KR100858475B1 - Solar cell modules having designed cover sheets in dual glass plates - Google Patents

Abstract

A solar cell module having a designed cover sheet between dual glass plates is provided to improve an exterior thereof by preventing direct exposure of a solar cell and an interconnected ribbon through glass substrates. A solar cell module includes a plurality of solar cells(10) for converting solar energy to electrical energy, a plurality of interconnected ribbons(40) for connecting electrically the solar cells with each other, front and rear glass substrates, and an EVA film arranged between the front and rear glass substrates. The EVA film is composed of a first EVA film, a second EVA film, and a third EVA film. The solar cell is arranged between the first and second EVA films. A designed cover sheet(50) is arranged between the second and third EVA films which are arranged in a backside of the solar cells.

Description

Solar Cell Modules Having Designed Cover Sheets in Dual Glass Plates

The present invention relates to a solar cell module for producing electric power using solar energy, and more particularly, attaching a packaging sheet such as a photograph, a picture, a lettered sheet, a hologram sheet, etc. on the back of the solar cell, and a solar cell The present invention relates to a solar cell module having a package designed between double laminated glass that improves the appearance exposed to the rear side by attaching a tape to both sides of a ribbon forming an electrical connection between cells.

In general, a solar cell module is a device that produces solar energy by using a plurality of solar cells.

The solar cell module for BIPV (Building Intergrated Photovoltaics System) developed as an integrated building is manufactured by laminating with EVA film on the front and back of the solar cell between low iron tempered glass.

As shown in FIG. 1, the conventional solar cell module 100 arranges a plurality of solar cells 110 made of a single crystal or polycrystal between the tempered glass substrates 120a and 120b, and an EVA film. It is produced by attaching these using 130.

The conventional solar cell module 100 manufactured as described above usually has a blue or black color as shown in FIG. 2A, and a gray color as shown in FIG. 2B).

In addition, such a conventional solar cell module 100 screen printing two electrode wires having a width of 3-5mm with silver paste Ag to form electrode wires 132b on the rear surface of the solar cell 110. It is dried in a roll conveyor equipped with an IR lamp. The color of the electrode line 132b dried as described above is close to light gray.

Such solar cells 110 are made by depositing an N layer on a P-type wafer or depositing a P layer on an N-type wafer. When the P-type is used, the back surface of each solar cell 110 has a positive (+) and the front has a negative polarity (−). When the solar cell module 100 is made using the solar cells 110 as described above, the respective solar cells 110 are connected in series and in parallel.

In this case, an interconnect ribbon 140 is used to connect the solar cells 110, and the material of the interconnect ribbon 140 is typically Sn + Pb + Ag, Sn + Ag, Sn + Ag +. It is made of Cu, and the negative paste (-) polarity silver paste electrode line 132a having a width of 1-3mm formed on the front of the solar cell 110 when connected in series has a width of 3-5mm formed on the back of the other solar cell. The silver paste electrode line 132b of the positive polarity is connected through the connecting ribbon 140.

As such, the width of the connecting ribbon 140 connecting the solar cells 110 is 1.5 to 3 mm and a thickness of 0.01 to 0.2 mm. The connection method is composed of an indirect connection method using an IR lamp, a halogen lamp, hot air, and a direct connection method using a soldering iron.

Meanwhile, the EVA film 130 positioned between the glass substrates 120a and 120b of the solar cell module 100 starts to melt at a temperature of 80 ° C., becomes clear and transparent at a temperature of about 150 ° C., and the solar cell 110. The glass substrates are bonded to each other, and the moisture and air are prevented from penetrating toward the solar cell 110 so that the silver electrode wires 132a and 132b of the solar cell 110 and the ribbon 140 are separated. Prevent corrosion and short circuits.

When the EVA film 130 is laminated by a laminator (not shown), it melts between the double laminated glass substrates 120a and 120b of the solar cell module 100 to make it look clear and transparent, wherein the solar cell ( Except for 110 and the connecting ribbon 140, the remaining portions are transparent.

The conventional BIPV solar cell module 100 is manufactured using a single crystal or a polycrystalline solar cell 110, according to the manufacturing form of the solar cell 110, the double glass substrates 120a and 120b of the building. It is placed in between to be seen inside and outside the building.

As described above, the solar cell module 100 mounted on the building has a color in the process of depositing an electrode and an anti-reflection film by PECVD and APCVD (not shown), which are vacuum equipment, by screen printing. Normally, the front side may have a blue or black color, but the back side (BSF: Back-Surface Field) of the solar cell module 100 is deposited by vacuum equipment (not shown) with aluminum (Al) to form an electrode. This makes the color grey.

In addition, the conventional solar cell module 100 as described above connects several to several tens of solar cells 110 inside the glass substrates 120a and 120b with a connection ribbon 140, and the connection ribbon ( 140, they do not maintain a straight line constantly, it is bent and swollen. When the solar cell module 100 is laminated and completed in this state, the shape of the connecting ribbon 140 connecting the solar cells 110 in the glass substrates 120a and 120b is generally curved and not uniform.

In addition, in the conventional solar cell module 100, the color of the connecting ribbon 140 floats silver, and when manufacturing the solar cell module 100 for BIPV, the connecting ribbon 140 is the front, the back of the color as it is silver. Exposed.

Therefore, in the conventional solar cell module 100, since the rear and the color of the connecting ribbon 140 floats gray and silver, when manufacturing the double junction solar cell module 100, the front of the solar cell module 100 Since the silver of the connecting ribbon 140 is exposed to the outside through the front glass substrates 120a and 120b, the gray and silver colors of the rear side are intact, and the connecting ribbon 140 lines are bent and serpentine. When the solar cell module 100 is attached as a substitute for the glass, it does not look good.

The present invention is to solve the conventional problems as described above, the object of which is exposed to the outside by improving the appearance of the solar cell mounted on the interior of the glass substrate and the interconnecting ribbon (Interconnector Ribbon) connecting these solar cells. The present invention provides a solar cell module having a package designed between double laminated glass with a beautiful appearance.

In order to achieve the above object, the present invention, a plurality of solar cells for converting solar energy into electrical energy; A plurality of connection ribbons electrically connecting the solar cells; A front and rear glass substrate that confines the solar cell and a plurality of connecting ribbons therebetween; And an EVA film disposed between the front and rear surface glass substrates to bond the solar cell and the plurality of connection ribbons during lamination.
The EVA film is composed of a first EVA film, a second EVA film, a third EVA film, the solar cell is disposed between the first EVA film and the second EVA film, the rear side of the solar cell It provides a solar cell module having a package designed between the double laminated glass, characterized in that the package design is disposed between the second EVA film and the third EVA film is disposed.

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The present invention is also preferably designed between the double laminated glass, characterized in that the package is a color insulating tape attached to both sides of the connecting ribbon, and has a color matching the color of the front glass substrate. It provides a solar cell module having a package.

In another aspect, the present invention provides a solar cell module having a package designed between the double laminated glass, characterized in that the tape has a color of blue or black, and has a width larger than the width of the connecting ribbon. do.

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In another aspect, the present invention preferably is a solar cell having a package designed between the double laminated glass, characterized in that the sheet is made of any one of a photograph, a picture, a sheet with a letter, a hologram sheet or a reflective sheet of the mirror effect. Provide a module.

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According to the solar cell module having a package designed between the double laminated glass according to the present invention attached to the back of the solar cell mounted on the inside of the glass substrate, the sheet-shaped package is attached to the connecting ribbon connecting the solar cells (Interconnector Ribbon) attaches the package in the form of color tape on both sides, which can block the direct external exposure of the solar cell and the connecting ribbon through the glass substrate, improving the appearance of the solar cell module and improving the aesthetics. It is possible to obtain an improvement effect.

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

Solar cell module (1) having a package designed between the double laminated glass according to the present invention is to produce power using solar energy as a stand (not shown) attached to various buildings or structures in the city alone It is used as an upright using the back.

For example, it can be attached to a glass window of a building to produce electricity using solar energy while acting as an existing glass window, or stand alone at a bus stop or on a road to connect power to a separate existing power line. It can be used to produce and output various road information to the outside.

The solar cell module 1 having a package designed between double laminated glass according to the present invention has a plurality of solar cell 10 for converting solar energy into electrical energy, as shown in FIGS. 3 and 4. Include them.

The solar cells 10 have a structure made of single crystal or polycrystal, and have a plurality of connection ribbons 40 electrically connecting these solar cells 10.

The connecting ribbon 40 is made of conventional Sn + Pb + Ag, Sn + Ag, Sn + Ag + Cu, and connects adjacent solar cells 10 in series or in parallel.

And the present invention has a package 50 is attached to the front and rear outer surface of the connecting ribbon 40, the package 50 is made of colored tape. The package 50 is an insulating tape and has a color that matches the color of the front glass substrate 20a. The tape is insulated, colored, and treated by attaching to both sides of the connecting ribbon 40 as shown in FIG. 3.

At this time, the tape (Art Work Tape) has a width (W) wider than the width (w) of the connecting ribbon 40, it is used on both sides. That is, if the width w of the connecting ribbon 40 is 1.8 mm, the tape of the package 50 uses 2 mm. The color of the tape is used to match the surrounding environment of the solar cell module 1, or to match the color of the glass substrates 20a and 20b described later.

For example, the package 50 may be a tape having a blue or black color, and the front and rear surfaces of the solar cell module 1 may be attached with the same black or blue tape, or may be attached in different colors.

In addition, the present invention includes a front and rear glass substrate 20b in which the solar cell 10, the plurality of connection ribbons 40, and the package 50 are narrowly embedded therebetween. The glass substrates 20a and 20b are made of tempered glass, and the solar cell 10, the plurality of connecting ribbons 40, and the package 50 are positioned between the front and rear glass substrates 20b. And bonded to each other via conventional EVA films 30a, 30b, 30c.

As shown in Figure 4a), b), the solar cell module 1 according to the present invention having such a structure is attached to the front of the connecting ribbon 40 with a colored tape of the package 50 and Therefore, the connection ribbons are seen from the outside in a uniform and straight black band shape than the solar cell module 1 in which the conventional silver connection ribbon 40 is exposed as it is, and accordingly, The front and rear aesthetics can be beautifully designed.

Therefore, since the solar cell module 1 of the present invention attaches to both sides of the connecting ribbon 40 by using the tape-shaped package 50, the bending and the bending of the connecting ribbon 40 are constantly and beautifully corrected. The rear of the solar cell module (1) seen inside the building can be more beautifully decorated.

And the present invention is made of a packaging sheet that the package 50 is attached to the same size on the back of the solar cell 10, respectively. The package 50 formed of the sheet is made of any one of a photograph, a picture, a sheet on which letters are written, a hologram sheet, or a reflective sheet having a mirror surface effect, and each of the solar cells using the EVA film 30c ( 10) attached to the structure.

That is, according to the present invention, a sheet-shaped package 50 is attached to the back of each solar cell 10 in the solar cell module 1, and each package 50 is a photograph, a picture. It is composed of one or a combination of written sheets, holographic sheets, and reflective sheets for mirror effect.

The solar cell module 1 having a package designed between the double laminated glass according to the present invention may be used as a substitute for the existing glass window outside the building by putting the solar cell module 1 in an aluminum window to attach to the building. In this case, the front of the solar cell module (1) visible outside the building should be in the direction of the sun to generate electricity by sunlight, but the rear of the solar cell module (1) is in the direction of the interior of the building inside the building To the office or room. Usually, people in the building can not see the front of the solar cell module (1) and can only see the back of the solar cell module (1).

In such a case, the solar cell module 1 according to the present invention is attached to the sheet-shaped package 50 of another design in the same size as the size of the solar cell 10 on the back of the solar cell 10 solar cell When the module (1) is used instead of the building glass window, it makes the solar cell module (1) more beautiful to look inside.

In this case, the rear surface of the conventional solar cell module 1 is mostly gray, which is aesthetically very monotonous. However, before the solar cell module 1 of the present invention laminates the solar cells 10 on the glass substrates 20a and 20b with the EVA films 30a and 30b, there is a picture and letters on the back of the solar cell 10. The package 50, such as a sheet covered with a sheet, a hologram sheet, and a reflecting sheet having an effect such as a mirror surface, is disposed, and laminated on the glass substrates 20a and 20b with an EVA film 30c.

5 shows a cross-sectional structure of a solar cell module 1 having a package designed between such double laminated glass according to the present invention. As shown in FIG. 5, the present invention performs lamination by arranging one EVA film 30c and a plurality of packaging sheets on the back of the plurality of solar cells 10.

In this case, the EVA film 30c attaches the respective sheet-shaped packages 50 to the surface of each solar cell 10 while being heated. In this way, the solar cell 10 and the package 50 are disposed between the front glass substrate 20a and the rear glass substrate 20b of the solar cell module 1, and another EVA film ( Laminate bonding using 30a, 30b).

FIG. 6A shows a sheet-shaped package 50 having a partially different design attached to a rear surface of each solar cell 10 to process the solar cell module 1, and FIG. 6B shows each solar cell 10. ) Shows the rear appearance when all of the back of the) is attached to the package 50 of the hologram sheet.

In this case, when the present invention is treated with a package 50 such as a picture, a photo, a hologram sheet, etc., compared to the conventional solar cell module 1, the rear surface of the solar cell module 1 is designed to be more beautiful and beautifully manufactured. You can do it.

As described above, the solar cell module 1 of the present invention has a solar cell 10 mounted inside the glass substrates 20a and 20b and an interconnector ribbon 40 connecting the solar cell 10 to each other. By improving the appearance of the beautifully exposed to the outside can be improved.

And the manufacturing method of the solar cell module (1) having a package designed between the double laminated glass according to the present invention is as follows.

First, a step of preparing a plurality of solar cells 10 for converting solar energy into electrical energy is made. Next, the solar cell 10 is connected to the plurality of connection ribbons 40. Such steps may be accomplished through conventional processes.

In the present invention, the step of attaching the package 50 to the solar cell 10 or the connecting ribbon 40 is made. Attaching the package 50 may attach a colored insulating tape on both sides of the connecting ribbon 40, in which case the tape has a color that matches the color of the front glass substrate. . For example, the tape may have a blue or black color. In addition, the tape-shaped package 50 has a width greater than that of the connecting ribbon 40 and is attached to the connecting ribbon 40 so that the connecting ribbon 40 is completely packaged so as not to be exposed to the outside.

In addition, the step of attaching the package 50 may be attached to the sheet of the same size on the back of the solar cell 10, in this case the package 50 is attached by the EVA film (30c) Done. In this case, the sheet-shaped package 50 is made of any one of a photograph, a picture, a sheet covered with letters, a hologram sheet, or a reflective sheet of mirror effect, and as shown in cross section in FIG. 5, one EVA A plurality of sheets may be attached to the solar cell 10 using the film 30c. In this case, the effect of easily attaching the plurality of sheet-shaped packages 50 to the plurality of solar cells 10 is obtained.

After attaching the package 50 as described above, the solar cell 10, the plurality of connecting ribbons 40, and the package 50 are placed between the glass substrates 20a and 20b. Attaching and embedding are made using (30a, 30b, 30c).

In this case, the EVA films 30a, 30b, and 30c positioned between the glass substrates 20a and 20b are heated and melted in a clear and transparent manner so that the solar cell 10, the plurality of connecting ribbons 40, and the package body are melted. 50 are bonded to each other between the glass substrates 20a and 20b, and effectively prevent the penetration of moisture and air from the outside to the solar cell 10 side.

As described above, the solar cell module 1 having the package designed between the double laminated glass fabricated by the present invention includes the rear surfaces of the solar cells 10 mounted inside the glass substrates 20a and 20b, and these. Since the appearance of the interconnector ribbon 40 interconnecting the solar cells 10 is beautifully improved, the appearance exposed to the outside through the glass substrates 20a and 20b may be beautifully improved.

Although the present invention has been described in detail with reference to the accompanying drawings, the present invention is not limited to such a specific structure. Those skilled in the art will be able to variously modify or change the embodiments of the present invention without departing from the spirit and scope of the present invention as set forth in the claims below. Nevertheless, it will be apparent that all such modifications or design modifications to such simple embodiments will clearly fall within the scope of the present invention.

1 is an exploded view showing in cross section a solar cell module according to the prior art;

2 is a view showing a solar cell module according to the prior art,

a) is a front view; b) is a rear view;

3 is an exploded perspective view illustrating a structure in which tape-shaped packages are attached to front and rear surfaces of a connecting ribbon according to the present invention;

4 is a view showing a state in which the tape-shaped package is attached to the front and rear both sides of the connecting ribbon according to the present invention,

a) is a front view; b) is a rear view;

5 is an exploded view showing the solar cell module according to the present invention in a cross section; And

6 is a view showing a solar cell module is a sheet-shaped package attached to the back of the solar cell according to the present invention,

a) is a front view, b) is a rear view.

<Description of Symbols for Major Parts of Drawings>

1 .... solar cell module of the invention 10 ..... solar cell

20a, 20b .... Glass Substrate 30a, 30b, 30c ..... EVA Film

40 ..... Connecting Ribbon 50 .... Package

100 .... Conventional Solar Cell Module

110 ..... Solar cell 120a, 120b ... Tempered glass substrate

130 .... EVA film 132a, 132b ... electrode wire

140 .... Interconnector Ribbon

w .... Width of connecting ribbon W ..... Width of tape package

Claims (10)

A plurality of solar cells 10 for converting solar energy into electrical energy; A plurality of connecting ribbons 40 electrically connecting the solar cells 10; Front and rear glass substrates 20a and 20b for constricting and embedding the solar cell 10 and the plurality of connection ribbons 40 therebetween; And an EVA film disposed between the front and rear glass substrates 20a and 20b to bond the solar cell 10 and the plurality of connection ribbons 40 to each other during lamination. The EVA film includes a first EVA film 30a, a second EVA film 30b, and a third EVA film 30c, and the solar cell 10 includes the first EVA film 30a and the second. The package 50 is designed between the second EVA film 30b and the third EVA film 30c disposed between the EVA film 30b and disposed on the rear side of the solar cell 10. Solar cell module having a package designed between the double laminated glass, characterized in that the arrangement. The method of claim 1, wherein a colored insulating tape is further attached to correspond to the connecting ribbon 40, wherein the insulating tape has a color matching the color of the front glass substrate 20a. A solar cell module having a package designed between glass. 3. The insulating tape of claim 2, wherein the insulating tape has a color of blue or black and has a width (W) greater than the width (w) of the connecting ribbon (40). Solar cell module having a package. delete The solar cell module of claim 1, wherein the package 50 is made of a sheet, and the sheet is made of any one of a photograph, a picture, a sheet on which letters are written, a hologram sheet, or a reflective sheet having a mirror effect. . delete delete delete delete delete

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