KR101927828B1 - Solar photovoltaic power generation module having multi-layered structure - Google Patents

Abstract

According to an embodiment of the present invention, a photovoltaic power generation module having a multi-layered structure comprises: a first double-sided solar battery panel including a plurality of unit modules including a top surface solar battery cell and a bottom surface solar battery cell arranged at the lower side corresponding to the top surface solar battery cell; a second double-sided solar battery panel which is separated to the bottom of the first double-sided solar battery panel, and which includes a plurality of unit modules including a top surface solar battery cell and a bottom surface solar battery cell which is arranged at the lower side corresponding to the top surface solar battery cell; and a one-surface solar battery panel which is separated to the bottom of the second double-sided solar battery panel and includes a plurality of unit modules including a top surface solar battery cell. Each of the first double-sided solar battery panel and the second double-sided solar battery panel is arranged to be separated by a predetermined interval from a unit module neighboring a planar second direction crossing a first direction, while the unit modules are continuously arranged in the planar first direction. The second double-sided solar battery panel is arranged such that a unit module of the second double-sided solar battery panel is partially crossed with a unit module of the first double-sided solar battery panel directly under a gap of the first double-sided solar battery panel, so that sunlight can be incident on the top surface solar battery cell of the second double-sided solar battery panel through a gap of the first double-sided solar battery panel.

Description

SOLAR PHOTOVOLTAIC POWER GENERATION MODULE HAVING MULTI-LAYERED STRUCTURE [0002]

The present invention relates to a solar cell module having a multilayer structure, and more particularly, to a solar cell module having a plurality of double-sided solar cell panels stacked in a vertical direction, The sunlight incident on the gap can be received by the lower solar cell panel and sunlight incident through the gap of the lower solar cell panel can be received by the lower solar cell panel to maximize the efficiency of solar power generation , And a solar cell module having a multi-layer structure.

The solar cell module is a semiconductor device that converts light energy into electrical energy using photoelectric effect, and it is getting popular recently because it is pollution-free, noiseless, and unlimited supply energy. In particular, in order to prevent global warming, the Tokyo Protocol, which regulates greenhouse gas emissions such as carbon dioxide and methane gas, came into effect on February 16, 2005. In Korea, where solar energy accounts for more than 80% It is one of the energy sources.

1 is a perspective view showing a conventional solar cell module. Referring to the drawings, a conventional solar cell module 10 'has a plurality of solar cells 11' for generating solar power on one side thereof, and the solar cell 11 ' It is generally arranged to be perpendicular to the direction S in which sunlight is incident to optimize.

However, since the solar cell module 10 'according to the related art is arranged perpendicular to the direction S in which the sunlight is incident, the number of the solar cell modules 10' is limited in the limited space, thereby limiting the total energy generation capacity in terms of space.

Accordingly, there is a need to develop a photovoltaic module having a new structure capable of increasing the efficiency of photovoltaic power generation.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned needs, and it is an object of the present invention to provide a solar cell module and a solar cell module, which are capable of receiving solar light from a plurality of solar cell panels, Module.

The objects of the present invention are not limited to those mentioned above, and other objects not mentioned may be clearly understood by those skilled in the art from the following description.

According to an aspect of the present invention, there is provided a solar cell module including a plurality of unit modules each including a top solar cell and a bottom solar cell disposed below the top solar cell, A first double-sided solar cell panel comprising; A second double-sided solar cell including a plurality of unit modules disposed below the first double-sided solar cell panel and including a top solar cell and a bottom solar cell disposed below the top solar cell, panel; And a single-sided solar cell panel spaced below the second double-sided solar cell panel, the single-sided solar cell panel including a plurality of unit modules including a top-side solar cell, Each of the solar panels is arranged so as to be spaced apart from a neighboring unit module by a gap of a predetermined interval in a second direction on a plane intersecting with the first direction, , And the second double-sided solar cell panel is configured such that solar light can enter the upper surface solar cell of the second double-sided solar cell panel through the gap of the first double- And the unit module is disposed so as to be offset from the unit module of the first double-sided solar cell panel in a portion directly under the gap of the first double-sided solar cell panel.

The first double-sided solar cell panel and the second double-sided solar cell panel may further include a surface layer disposed below the top and bottom surface solar cells of the top surface solar cell, Wherein a surface layer is further formed on the lower surface of the first double-sided solar cell panel, a surface layer on the lower surface of the first double-sided solar cell panel, upper and lower surface layers of the second double- .

The net type reflector may be composed of a reflective portion for reflecting sunlight and at least one transmissive portion having a position corresponding to the upper or lower surface solar cell.

A plurality of unit modules including a plurality of unit modules each including a top solar cell and a bottom solar cell disposed below the top solar cell, are provided between the second double-sided solar cell panel and the one- 3 double sided solar panels; And a fourth double-sided solar cell including a plurality of unit modules disposed below the third double-sided solar cell panel and including a top solar cell and a bottom solar cell disposed below the top solar cell, The solar cell module according to any one of claims 1 to 3, wherein the first and second solar cell modules are arranged in a first direction along a first direction on a plane, And the third double-sided solar cell panel is arranged so as to be spaced apart by a gap of a predetermined interval so that sunlight can be incident on the upper surface solar cell of the third double-sided solar cell panel through the gap of the second double- Wherein a unit module of the third double-sided solar cell panel is disposed so as to be located directly below a gap of the second double-sided solar cell panel, and the fourth double- Sided solar cell panel so that the unit module of the fourth both-sided solar cell panel can be directly incident on the top-side solar cell of the fourth-sided solar cell panel through the gap of the third, Can be arranged to be located in the room.

In addition, the third and the second both-side solar cell panels may have a surface layer formed below the upper and lower surface solar cells of each of the upper and lower surface solar cells, A net-like reflector may be attached to the lower surface layer and the upper and lower surface layers of the fourth both-side solar cell panel.

In addition, each of the double-sided solar panels and the single-sided solar panels can be fixed in a state of being vertically spaced apart from each other by a transparent vertical panel outside the frame.

According to the solar cell module having the multi-layer structure according to the embodiment of the present invention, solar light incident on the gap of the upper solar cell panel is received by the lower solar cell panel and incident through the gap of the lower solar cell panel The sunlight can be received by the lower solar cell panel, thereby maximizing the efficiency of solar power generation.

The effects of the present invention are not limited to those mentioned above, and other effects not mentioned can be clearly understood by those skilled in the art from the following description.

1 is a perspective view showing a conventional solar cell module.
2 is a cross-sectional view of a solar cell module having a multi-layer structure according to an embodiment of the present invention.
3 is a conceptual view showing a cross-sectional structure of a surface layer adhered to a double-sided solar cell panel of the present invention.
FIG. 4 is a conceptual view illustrating a lamination structure of a solar cell module having a multi-layer structure according to an embodiment of the present invention.
5 is a plan view of a double-sided solar cell panel and a net type reflector according to an embodiment of the present invention.
6 is a plan view of a double-sided solar cell panel and a net type reflector according to an embodiment of the present invention.
FIG. 7 is a conceptual diagram for explaining various types of incident and reflected sunlight in the solar cell module having the multi-layer structure shown in FIG. 2. FIG.
8 is a cross-sectional view of a photovoltaic module having a multi-layer structure according to another embodiment of the present invention.
FIG. 9 is a conceptual diagram for explaining various types of incident and reflected sunlight in the solar cell module of the multi-layer structure shown in FIG.

BRIEF DESCRIPTION OF THE DRAWINGS The above and other objects, features and advantages of the present invention will be more apparent from the following detailed description taken in conjunction with the accompanying drawings, in which: FIG. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unnecessary. The terms described below are defined in consideration of the structure, role and function of the present invention, and may be changed according to the intention of the user, the intention of the operator, or the custom.

The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. These embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art to which the present invention pertains, It is only defined by the scope of the claims. Therefore, the definition should be based on the contents throughout this specification.

Throughout the specification, when an element is referred to as "comprising ", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise.

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

FIG. 2 is a cross-sectional view of a solar cell module having a multi-layer structure according to an embodiment of the present invention, FIG. 3 is a conceptual view illustrating a cross-sectional structure of a surface layer attached to a double- FIG. 3 is a conceptual view illustrating a stacked structure of a solar cell module having a multi-layer structure according to an embodiment. Referring to these figures, the solar cell module 100 of the present invention has a first double-sided solar cell panel 110 at the top, a second double-sided solar cell panel 120 at the middle, Panel 150 as shown in FIG. Each double-sided solar cell panel and single-sided solar cell panel 150 is configured to receive solar light to produce electric energy, and includes a plurality of unit modules in which a plurality of solar cells are arrayed. The photovoltaic cell is composed of a p-type semiconductor and an n-type semiconductor. When the photovoltaic cell receives sunlight, electrons and cogs are generated in the p-type and n-type semiconductors, and electromotive force is generated by the internal electric field in the pn junction region. . Since the voltage required for practical use is several tens to several hundreds of volts or more, the voltage from one cell is very small, about 0.5 V, so that a plurality of solar cells are connected in series or parallel in a required unit capacity and used in the form of a unit module .

First, the first double-sided solar cell panel 110 is disposed at the uppermost position of the solar cell module to receive solar light primarily, and is composed of a plurality of unit modules. Each of the unit modules includes a plurality of upper surface solar cell cells 102 and a plurality of lower surface solar cell cells 104 disposed below and corresponding to the upper surface solar cell 102, respectively. At this time, the first double-sided solar cell panel 110 receives direct sunlight from the sun by the top solar cell 102 to generate electric energy. On the other hand, the bottom solar cell 104 receives the reflected light reflected from the second double-sided solar cell panel 120 by the sunlight incident on the gap G of the first double-sided solar cell panel 110 , And is configured to generate electric energy from the reflected light.

In the first double-sided solar cell panel 110, a surface layer is further formed above the upper surface solar cell 102 and below the lower surface solar cell 104. More specifically, the first double-sided solar cell panel 110 includes an upper surface layer 101, an upper surface solar cell 102, a separator 103, a lower surface solar cell 104, a lower surface layer 105 ).

At this time, the lower surface layer 105 and the upper surface layer 101 are layers for absorbing maximum solar energy even when the incident angle of sunlight changes, and the multi-directional energy absorbing surface layer 11, the inductive layer 12, (13) may be stacked. 3 is a conceptual view showing a cross-sectional structure of a surface layer adhered to a double-sided solar cell panel of the present invention.

The absorbent surface layer 11 is formed in various shapes such as a pyramid-like horn or a truncated cone-like shape, a semispherical protruding shape or a plate-like film shape, and the material is processed into a hologram plate shape by using a laser- It has a refractive index that can be placed on the solar cell surface in any direction. That is, when the incident angle of sunlight to the absorbing surface layer is lowered, the amount of reflection from the absorptive surface layer is increased and the amount of light supplied to the surface of the solar cell is small, so that when the projecting portion is formed on the surface of the absorbing surface layer, The incidence angle of the protruding portion and the sunlight is increased so that the amount of reflection on the absorbing surface layer is reduced and finally the amount of light supplied to the surface of the solar cell is increased.

For this reason, when a conventional solar cell module is installed at a fixed angle of 30 degrees in the Jeollanam-do, the maximum power can be produced at about 12:00, when the sunlight is perpendicular to the solar cell module. When the altitude of the sunlight changes, such as summer, autumn, winter, it will not absorb the maximum amount of sunlight energy reaching the ground.

However, the absorption surface layer 11 described above is intended to absorb solar light energy reaching the ground to the maximum even if the direction and altitude of the sun light change depending on time and season. The material of the absorptive surface layer can be a material such as glass, an acrylic plate and a PET film that can increase the transmittance, and is structurally processed into a hologram plate form. Also, the thickness of the absorbing surface layer can be used regardless of the thickness if the transmittance of sunlight can be secured to 90% or more. When the absorbing surface layer is processed in the form of film using PET or the like, the solar cell is protected from external physical factors A glass layer may be formed on the uppermost layer to form a bonded single absorption surface layer.

In addition to the absorbing surface layer 11, the inductive layer 12 and the diffusing layer 13 can also be combined with a laser processing technique that is configured in the form of a hologram plate and can diffuse uniformly with a desired refractive index using a polymer. As the material of the induction layer and the diffusion layer, PET (Polyethylen Terephthalate) or OPP (Oriented Polypropylene) can be used, and it can be processed into a film form. The solar light passing through the inductive layer and the diffusion layer is refracted while the medium passes through the other layer due to its optical characteristics, and light is diffused by diffusing light according to the material properties of PET or OPP. In addition, the absorbing surface layer, the induction layer, and the diffusion layer may be formed of a single composite layer and may be provided in the form of a sheet material or a film.

When the surface layer having the above-described structure is attached to the double-sided solar cell panel, the maximum solar energy is always absorbed even when the incident angle of the sunlight varies with time according to the season. In addition, even when installed in a fixed manner, the installation cost and maintenance cost of the tracking device can be reduced because the performance of the solar cell module is significantly improved.

On the other hand, the second double-sided solar cell panel 120 is spaced below the first double-sided solar cell panel 110 and receives sunlight incident on the gap G of the first double-sided solar cell panel 110 Thereby producing electrical energy. The second double-sided solar cell panel 120 is composed of a plurality of unit modules, and each unit module includes a plurality of top solar cell units 102, a plurality of downwardly disposed solar cell units 102 corresponding to the top solar cell units 102, And includes a solar cell (104). The structure of the second double-sided solar cell panel 120 is the same as that of the first double-sided solar cell panel 110. More specifically, the second double-sided solar cell panel 120 also includes an upper surface layer 101, a top surface solar cell 102, a separation plate 103, a bottom surface solar cell 104, and a bottom surface layer 105 ). Like the first double-sided solar cell panel 110, the lower surface layer 105 and the upper surface layer 101 may be formed by laminating the above-described multi-directional energy-absorbing surface layer, an induction layer, and a diffusion layer.

On the other hand, the one-sided solar cell panel 150 is located below the second double-sided solar cell panel 120 and receives solar light incident on the gap G of the second double-sided solar cell panel 120, . The single-sided solar cell panel 150 includes a plurality of unit modules, each unit cell including a plurality of top-side solar cells 102. The upper surface layer 101, the upper surface solar cell 102, the lower surface layer 104, the upper surface layer 106, the lower surface layer 104, the lower surface layer 106, and the lower surface layer 104 are formed on the upper surface solar cell 102. [ 105). Like the first double-sided solar cell panel 110, the lower surface layer 105 and the upper surface layer 101 may be formed by laminating the above-described multi-directional energy-absorbing surface layer, an induction layer, and a diffusion layer.

As shown in FIG. 5, the first and second double-sided solar cell panels 110 and 120 are sequentially arranged along a first direction on a plane, And may be spaced apart from a neighboring unit module by a predetermined gap G in a second direction on a plane intersecting the first direction. It is possible to enter the solar cell panel in which the sunlight is disposed downward through the gap G between the unit modules. To this end, the second double-sided solar cell panel 120 is configured such that solar light is transmitted through the gap G of the first double-sided solar cell panel 110 to the second double-sided solar cell panel 120, The unit module of the second double-sided solar cell panel 120 is disposed so as to be positioned directly below the gap G of the first double-sided solar cell panel 110 so as to be incident on the upper surface solar cell 102 of the first double- The one-sided solar cell panel 150 is configured to allow solar light to enter the upper surface solar cell 102 of the one-sided solar cell panel 150 through the gap G of the second double- , The unit module of the one-sided solar cell panel 150 is disposed so as to be located directly below the gap G of the second both-sided solar cell panel 120.

On the other hand, the single-sided solar cell panel 150 also has a plurality of unit modules arranged consecutively along a first direction on a plane, and spaced apart from a neighboring unit module by a gap G of a predetermined interval in a second direction on a plane . However, the one-sided solar cell panel 150 is arranged in the lowermost room, and the gap G through which sunlight is transmitted is formed narrower than the first or second double-sided solar cell panel 120, And may be continuously arranged with neighboring unit modules.

The lower surface of the lower surface layer 105 of the first double-sided solar cell panel 110 and the lower surface layer 105 of the upper surface layer 101 of the second double-sided solar cell panel 120, Type reflecting mirror 106 is further provided on the upper surface of the upper surface layer 101 of the light guide plate 150. The reflector reflects the sunlight incident on the gap G of the upper solar cell panel so as to be incident on the back surface of the solar cell panel. In addition, the reflector reflects the light incident on the back surface of the solar cell panel and reflects the incident light to the solar cell panel. It is preferable that the reflector is formed of a mirror material whose surface can reflect sunlight by 90% or more. At this time, the reflector according to the present invention adopts a net-like structure. Referring again to Fig. 5, the net type reflector 106 includes a transmissive portion 106b together with a reflective portion 106a. The transmissive portion 106b is formed at a position corresponding to the unit module of the solar cell panel, in which at least one transmissive portion 106b is opened to the reflector of the flat panel type. For example, as shown in FIG. 5, when a plurality of unit modules are consecutively arranged along the first direction, and the unit modules arranged in this manner are spaced apart along the second direction, The transmissive portions 106b have openings that are continuous along the first direction to correspond to the unit modules, and these openings are formed along the second direction. Referring to FIG. 6, a plurality of unit modules constituting the double-sided solar cell panel may be disposed apart from neighboring unit panels along the first direction and the second direction. In this case, the transmissive portion 106b of the net-like reflector 106 attached to the solar cell panel has a shape in which opening portions are spaced apart from each other along the first direction and the second direction to correspond to the unit module.

On the other hand, the first and second double-sided solar cell panels 120 and the single-sided solar cell panel 150 are fixed in a state of being vertically spaced apart from each other by a transparent vertical panel 160. The vertical panel 160 is made of a transparent material and can transmit sunlight to enter the solar panel in the power generation module.

The solar cell module 100 of the multi-layered structure having such a structure is constructed by stacking the first and second double-sided solar cell panels 120 and the single-sided solar cell panels 150 in the vertical direction, The sunlight incident on the gap G of the solar cell panel disposed above is received by the lower solar cell panel and sunlight incident through the gap G of the lower solar cell panel is received It is possible to receive it from the solar panel below. FIG. 7 is a conceptual diagram for explaining various types of incident and reflected sunlight in the solar cell module 100 of the multi-layer structure shown in FIG. Referring to the drawing, the sunlight incident on the solar cell module 100 may be incident on the first double-sided solar cell panel 110 according to the position of the sun, may be transmitted through the vertical panel 160, Panel or the one-sided solar cell panel 150, as shown in Fig.

The first double-sided solar cell panel 110 generates electric energy from sunlight incident on the upper surface solar cell 102. At this time, sunlight is incident through the upper surface layer of the first double-sided solar cell panel 110, so that it is possible to absorb maximum sunlight irrespective of the incident angle. The solar light that has passed through the gap G of the first double-sided solar cell panel 110 passes through the transmission portion 106b of the net-like reflector 106 of the first double-sided solar cell panel 110, As shown in FIG. 1) Solar light incident on the reflecting portion 106a of the net-like reflector 106 attached to the second double-sided solar cell panel 120 is incident on the back surface of the first double-sided solar cell panel 110 And is incident on the bottom solar cell 104 of the first double-sided solar cell panel 110 through the transmissive portion 106b of the net-like reflector 106 attached to the first double-sided solar cell panel 110. [ At this time, when the reflected sunlight is incident on the reflecting portion 106a of the net-like reflector 106 of the first double-sided solar cell panel 110, the reflected sunlight is reflected again toward the second double- The solar cell of the first or second double-sided solar cell panel 120 is incident on the solar cell through the reflection and the reflection, thereby producing electric energy. 2) Solar light incident on the transmission portion 106b of the net-like reflector 106 attached to the second double-sided solar cell panel 120 is incident on the solar cell of the second double-sided solar cell panel 120 , Thereby producing electrical energy.

The sunlight passing through the gap G of the second double-sided solar cell panel 120 passes through the transmission portion 106b of the net-like reflector 106 of the second double-sided solar cell panel 120, As shown in FIG. 1) solar light incident on the reflecting portion 106a of the net type reflecting mirror 106 attached to the one-sided solar cell panel 150 is reflected to the back side of the second double-sided solar cell panel 120 And is incident on the bottom solar cell 104 of the second double-sided solar cell panel 120 through the transmissive portion 106b of the net-like reflector 106 attached to the second double-sided solar cell panel 120. At this time, when the reflected sunlight is incident on the reflecting portion 106a of the net-like reflecting mirror 106 of the second double-sided solar cell panel 120, the reflected sunlight is reflected again toward the single- And is incident on the solar cell of the second or one-sided solar cell panel 150 through such reflection and re-reflection, thereby producing electrical energy. 2) Solar light incident on the transmissive portion 106b of the net-like reflector 106 attached to the one-sided solar cell panel 150 is incident on the solar cell of the one-sided solar cell panel 150, It produces energy.

According to this structure, the sunlight incident on the gap G of the solar cell panel disposed above is received by the solar cell panel below, and the solar cell cell of the solar cell panel is incident through the net- It is possible to maximize the light receiving efficiency of solar light by selectively re-reflecting sunlight that is not sunlight.

8 is a sectional view of a solar cell module 100 having a multi-layer structure according to another embodiment of the present invention. FIG. 9 is a cross-sectional view of a solar cell module 100 having a multi- And reflection. Referring to these figures, a solar cell module 100 of a multi-layer structure according to another embodiment of the present invention includes a second double-sided solar cell panel 120 and a first single-sided solar cell panel 150, And may further include a solar cell panel 130 and a fourth double-sided solar cell panel 140.

The third double-sided solar cell panel 130 includes a plurality of unit modules including a top solar cell 102 and a bottom solar cell 104 disposed below the top solar cell 102. The fourth double-sided solar cell panel 140 is spaced below the third double-sided solar cell panel 130 and is disposed below the top and bottom solar cells 102 and 102, And a plurality of unit modules including the battery cells 104. The third and fourth double-sided solar cell panels 140 are arranged such that the unit modules are arranged continuously along the first direction in the plane, and in the second direction on the plane, by a gap G of a predetermined interval from the adjacent unit modules Can be spaced apart. The third and the second both-side solar cell panels 130 and 140 further have a surface layer formed above the upper surface solar cell 102 and below the lower surface solar cell 104, respectively. The specific internal structure of the third and fourth double-sided solar cell panels 130 and 140 is the same as that of the first or second double-sided solar cell panel 120. 8, the third double-sided solar cell panel 130 is formed such that the sunlight is transmitted through the gap G of the second double-sided solar cell panel 120 to the third double-sided solar cell panel 130 The unit module of the third double-sided solar cell panel 130 is disposed so as to be positioned directly below the gap G of the second double-sided solar cell panel 120 so as to be incident on the upper surface solar cell 102, 4 double-sided solar cell panel 140 can receive sunlight from the top surface solar cell 102 of the fourth double-sided solar cell panel 140 through the gap G of the third double-sided solar cell panel 130 So that the unit module of the fourth double-sided solar cell panel 140 is positioned directly below the gap G of the third double-sided solar cell panel 130. A net-like reflector 106 is attached to upper and lower surface layers of the third double-sided solar cell panel 130 and upper and lower surface layers of the fourth both-side solar cell panel 140.

FIG. 9 is a conceptual diagram for explaining various types of incident and reflected sunlight in the solar cell module of the multi-layer structure shown in FIG. The sunlight incident on the gap G of the second solar cell panel is received by the third solar cell panel and the sunlight incident on the gap G of the third solar cell panel is received by the fourth solar cell panel in the same manner as described above, It receives from the solar panel. In this process, sunlight that does not enter the solar cell through the net-shaped reflector 106 can be selectively retroreflected, thereby maximizing the solar light receiving efficiency.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It is to be understood that the invention is not limited thereto and that various changes and modifications may be made therein without departing from the scope of the invention.

100: solar cell module having a multi-layer structure 110: first double-sided solar cell panel
120: second double-sided solar cell panel 130: third double-sided solar cell panel
140: Fourth-sided solar cell panel 150: One-sided solar cell panel
160: vertical panel 101: upper surface layer
102: upper surface solar battery cell 103: separator plate
104: lower solar cell 105: lower surface layer
106: net type reflecting mirror 106a:
106b:

Claims (6)

A first double-sided solar cell panel including a plurality of unit modules including a top solar cell and a bottom solar cell disposed below the top solar cell;
A second double-sided solar cell including a plurality of unit modules disposed below the first double-sided solar cell panel and including a top solar cell and a bottom solar cell disposed below the top solar cell, panel; And
A single-sided solar cell panel disposed below the second double-sided solar cell panel and including a plurality of unit modules including a top-side solar cell;
/ RTI >
Wherein each of the first double-sided solar cell panel and the second double-sided solar cell panel includes a plurality of unit modules each of which is arranged continuously along a first direction on a plane, and which is adjacent in a second direction on a plane intersecting the first direction The unit module being spaced apart from a gap of a predetermined interval,
Wherein the second double-sided solar cell panel comprises a first double-sided solar cell panel, a second double-sided solar cell panel, and a second double-sided solar cell panel, Wherein the module is disposed such that a portion thereof is staggered with a unit module of the first double-sided solar cell panel directly below the gap of the first double-sided solar cell panel. The method according to claim 1,
The first double-sided solar cell panel and the second double-sided solar cell panel each have a surface layer formed above and below the upper surface solar cell and the upper surface solar cell, A surface layer is further formed on the substrate,
Wherein a net-like reflecting mirror is attached to the surface layer on the lower side of the first double-sided solar cell panel, the surface layer on the lower side of the first double-sided solar cell panel, the surface layer on the lower side of the first double- Power generation module. 3. The method of claim 2,
Wherein the net type reflector is composed of a reflecting portion for reflecting sunlight and at least one transmitting portion having a position corresponding to the upper or lower surface solar cell. The method of claim 3,
And a plurality of unit modules including a plurality of unit modules including a top solar cell and a bottom solar cell disposed on a lower side corresponding to the top solar cell, between the second double-sided solar cell panel and the single- Solar panel; And
A fourth double-sided solar cell including a plurality of unit modules disposed below the third double-sided solar cell panel and including a top solar cell and a bottom solar cell disposed below the top solar cell, Further comprising a panel,
The third and fourth double-sided solar cell panels are arranged such that the unit modules are successively arranged along a first direction on a plane, and are spaced apart from each other by a gap of a predetermined interval in a second direction on the plane, ,
Wherein the third double-sided solar cell panel comprises a third double-sided solar cell panel, a second double-sided solar cell panel, and a third double-sided solar cell panel, Wherein the module is disposed so as to be located right under the gap of the second double-sided solar cell panel,
Wherein the fourth double-sided solar cell panel is a unit of the fourth double-sided solar cell panel so that sunlight can be incident on the upper surface solar cell of the fourth double-sided solar cell panel through a gap of the third double- Wherein the module is disposed so as to be located directly below the gap of the third double-sided solar cell panel. 5. The method of claim 4,
Wherein the third and the second both-sided solar cell panels further include a surface layer disposed below the upper surface solar cell and below the lower surface solar cell,
Wherein a mesh type reflector is attached to upper and lower surface layers of the third double-sided solar cell panel, upper and lower surface layers of the third double-sided solar cell panel, and upper and lower surface layers of the fourth both-side solar cell panel. 6. The method according to any one of claims 1 to 5,
Wherein each of the double-sided solar panel and the single-sided solar panel is fixed in a state of being vertically spaced apart by a transparent vertical panel outside the rim.

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