KR102444713B1 - Hybrid solar cell module and light emitting device including same - Google Patents

Abstract

a plurality of organic solar cells spaced apart from each other on the same plane; and a plurality of inorganic solar cells disposed on the same plane as the organic solar cell and disposed between the organic solar cells. The hybrid solar cell module provided in one aspect of the present invention has the advantage of being able to operate even on a cloudy day and sufficiently securing flexibility while having excellent efficiency.

Description

Hybrid solar cell module and light emitting device including same

The present invention relates to a hybrid solar cell module and a light emitting device including the same.

Recently, as the reserves of traditional fossil fuels are decreasing and environmental pollution caused by fossil fuels has become serious, interest in the use of eco-friendly alternative energy is growing. In particular, solar cell modules using sunlight are spotlighted as the most promising alternative energy to replace traditional energy in the future through technology accumulated through long-term research.

The installed capacity of these solar cell modules has reached about 30 GW by 2010, and the solar market of 100 GW is expected to be formed in 2020. In addition, domestic demand is about 100 MW per year, and the production capacity is about 1 GW. Considering this long-term domestic and international situation, the solar power industry is expected to continue to grow in the future.

Power generation using solar energy includes solar power generation that converts solar light into electrical energy and uses solar power, and solar thermal device that collects solar energy with a heat collector and then uses it for heating or hot water.

Among them, solar power generation has advantages in that it does not require fuel costs and does not generate noise and pollution, unlike existing power generation facilities such as thermal power or nuclear power. In addition, solar power generation does not require a large-scale power generation facility, and since small-scale power generation is possible, there is an advantage that it can be installed and used for home use.

Therefore, it is not possible to achieve efficient use of solar energy only with such an independent and inefficient configuration, and a mechanism that can generate combined power must be developed.

For this reason, solar power generation is widely used in developed countries such as Germany, Japan, and the United States, and as the Act on Promotion of Use of Alternative Energy was recently revised and announced in Korea, specific implementation plans such as the construction of 10,000 solar power generation units are being realized.

Silicon solar cell development began in earnest in 1954 when Bell Labs in the US developed a solar cell with 45% efficiency. Since then, through continuous research, the highest efficiency of a silicon solar cell, 247%, was achieved in 1999. For practical commercialization, production cost and productivity as well as the efficiency of silicon solar cells become important issues, and the importance of amorphous thin film silicon solar cells with low material and process costs and the highest efficiency of about 10% is being emphasized.

In general, silicon solar cells are divided into substrate type and thin film type according to the type of material. The substrate-type silicon solar cell is further divided into a single-crystalline silicon solar cell and a polycrystalline silicon solar cell according to the material used as the light absorption layer. Thin-film silicon solar cells are also classified into amorphous silicon (a-Si:H) solar cells and micro-crystalline silicon (c-Si:H) solar cells depending on the material used as the light absorption layer. In order to obtain a crystalline silicon substrate, since a silicon wafer is used, the production cost is high and the productivity is low because complicated steps are required in the process. On the other hand, an amorphous silicon solar cell has a sufficient potential for commercialization because its material cost is low and it is suitable for a continuous mass production process.

The most basic structure of a silicon solar cell is in the form of a diode composed of a p-n junction, but in the case of an amorphous silicon thin film, the diffusion length of carriers is very low compared to that of a crystalline silicon substrate. The collection efficiency of electron-hole pairs is low. Therefore, the amorphous silicon solar cell is manufactured in a p-i-n structure in which an undoped intrinsic (i-type) amorphous silicon light absorption layer is inserted between the p-type amorphous silicon and n-type amorphous silicon layers. The structure of a typical amorphous silicon solar cell is shown in FIG. 1 . As can be seen from FIG. 1, an amorphous silicon solar cell is generally composed of a transparent electrode layer, a p-type amorphous silicon layer, an i-type amorphous silicon layer, an n-type amorphous silicon layer, and a metal electrode layer on a glass substrate.

On the other hand, the organic solar cell is a solar cell using an organic material as a light absorption layer, and the material cost is lower than that of an inorganic material such as silicon, and the production cost can be significantly lowered because the solar cell manufacturing process is very simple. An organic solar cell is characterized in that it is composed of organic materials having an electron donor characteristic and an electron acceptor characteristic. The principle of operation is that when light energy is incident on a photoactive layer made of an organic material, electrons are excited, and the excited electrons and the holes remaining at the excited sites are electrostatically weakly coupled to form exciton pairs. ) is created. In order for the exciton generated by sunlight to actually generate a photocurrent, the electron-hole pair must be dissociated to become each electron and hole, and at this time, the electron must flow to the anode and the hole to flow to the cathode. Recently, due to technological advances in solar cells made of polymers, energy conversion efficiency is improving. As an example of an organic solar cell, in the most used polymer system, a conjugated polymer such as poly(3-hexylthiophene, P3HT) and [6,6]-phenyl-C A mixed solution of _x -butyric acid methyl ester (PC _x BM) is used as the main material. An organic solar cell is generally composed of a transparent electrode layer, a hole transport layer, a light absorption layer, and a metal electrode layer on a glass substrate.

On the other hand, a tandem solar cell can be manufactured by stacking two or more types of single solar cells and electrically connecting them in series, which has a problem in that it is difficult to secure sufficient flexibility.

Republic of Korea Patent Publication No. 10-2012-0013731

An object of the present invention is to provide an organic-inorganic hybrid solar cell module with improved flexibility.

In order to achieve the above object, in one aspect of the present invention

a plurality of organic solar cells spaced apart from each other on the same plane; and

a plurality of inorganic solar cells disposed on the same plane as the organic solar cell and disposed between the organic solar cells;

There is provided a hybrid solar cell module comprising a.

In addition, in another aspect of the present invention

transparent insulating film;

a plurality of organic solar cells disposed on one surface of the transparent insulating film; and

a plurality of inorganic solar cells disposed on the other surface of the transparent insulating film;

There is provided a hybrid solar cell module comprising a.

In addition, in another aspect of the present invention

As a manufacturing method for manufacturing the hybrid solar cell module,

forming a plurality of spaced apart organic solar cells; and

forming an inorganic solar cell between the spaced apart organic solar cells;

There is provided a hybrid solar cell module manufacturing method comprising a.

In addition, in another aspect of the present invention

As a manufacturing method for manufacturing the hybrid solar cell module,

forming a plurality of organic solar cells on one surface of the transparent insulating film; and

forming a plurality of inorganic solar cells on the other surface of the transparent insulating film;

There is provided a hybrid solar cell module manufacturing method comprising a.

Furthermore, in another aspect of the present invention

the hybrid solar cell module; and

A light emitting device comprising a; a light emitting device disposed on the surface of the solar cell is provided.

The hybrid solar cell module provided in one aspect of the present invention has the advantage of being able to operate even on a cloudy day and sufficiently securing flexibility while having excellent efficiency.

1 shows a schematic diagram of a hybrid solar cell module according to an embodiment of the present invention,
2 is a plan view and a side view of a hybrid solar cell according to an embodiment of the present invention;
3 is a schematic diagram of a hybrid solar cell module according to another embodiment of the present invention,
4 is a plan view and a side view of a hybrid solar cell module according to another embodiment of the present invention,
5 is a schematic diagram showing a light emitting device according to an embodiment of the present invention,
6 shows a light emitting device in the form of a bracket according to an embodiment of the present invention,
7 shows a light emitting device in the form of a stitch belt according to an embodiment of the present invention,
8 is a photograph showing a state in which a light emitting device according to an embodiment of the present invention is actually used.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. In general, the nomenclature used herein is those well known and commonly used in the art.

In one aspect of the invention

a plurality of organic solar cells spaced apart from each other on the same plane; and

a plurality of inorganic solar cells disposed on the same plane as the organic solar cell and disposed between the organic solar cells;

There is provided a hybrid solar cell module comprising a.

Hereinafter, a hybrid solar cell module provided in one aspect of the present invention will be described in detail.

First, the hybrid solar cell module provided in one aspect of the present invention includes a plurality of organic solar cells.

The organic solar cell may be used without limitation as long as it is a conventionally used organic solar cell.

Preferably, the organic solar cell may be a non-transmissive solar cell.

In the hybrid solar cell module, an organic solar cell and an inorganic solar cell are disposed on the same plane. Transmittance and output are inversely proportional. In order to maximize the output, the organic solar cell is preferably a non-transmissive type.

The organic solar cells are spaced apart from each other on the same plane.

The width, the number of strips and the separation distance between the strips of the organic solar cell may be adjusted according to the product to be used.

Next, the hybrid solar cell module provided in one aspect of the present invention includes a plurality of inorganic solar cells.

The inorganic solar cell may be used without limitation as long as it is a conventionally used inorganic solar cell, for example, a silicon solar cell, a CIGS solar cell, a CdTe solar cell, a perovskite solar cell, a quantum dot solar cell, and a dye-sensitized solar cell. It may be a battery or the like.

Preferably, it may be a silicon solar cell or a CIGS solar cell that is easily manufactured and used in a strip shape.

The width, the number of strips, and the separation distance between the strips of the inorganic solar cell may be adjusted according to the product to be used.

That is, the hybrid solar cell module provided in one aspect of the present invention can control the output by easily adjusting the number of strips according to the desired application product, and a new inorganic solar cell is installed between each strip of the organic solar cell spaced apart. Since the output can be further adjusted by placing it, there is an advantage that the output can be freely adjusted within the same space.

Accordingly, it is possible to control required output and flexibility by actively adjusting the width, number of strips, and separation distance between strips of organic and inorganic solar cells according to the external application environment.

The organic and inorganic solar cells may be disposed in a shingled junction method.

Such a shingled junction arrangement is preferable in that space utilization can be maximized, and more specifically, in the case of such a shingled junction method, more cells can be placed in the same area, resulting in more power production. It is possible, and it is possible to solve problems such as output degradation due to bar shading and stress caused by ribbon soldering, which can connect cells without a busbar.

The shingled bonding method may be performed by directly bonding the solar cells using a conductive adhesive paste without using a conventional string or ribbon when connecting the solar cells. For example, it may be joined using a metal mesh and a conductive paste.

In the case of the conventional shingled bonding method, a conductive paste is applied between the two silicones when bonding from silicon to silicon, and in the final module, a string and a ribbon are used to form the + and - pole connection parts.

On the other hand, in an embodiment of the present invention, when connecting between two silicons and forming the final connection portion using a finely patterned metal mesh, it is used for silicon bonding through patterning on a single mesh plate and at the same time as the final electrode can be used as

Specifically, when bonding between solar cells, it is possible to use a method of attaching a metal mesh, not bonding using solder, to the upper or lower portion of the cell (electrode forming portion) and bonding through heat treatment such as hot press.

In this case, the final wiring process is not required, and the alignment problem at the time of silicon bonding can be easily solved.

The inorganic solar cell is disposed on the same plane as the organic solar cell, and is disposed between the organic solar cells. That is, the organic solar cell and the inorganic solar cell are cross-arranged.

In this way, when the organic solar cell and the inorganic solar cell are cross-arranged on the same plane, sufficient flexibility can be secured as described above, the efficiency of the cell is increased by using the inorganic solar cell, and the organic solar cell is blurred by using the organic solar cell. Since it can be operated even during the day, the number of days of assistance can be significantly reduced, so that the battery can be continuously operated and the stability of the battery can be guaranteed.

In addition, since the output can be adjusted by controlling only the structure within a limited area, there is also an advantage of being economical compared to the conventional solar cell module.

In another aspect of the invention

transparent insulating film;

a plurality of organic solar cells disposed on one surface of the transparent insulating film; and

a plurality of inorganic solar cells disposed on the other surface of the transparent insulating film;

There is provided a hybrid solar cell module comprising a.

Hereinafter, a hybrid solar cell module provided in one aspect of the present invention will be described in detail.

First, the hybrid solar cell module provided in another aspect of the present invention includes a transparent insulating film.

The transparent insulating film has the same performance as the polymer film, such as, for example, polyethylene terephthalate (PET), polydimethylsiloxane (PDMS), silicone, polyurethane, or very high bond (VHB), and uses a thin polymer film or polymer coating method. It may be a polymer layer such as polymethylmethacrylate (PMMA), cellulose, boron nitride, or the like, but is not limited thereto.

The transparent insulating film functions to prevent a short circuit by insulating the + and - poles from each other.

Next, the hybrid solar cell module provided in another aspect of the present invention includes a plurality of organic solar cells.

The organic solar cell may be used without limitation as long as it is a conventionally used organic solar cell.

Preferably, the organic solar cell may be a light-transmitting solar cell. When the organic solar cell is a light-transmitting type, it is preferable in that light can pass through and the light can reach the inorganic solar cell lower than the organic solar cell.

The organic solar cell is disposed on one surface of the transparent insulating film.

The width, the number of strips and the separation distance between the strips of the organic solar cell may be adjusted according to the product to be used.

Next, the hybrid solar cell module provided in another aspect of the present invention includes a plurality of inorganic solar cells.

The inorganic solar cell may be used without limitation as long as it is a conventionally used inorganic solar cell, for example, a silicon solar cell, a CIGS solar cell, a CdTe solar cell, a perovskite solar cell, a quantum dot solar cell, and a dye-sensitized solar cell. It may be a battery or the like.

Preferably, it may be a silicon solar cell or a CIGS solar cell that is easily manufactured and used in a strip shape.

The inorganic solar cell is disposed on one surface of the transparent insulating film different from the surface on which the organic solar cell is disposed.

The width, the number of strips, and the separation distance between the strips of the inorganic solar cell may be adjusted according to the product to be used.

The organic and inorganic solar cells may be disposed in a shingled junction method.

When arranged in this shingled junction method, it is preferable in that space utilization can be maximized. More specifically, in the case of this shingled junction method, more cells can be put in the same area, resulting in more power production. It is possible, and it is possible to solve problems such as output degradation due to bar shadows and stress caused by ribbon soldering, which can bond cells without a busbar.

The shingled bonding method may be performed by directly bonding the solar cells using a conductive adhesive paste without using a conventional string or ribbon when connecting the solar cells. For example, it may be joined using a metal mesh and a conductive paste.

In the case of the conventional shingled bonding method, a conductive paste is applied between the two silicones when bonding from silicon to silicon, and in the final module, a string and a ribbon are used to form the + and - pole connection parts.

On the other hand, in an embodiment of the present invention, when connecting between two silicons and forming the final connection portion using a finely patterned metal mesh, it is used for silicon bonding through patterning on a single mesh plate and at the same time as the final electrode can be used as

Specifically, when bonding between solar cells, it is possible to use a method of attaching a metal mesh, not bonding using solder, to the upper or lower portion of the cell (electrode forming portion) and bonding through heat treatment such as hot press.

In this case, the final wiring process is not required, and the alignment problem at the time of silicon bonding can be easily solved.

In this way, when the organic solar cell and the inorganic solar cell are vertically arranged around the transparent insulating film, sufficient flexibility can be secured. Since the operation is possible, the number of days of assistance can be significantly reduced.

More specifically, the advantage of an organic solar cell that relatively high output can be obtained in a low-illuminance environment such as a cloudy day or sunrise/sunset, and an inorganic solar cell that can obtain a higher output compared to an organic solar cell when there is a lot of sunlight It has the advantage of being able to have both advantages at the same time.

Next, in another aspect of the present invention, as a manufacturing method for manufacturing the hybrid solar cell module,

forming a plurality of spaced apart organic solar cells; and

forming an inorganic solar cell between the spaced apart organic solar cells;

There is provided a hybrid solar cell module manufacturing method comprising a.

The hybrid module manufacturing method provided in another aspect of the present invention includes a plurality of organic solar cells spaced apart on the same plane; and a plurality of inorganic solar cells disposed on the same plane as the organic solar cell and disposed between the organic solar cells.

First, the hybrid solar cell module manufacturing method provided in another aspect of the present invention includes forming a plurality of spaced apart organic solar cells.

The organic solar cell may be used without limitation as long as it is a conventionally used organic solar cell.

Preferably, the organic solar cell may be a non-transmissive solar cell.

In the hybrid solar cell module, an organic solar cell and an inorganic solar cell are disposed on the same plane. Transmittance and output are inversely proportional. In order to maximize the output, the organic solar cell is preferably a non-transmissive type.

The organic solar cells are spaced apart from each other on the same plane.

The width, the number of strips and the separation distance between the strips of the organic solar cell may be adjusted according to the product to be used.

The organic solar cell may be manufactured by patterning after coating with an organic material in order to control the number of strips in a desired shape.

The patterning may be performed by laser patterning or mechanical scribing.

Next, the hybrid solar cell module manufacturing method provided in another aspect of the present invention includes forming an inorganic solar cell between the spaced apart organic solar cells.

The inorganic solar cell may be used without limitation as long as it is a conventionally used inorganic solar cell, for example, a silicon solar cell, a CIGS solar cell, a CdTe solar cell, a perovskite solar cell, a quantum dot solar cell, and a dye-sensitized solar cell. It may be a battery or the like.

Preferably, it may be a silicon solar cell or a CIGS solar cell that is easily manufactured and used in a strip shape.

The width, the number of strips, and the separation distance between the strips of the inorganic solar cell may be adjusted according to the product to be used.

That is, the hybrid solar cell module provided in one aspect of the present invention can control the output by easily adjusting the number of strips according to the desired application product, and a new inorganic solar cell is installed between each strip of the organic solar cell spaced apart. Since the output can be further adjusted by placing it, there is an advantage that the output can be freely adjusted within the same space.

Accordingly, it is possible to control required output and flexibility by actively adjusting the width, number of strips, and separation distance between strips of organic and inorganic solar cells according to the external application environment.

The inorganic solar cell may be formed between spaced apart organic solar cells through a general inorganic solar cell manufacturing process.

The organic and inorganic solar cells may be disposed in a shingled junction method.

Such a shingled junction arrangement is preferable in that space utilization can be maximized, and more specifically, in the case of such a shingled junction method, more cells can be placed in the same area, resulting in more power production. It is possible, and it is possible to solve problems such as output degradation due to bar shading and stress caused by ribbon soldering, which can connect cells without a busbar.

The shingled bonding method may be performed by directly bonding the solar cells using a conductive adhesive paste without using a conventional string or ribbon when connecting the solar cells. For example, it may be joined using a metal mesh and a conductive paste.

In the case of the conventional shingled bonding method, a conductive paste is applied between the two silicones when bonding from silicon to silicon, and in the final module, a string and a ribbon are used to form the + and - pole connection parts.

On the other hand, in an embodiment of the present invention, when connecting between two silicons and forming the final connection portion using a finely patterned metal mesh, a single mesh plate is patterned to be used for silicon bonding and at the same time, the final electrode can be used as

Specifically, when bonding between solar cells, it is possible to use a method of attaching a metal mesh, not bonding using solder, to the upper or lower portion of the cell (electrode forming portion) and bonding through heat treatment such as hot press.

In this case, the final wiring process is not required, and the alignment problem at the time of silicon bonding can be easily solved.

The inorganic solar cell is disposed on the same plane as the organic solar cell, and is disposed between the organic solar cells. That is, the organic solar cell and the inorganic solar cell are cross-arranged.

In this way, when the organic solar cell and the inorganic solar cell are cross-arranged on the same plane, sufficient flexibility can be secured as described above, the efficiency of the cell is increased by using the inorganic solar cell, and the organic solar cell is blurred by using the organic solar cell. Since it can be operated even during the day, the number of days of assistance can be significantly reduced, so that the battery can be continuously operated and the stability of the battery can be guaranteed.

In addition, since the output can be adjusted by controlling only the structure within a limited area, there is also an advantage of being economical compared to the conventional solar cell module.

In another aspect of the present invention,

As a manufacturing method for manufacturing the hybrid solar cell module,

forming a plurality of organic solar cells on one surface of the transparent insulating film; and

forming a plurality of inorganic solar cells on the other surface of the transparent insulating film;

There is provided a hybrid solar cell module manufacturing method comprising a.

The hybrid module manufacturing method provided in another aspect of the present invention includes a transparent insulating film; a plurality of organic solar cells disposed on one surface of the transparent insulating film; and a plurality of inorganic solar cells disposed on the other surface of the transparent insulating film.

First, the method for manufacturing a hybrid solar cell module provided in another aspect of the present invention includes forming a plurality of organic solar cells on one surface of a transparent insulating film.

The transparent insulating film has the same performance as the polymer film, such as, for example, polyethylene terephthalate (PET), polydimethylsiloxane (PDMS), silicone, polyurethane, or very high bond (VHB), and uses a thin polymer film or polymer coating method. It may be a polymer layer such as polymethylmethacrylate (PMMA), cellulose, boron nitride, or the like, but is not limited thereto.

The transparent insulating film functions to prevent a short circuit by insulating the + and - poles from each other.

The organic solar cell may be used without limitation as long as it is a conventionally used organic solar cell.

Preferably, the organic solar cell may be a light-transmitting solar cell. When the organic solar cell is a light-transmitting type, it is preferable in that light can pass through and the light can reach the inorganic solar cell lower than the organic solar cell.

The above step may be performed by manufacturing a plurality of organic solar cells on one surface of the transparent insulating film, or may be performed by forming a transparent insulating film on a plurality of organic solar cells already manufactured.

For example, a plurality of already manufactured organic solar cells may be bonded through a transparent insulating film. In general, when manufacturing a solar cell module, a transparent insulating protective film is covered after manufacturing each solar cell. In the case of the solar cell module manufacturing method provided in another aspect of the present invention, this insulating film is a protective layer and two In order to act as a bonding agent that connects devices, a material having bonding properties may be used.

The width, the number of strips and the separation distance between the strips of the organic solar cell may be adjusted according to the product to be used.

Next, the method for manufacturing a hybrid solar cell module provided in another aspect of the present invention includes forming a plurality of inorganic solar cells on the other surface of the transparent insulating film.

The inorganic solar cell may be used without limitation as long as it is a conventionally used inorganic solar cell, for example, a silicon solar cell, a CIGS solar cell, a CdTe solar cell, a perovskite solar cell, a quantum dot solar cell, and a dye-sensitized solar cell. It may be a battery or the like.

Preferably, it may be a silicon solar cell or a CIGS solar cell that is easily manufactured and used in a strip shape.

The inorganic solar cell is disposed on one surface of the transparent insulating film different from the surface on which the organic solar cell is disposed.

The width, the number of strips, and the separation distance between the strips of the inorganic solar cell may be adjusted according to the product to be used.

The organic and inorganic solar cells may be disposed in a shingled junction method.

Such a shingled junction arrangement is preferable in that space utilization can be maximized, and more specifically, in the case of such a shingled junction method, more cells can be placed in the same area, resulting in more power production. It is possible, and it is possible to solve problems such as output degradation due to bar shading and stress caused by ribbon soldering, which can connect cells without a busbar.

The shingled bonding method may be performed by directly bonding the inorganic solar cells using a conductive adhesive paste without using a conventional string or ribbon when connecting the solar cells. For example, it may be joined using a metal mesh and a conductive paste.

In the case of the conventional shingled bonding method, a conductive paste is applied between the two silicones when bonding from silicon to silicon, and in the final module, a string and a ribbon are used to form the + and - pole connection parts.

On the other hand, in an embodiment of the present invention, when connecting between two silicons and forming the final connection portion using a finely patterned metal mesh, it is used for silicon bonding through patterning on a single mesh plate and at the same time as the final electrode can be used as

Specifically, when bonding between solar cells, it is possible to use a method of attaching a metal mesh, not bonding using solder, to the upper or lower portion of the cell (electrode forming portion) and bonding through heat treatment such as hot press.

In this case, the final wiring process is not required, and the alignment problem at the time of silicon bonding can be easily solved.

In this way, when the organic solar cell and the inorganic solar cell are vertically arranged around the transparent insulating film, sufficient flexibility can be secured. Since the operation is possible, the number of days of assistance can be significantly reduced.

More specifically, the advantage of an organic solar cell that relatively high output can be obtained in a low-illuminance environment such as a cloudy day or sunrise/sunset, and an inorganic solar cell that can obtain a higher output compared to an organic solar cell when there is a lot of sunlight It has the advantage of being able to have both advantages at the same time.

In another aspect of the invention

the hybrid solar cell module; and

A light emitting device comprising a; a light emitting device disposed on the surface of the solar cell module is provided.

The hybrid solar cell module may be any type of solar cell described above.

The light emitting device may be used without limitation as long as it is a commonly used light emitting device, and may be, for example, LED or OLED.

The light emitting device may emit point light or surface light emission.

A plurality of organic solar cells disposed spaced apart on the same plane provided in one aspect of the present invention; and a plurality of inorganic solar cells disposed on the same plane as the organic solar cell and disposed between the organic solar cells; A light emitting device may be disposed on an edge portion of the , and an inorganic solar cell or a surface light emitting device may be alternately disposed between organic solar cells in order to manufacture a surface light emitting device.

Transparent insulating film provided in another aspect of the present invention; a plurality of organic solar cells disposed on one surface of the transparent insulating film; and a plurality of inorganic solar cells disposed on the other side of the transparent insulating film. In addition, the light emitting device may be disposed between the strips of the organic solar cell in order to manufacture a light emitting device of surface light emission.

The light emitting device may be driven using power generated by the solar cell.

The light emitting device may be in the form of a bracket or a stitch belt. This type of light emitting device can maximize the flexible characteristics of the solar cell.

The light emitting device may be used by being attached to road safety products. For example, it can be used for electric poles, light beams, construction site information boards, and the like. When the light emitting device is in the form of a bracket or a stitch belt as described above, it is more easily attached to the cylindrical structure.

Hereinafter, the present invention will be described in more detail through examples. The scope of the present invention is not limited to specific embodiments, and should be construed by the appended claims. In addition, those skilled in the art should understand that many modifications and variations are possible without departing from the scope of the present invention.

<Example 1> Organic-inorganic hybrid solar cell modules cross-arranged on the same plane

In a general organic solar cell manufacturing method, an insulating layer was applied to the entire surface after the non-transmissive organic solar cell was manufactured. Thereafter, the sliced silicon solar cell was placed between the strips of the organic solar cell, and a silicon module was formed through a process of connecting silicon and silicon using a metal mesh.

<Example 2> Organic-inorganic hybrid solar cell module arranged vertically around a transparent insulating film

As a general method for manufacturing an organic solar cell, an insulating layer was applied after a light-transmitting organic solar cell was manufactured. Thereafter, a shingled junctioned silicon solar cell was disposed on the other side of the insulating layer on which the organic solar cell was not disposed, and the shingled junctioned silicon solar cell was provided with an electrode made of a metal mesh.

It was prepared in the same manner as in Example 1, but since a light-transmitting organic solar cell was used, the organic solar cell was disposed on the front surface, not between the strips, when the silicon solar cell was disposed.

<Example 3> Light emitting device including organic-inorganic hybrid solar cell modules cross-arranged on the same plane

With respect to the solar cell module of Example 1, a light emitting element was disposed at an edge portion of the entire device in order to manufacture a light emitting device of point light emission.

In addition, in order to manufacture a light emitting device of surface light emission, an inorganic solar cell or a surface light emitting device may be alternately disposed between organic solar cells.

<Embodiment 4> Light-emitting device including organic-inorganic hybrid solar cell modules arranged vertically around a transparent insulating film

With respect to the solar cell module of Example 2, a light emitting element may be disposed on the entire surface of an organic solar cell strip in order to manufacture a light emitting device of point light emission, and between the strips of an organic solar cell in order to manufacture a light emitting device of surface light emission. A light emitting device may be disposed.

10 organic solar cells
20 inorganic solar cells
30 Transparent Insulation Film
40 light emitting element
100 hybrid solar cells
1000 light emitting device

Claims (11)

a plurality of organic solar cells spaced apart from each other on the same plane;
a plurality of inorganic solar cells disposed on the same plane as the organic solar cells and spaced apart between the organic solar cells; and
a metal mesh electrically connecting a plurality of inorganic solar cells;
A flexible hybrid solar cell module comprising a.
According to claim 1,
The organic solar cell is a flexible hybrid solar cell module, characterized in that the non-transmissive solar cell.
transparent insulating film;
a plurality of organic solar cells spaced apart from one surface of the transparent insulating film;
a plurality of inorganic solar cells spaced apart from the other surface of the transparent insulating film; and
a metal mesh electrically connecting a plurality of inorganic solar cells;
A flexible hybrid solar cell module comprising a.
4. The method of claim 3,
The inorganic solar cell is a flexible hybrid solar cell module, characterized in that it is arranged in a shingled array method.
4. The method of claim 3,
The organic solar cell is a flexible hybrid solar cell module, characterized in that it is a light-transmitting solar cell.
A manufacturing method for manufacturing the flexible hybrid solar cell module of claim 1,
forming a plurality of spaced apart organic solar cells;
forming inorganic solar cells to be spaced apart between the spaced organic solar cells; and
electrically connecting the plurality of inorganic solar cells with a metal mesh;
A method for manufacturing a flexible hybrid solar cell module comprising a.
A manufacturing method for manufacturing the flexible hybrid solar cell module of claim 3,
forming a plurality of organic solar cells to be spaced apart from each other on one surface of the transparent insulating film;
forming a plurality of inorganic solar cells to be spaced apart from each other on the other surface of the transparent insulating film; and
electrically connecting the plurality of inorganic solar cells with a metal mesh;
A method for manufacturing a flexible hybrid solar cell module comprising a.
The flexible hybrid solar cell module of claim 1; and
A light emitting device comprising a; a light emitting device disposed on the surface of the solar cell module.
9. The method of claim 8,
The light emitting device is a light emitting device, characterized in that the form of a bracket or a stitch belt.
The flexible hybrid solar cell module of claim 3; and
A light emitting device comprising a; a light emitting device disposed on the surface of the solar cell module.
11. The method of claim 10,
The light emitting device is a light emitting device, characterized in that the form of a bracket or a stitch belt.

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