effect is generated. That is, the hot air in the heat radiation space heated by the double-sided battery panel 410 and the reflective battery panel 420 is discharged to the upper portion of the opened heat release space, and the outside air flows in through the opened lower portion of the heat radiation space, The cooling efficiency of the double-sided battery panel 410 and the reflective battery panel 420 is improved.

The charging unit 440 is installed on the first and second terminals of the double-sided battery panel 410 and the reflective battery panel 420 to output electricity generated through incident solar light, Side battery panel 410 and the reflective battery panel 420 connected to the counter electromotive force prevention circuit portion 441. The back electromotive force prevention circuit portion 441 blocks the back electromotive force generated according to the difference in the amount of electricity generated by the battery panel 420, And a rechargeable battery 442 for recharging the electricity generated by the rechargeable battery.

The developed electricity of the double-sided battery panel 410 and the reflective battery panel 420 does not match the voltage or impedance of the developed electricity, so that the developed electricity of the double-sided battery panel 410 and the reflective battery panel 420 are overlapped or crossed with each other, The counter electromotive force preventing circuit part 441 blocks the counter electromotive force so that the electricity generated from the both-side battery panel 410 and the reflecting battery panel 420 can be charged into the rechargeable battery 442 without loss due to the counter electromotive force.

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.

Accordingly, the true scope of protection of the present invention should be determined only by the appended claims.

100: Photovoltaic device
110: Solar panel section
111: first battery panel
112: second battery panel
120: spacing frame
121: first separation bar
122: second separation bar
130: Concentrator
140:

Claims (7)

A solar cell panel unit having a plurality of solar cells for generating electricity through incident sunlight, the solar panel unit including first and second battery panels arranged such that sunlight incident surfaces of the solar cells are opposite to each other;
A spacing frame installed between the first and second battery panels so that a heat dissipation space may be provided between the first and second battery panels to separate the first and second battery panels from each other in a direction away from each other;
And a condensing unit condensing the sunlight and making incident on the second battery panel,
Wherein the light collecting unit is installed in an arcuate shape behind the second battery panel and has a reflecting surface for reflecting incident sunlight to the second battery panel.
The method according to claim 1,
The spacing frame
The first and second battery panels having opposite ends fixed to the edges of the first and second battery panels, respectively, the first and second spacing bars extending in the spacing direction of the first and second battery panels,
Wherein the first and second battery panels are provided at positions opposite to the first spacing bar with respect to the center of the first and second battery panels, respectively, both ends of the first and second battery panels being fixed to the edges of the first and second battery panels, And a second spacing bar extending in the direction of separation of the two battery panels.
The method according to claim 1,
The spacing frame
A heat sink having one side thereof fixed to one of the first and second battery panels,
And a plurality of heat dissipating ribs spaced apart from each other on the other side of the heat dissipating plate and extending in a direction away from the heat dissipating plate and having the other one of the first and second battery panels fixed to the end thereof. Photovoltaic device.
The method according to claim 1,
The spacing frame
A heat sink disposed between the first and second battery panels,
A plurality of first heat dissipating ribs spaced from each other on a side surface of the heat dissipating plate facing the first battery panel, the first heat dissipating ribs extending in a direction away from the heat dissipating plate,
And a plurality of second heat radiating ribs spaced apart from each other on the other side of the heat sink facing the second battery panel and extending in a direction away from the heat sink and having the second battery panel fixed to the end thereof A photovoltaic device characterized by.
5. The method according to any one of claims 2 to 4,
A back electromotive force preventing circuit unit installed at output terminals of the first and second battery panels for outputting electricity generated through incident sunlight to block back electromotive force generated according to a difference in the amount of generated electricity of the first and second battery panels; ;
And a rechargeable battery connected to the counter electromotive force prevention circuit for charging electricity generated through the first and second battery panels.
5. The method according to any one of claims 2 to 4,
A first battery connected to a first output terminal of the first battery panel through which electricity generated through sunlight incident on the solar battery is output, to charge the electricity;
A second battery connected to a second output terminal of the second battery panel through which electricity generated through solar light incident on the solar battery is output, to charge the electricity;
Further comprising a control unit connected to the first and second batteries and supplying the electric power charged in any one of the first and second batteries to an external electronic device.
A double-sided battery panel having a plurality of first solar cells for generating electricity through incident sunlight;
And a reflective battery panel installed at a position spaced rearward from the double-sided battery panel so that a heat radiation space is provided behind the double-sided battery panel,
Wherein the first solar cell of the double-sided battery panel has front and rear surfaces on which a light receiving surface for receiving the sunlight is formed,
A plurality of second solar cells are provided on the front surface of the reflective battery panel facing the rear surface of the double-sided battery panel to reflect incident sunlight to the rear surface of the double-sided battery panel and generate electricity by the sunlight And a solar cell.

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