KR101077579B1 - Solar cell module - Google Patents

Abstract

The present invention relates to a solar cell module, specifically, by forming a reflective layer inside the module, reflecting the sunlight irradiated between each unit cell of the solar cell to guide each solar cell to increase the power generation efficiency, the module The present invention relates to a solar cell module capable of suppressing a rise in temperature inside a module by reflecting sunlight irradiated to the outside to the outside.

Description

Solar cell module {SOLAR CELL MODULE}

The present invention relates to a stacked solar cell module.

Recently, as awareness of environmental problems has increased, energy supply technology using solar cells has been widely spread.

Such solar cells are used in a state in which a plurality of unit cells are connected and modularized, and such solar cell modules are mostly structured between a floodlight plate and an insulator such as glass in a state in which unit cells are connected at intervals.

However, the conventional solar cell module is a structure in which the energy is supplied only through the sunlight directly irradiated to each battery cell of the sunlight passing through the floodlight plate in this state, so to increase the number of unit cells in order to increase the power generation capacity of the solar cell module Since there is only, there is a problem that the size of the solar cell module increases.

The present invention is to provide a solar cell module that can obtain a higher power generation efficiency than conventional by using a solar cell module of the same size.

In addition, it is to provide a solar cell module that can prevent the life degradation of the unit cell due to geothermal.

Embodiment of the solar cell module structure of the embodiment of the present invention,

A solar cell having a light transmitting plate and a support plate positioned to face each other, a plurality of unit cells disposed at intervals between the light transmitting plate and the support plate, the light transmitting plate in a state located between the solar cell and the support plate It includes a reflective layer for reflecting the sunlight passing through the support plate.

The reflective layer may include a first reflection surface facing the floodlight plate, and the first reflection surface may be formed to be exposed between the unit cells.

In addition, the support plate may be made of a light-transmissive material, wherein the reflective layer may include a second reflective surface facing the support plate.

And it may further include a coating layer surrounding the first reflecting surface.

In addition, the coating layer may be made of a light transmitting material.

And a molding part surrounding the solar cell.

In addition, the molding part may be a translucent material.

The molding layer may be formed between the solar cell and the reflective layer.

The molding part may include a first molding layer formed between the support plate and the solar cell and a second molding layer positioned between the solar cell and the floodlight plate, and the reflective layer is formed on the second molding layer. It may be formed on the surface facing the floodlight plate.

The apparatus may further include a packing member formed between the floodlight plate and the support plate to surround the solar cell, and the gap between the floodlight plate and the support plate may be in a vacuum state.

In addition, the manufacturing method of the solar cell module according to this embodiment,

Arranging a plurality of unit cells connected to each other at intervals between the transparent plate and the support plate facing each other, wherein at least one surface of the surface facing the flood plate and the surface facing the support plate Disposing a reflective layer having a reflective surface capable of reflecting sunlight between the solar cell and the support plate.

And enveloping the solar cell with a molding layer between the floodlight plate and the support plate.

The method may further include covering the reflective surface with a coating layer.

And the solar cell may further comprise the step of passing the pressure disposed between the light transmitting plate and the support plate between the pressure roller to press.

The present invention according to these various embodiments,

Since the solar light irradiated between each unit cell of the solar cell is reflected by the reflective layer and then supplied to each unit cell to be used as power generation energy, it is possible to obtain higher power generation efficiency even with the same size solar cell module. have.

In addition, since the sunlight passing through the support plate from the outside is reflected by the second reflecting surface of the reflective layer is emitted, there is an advantage that can prevent the degradation of the life of the solar cell due to the internal temperature rise.

1 and 2 are views related to the first embodiment,
1 is a cross-sectional view showing an overall decomposition state
Figure 2 is an overall cross-sectional view showing a laminated structure
Fig. 3 is a sectional view showing an entire lamination state in a diagram relating to a second embodiment;
Fig. 4 is a sectional view showing an entire lamination state in a diagram relating to a third embodiment;
Fig. 5 is a sectional view showing an entire lamination state in a diagram relating to a fourth embodiment;
Fig. 6 is a sectional view showing an entire lamination state in a diagram relating to a fifth embodiment;
7 and 8 are cross-sectional views showing an entire lamination state in a diagram relating to a sixth embodiment;
Fig. 9 is a sectional view showing an entire lamination state in a diagram relating to a seventh embodiment.
10 is a process chart related to the manufacturing method

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Like parts are designated by like reference numerals throughout the specification.

1 and 2 are views of a first embodiment of the present invention, the solar cell module according to the present embodiment is largely the case portion 100, the reflective layer 200, the coating layer 300, the molding portion 400 and the solar cell 500.

First, the case part 100 serves as a casing of the solar cell 500 which is transmitted through sunlight and will be described later, and includes a light transmitting plate 110 and a support plate 120.

The floodlight plate 110 serves to protect the solar light required for electricity generation and the solar cell to be described later, and is formed in the form of a glass plate to ensure light transmittance.

Since the entire floodlight plate 110 is exposed to the outside, tempered glass may be used to prevent breakage, and may be selectively used as long as the material has a light transmitting function and sufficient strength in addition to the glass.

In addition, the shape can also be applied in a variety of variations, such as a circle in addition to the square shown in the drawing according to the installation environment.

Although not shown in the drawing, a separate protective film is attached to the surface of the floodlight panel 110 as necessary to block ultraviolet rays that adversely affect the life of the solar cell and to prevent surface damage of the floodlight panel 110 itself from the outside. To help.

The support plate 120 constituting the case part 100 together with the floodlight panel 110 serves as an installation plate when installing a solar cell protection function and a solar cell module, and has the same area and shape as the floodlight panel 110. It is in the form of a plate having a light-transmissive plate 110 and made of a light-transmissive material such as glass.

The support plate 120 and the floodlight plate 110 are disposed to face each other at a distance.

The reflective layer 200 is provided in the case part 100 described above.

The reflective layer 200 does not directly irradiate the unit cells 510 of the solar cell 500 among the sunlight passing through the floodlight panel 110, but reflects the sunlight irradiated into the spaces between the unit cells 510 to generate energy. It serves as a circle, and includes the reflective layer body 210 and the first and second reflective surfaces 220 and 240 again.

The reflective layer body 210 serves as a frame for the formation of the first and second reflective surfaces 220 and 240, which will be described later, and is in the form of a plate and faces the transparent plate 110 of the support plate 120. It is installed seated on.

In addition, the first reflecting surface 220 serves to guide the solar light passing through the floodlight panel 110 to the solar cell 500. The first reflecting surface 220 is made of a material capable of reflecting the sunlight and is formed in the reflective layer body 210. It is formed over the whole surface facing the floodlight plate 110.

The first reflecting surface 220 is made of a material having a light reflection function such as mercury, platinum titanium, or silver foil, and is formed by using a general mirror coating or a deposition method used for manufacturing a mirror.

The second reflecting surface 240 reflects light passing through the supporting plate 120 to maintain a proper temperature of the space between the floodlight panel 110 and the supporting plate 120, and is similar to the first reflecting surface 220. Alternatively, the same material is formed over the entire surface of the reflective layer body 210 facing the support plate 120.

The second reflecting surface 240 is formed using the same or similar method as the first reflecting surface 220.

The coating layer 300 is formed on the first reflection surface 220 of the reflective layer 200.

The coating layer 300 serves to protect the reflective layer 200 from corrosion by blocking exposure of the reflective layer 200. The coating layer 300 has a structure surrounding the first reflecting surface 220 in the form of a resin or film having a general corrosion protection function. do.

At this time, the coating layer 300 in the present embodiment is formed in a transparent state that can transmit sunlight.

Thus, the molding part 400 is formed between the transparent plate 110 and the support plate 120 in a state where the reflective layer 200 and the coating layer 300 are provided.

The molding part 400 serves to fix and protect the solar cell 500 to be described later, and to connect the floodlight plate 110 and the support plate 120 with ethyl vinyl acetate (EVA) or polyvinyl in the form of a film. Butyral (PolyVinylButyral (PVB)), TPT (Tedlar / PET / Tedlar), PET (PolyEthylene Terephthalate) is used.

At this time, the molding part 400 is divided into a first molding layer 410 and a second molding layer 420, wherein the first molding layer 410 is made of a transparent state so that sunlight can pass through. The coating layer 300 is formed on the surface facing the light transmitting plate 110 and the second molding layer 420 is also transparent to allow sunlight to pass through and the coating layer 300 of the light transmitting plate 110. Is formed on the side facing.

In this state, the solar cell 500 to be described later is positioned between the first and second molding layers 410 and 420, and then the first and second molding layers 410 and 420 are integrated through heat compression.

The solar cell 500 is a substantially power generation function using the sunlight, the unit cells 510 are formed in a form having a dust collecting structure is connected to each other by a separate ribbon 520 in a state arranged at intervals and the first molding Located between layer 410 and second molding layer 420.

As such, since the unit cells 510 are disposed at intervals, the first reflection surface 210 of the reflective layer 200 is exposed between each unit cell 510 through the first molding layer 410 and the coating layer 300. It becomes a state.

The reflective layer 200, the coating layer 300, the molding part 400, and the solar cell 500 are sequentially stacked between the transparent plate 110 and the support plate 120, and the transparent plate 110 is externally disposed. As the support plate 120 is pressed and heated, the first molding layer 410 and the second molding layer 420 are integrated with each other, thereby performing an adhesive function between the light transmitting plate and the support plate, thereby integrating the laminate structure.

Hereinafter will be described the operation of this embodiment by the configuration and the unique effects generated in the process.

The solar cell module is installed in the form of seating the support plate 120 on the installation point, etc. In this state, as shown in FIG. 2, the sunlight S passing through the floodlight panel 110 is the second molding layer. After passing through 420, most of the solar cells 500 are directly irradiated to each unit cell 510 and used as power generation energy.

In this case, since the first molding layer 410 and the coating layer 300 are transparent, each unit cell 510 of the solar cell is formed through the first molding layer 410 and the coating layer 300 of the first reflective surface 220 of the reflective layer 200. Since the light is exposed to each other, the sunlight irradiated between the unit cells 510 is irradiated to the first reflecting surface 220 in this process.

The solar light irradiated onto the first reflecting surface 220 is reflected from the first reflecting surface 220, and then passes through the coating layer 300 and the first molding layer 410, and then each solar cell unit cell 510. Is supplied.

By using the reflective layer 200 to guide the unit cell 510 to the sunlight not directly irradiated to the unit cell 510, it is possible to maximize the power generation efficiency of the solar cell.

And the solar light (S) irradiated toward the support plate 120 passes through the support plate () and then is reflected by the second reflecting surface 240 of the reflective layer 200 is emitted to the outside again solar cells due to sunlight It is possible to prevent the temperature inside the module from rising.

In addition, if the support plate 120 is installed close to the ground, the ground heat is conducted to the support plate 120, but because the infrared rays included in the geothermal heat is reflected by the second reflecting surface 240, It is also possible to prevent the internal temperature rise.

As described above, the present invention is characterized by maximizing the collection capacity of the solar light using a reflective layer to increase the power generation efficiency and at the same time suppress the unnecessary temperature rise in the interior to extend the life of the product.

Hereinafter, various modifications to the present invention will be described.

3 is a view of a second embodiment of the present invention. The basic structure is the same as the above embodiment, but each solar cell unit is not formed on the entire surface of the reflective layer body 210. There is a difference in locally formed only at points between the cells 510.

Anyway, since the reflection of the sunlight is made only at the point exposed between each unit cell 510 of the first reflecting surface 220, when the first reflecting surface 220 is formed between each unit cell 510, It is possible to reduce the material used for the first reflective surface 220 and to simplify the manufacturing of the entire reflective layer.

4 is a view of a third embodiment of the present invention. The basic structure is the same as that of the first embodiment, but the second reflection surface 240 is formed on the reflective layer body 210 by changing the structure of the reflective layer 200. There is a difference in forming the bay.

In this case, there is no effect of reflecting sunlight irradiated between each unit cell 510 among the sunlight passing through the floodlight panel 110 to guide each unit cell 510, but passing through the support plate 120 from the outside. The effect of suppressing an increase in the temperature inside the module due to light, geothermal heat, or the like has an effect.

In this case, since the coating layer 300 and the second molding layer 420 do not need to have a solar light transmitting function, the coating layer 300 and the second molding layer 420 may be opaque.

FIG. 5 is a view showing a fourth embodiment of the present invention, in which the present embodiment can be considered when installed in a place where the temperature rise inside the module is not largely considered. That is, the case where only the first reflecting surface 220 is formed in the reflective layer 200.

In this case, although the effect of suppressing the internal temperature increase due to the second reflecting surface is not obtained, there is an effect of increasing power generation efficiency by reflecting the sunlight irradiated between each unit cell 510 and supplying it to each solar cell. do.

6 is a view showing a fifth embodiment of the present invention, in which the second reflective surface 240 is omitted in the same manner as in the fourth embodiment, even though the second reflective surface 240 is not formed. It is characterized in that internal temperature rise suppression effect can be obtained.

To this end, the support plate 120 itself is made of opaque to prevent the transmission of sunlight, or as a separate auxiliary reflection layer 600 is formed on the surface of the support plate 120 as shown in the drawing, the sunlight does not pass through the support plate By being reflected by the reflective layer 600, it is possible to increase the suppression effect of the temperature rise inside the module.

In this case, the auxiliary reflection layer 600 may be manufactured in the form of a white paint or a separate reflector film, and may be implemented in various forms such as coating, attaching, or depositing the surface of the support plate 120.

7 is a view showing a sixth embodiment of the present invention, in which the structure in which only the second reflection surface 240 is formed on the reflective layer body 210 is the same as in the third embodiment, but the molding part 400 is formed. It is characterized in that to achieve the same effect as the first reflective surface 220 by using.

To this end, the second molding layer 420 of the molding part 400 is formed to be transparent, while the first molding layer 410 is formed to be opaque and manufactured in a form that can reflect sunlight.

For example, the resin itself used in the second molding layer 420 is used in white, or as shown in the drawing, the first reflective surface is formed on the surface of the second molding layer 420.

At this time, the coating layer 300 may be manufactured in an opaque state rather than transparent.

Therefore, the sunlight irradiated between the unit cells 510 among the sunlight passing through the floodlight panel 110 and the second molding layer 420 is reflected from the first molding layer 410 and supplied to each unit cell 510. do.

In addition, if the second reflecting surface 240 is unnecessary because the internal temperature of the module is less likely to rise, the second molding layer 420 may be applied to the second molding layer 420 in the state where the reflective layer body 210 and the second reflecting surface 240 are omitted. It is also possible to obtain only the solar reflection function.

In addition, as shown in FIG. 8, the first and second reflection surfaces 220 and 240 may be formed on both surfaces of the first molding layer 410 in the state where the reflective layer body is omitted.

In this case, the first and second reflection surfaces 220 and 240 may be implemented in a structure formed in the first molding layer 410 in the form of a white paint or a film having a solar reflection function.

In this case, the second molding layer 420 eventually functions as the reflective layer body 210.

In addition, Figure 9 relates to the seventh embodiment of the present invention, the present embodiment is characterized in that the sealing inside the module is made through the vacuum forming structure, not made to the molding portion 400.

To this end, in the present embodiment, the packing member 700 positioned between the light transmitting plate 110 and the supporting plate 120 is formed along the edge of the reflective layer 200 in a state where the molding part 400 is omitted.

Therefore, the space in which the solar cell 500 is installed is sealed from the outside by the packing member 700, and in this state, the space in which the solar cell 700 is installed becomes a vacuum state as air is extracted from the interior space to the outside. .

Since the vacuum forming process is performed at room temperature, the manufacturing time of the solar cell may be shortened as compared with the case where a high temperature compression process is required for the melting of the molding part 400.

Although not shown in the drawing, the coating layer 300 may be omitted when there is no fear of corrosion by reinforcing its own strength and the like of the first reflective surface 220.

Next, the manufacturing method of the solar cell module according to various embodiments will be described with reference to FIG. 10.

First, a step of manufacturing the light transmitting plate 110 and the support plate 120 is performed, in which case the support plate 120 may be manufactured in a transparent or opaque state as described above, and the sub-reflective layer 600 in the form of a white paint or film on the surface thereof. It may also be manufactured in a structure formed.

Thereafter, the solar cell 500 is positioned between the floodlight panel 110 and the support plate 120, and the reflective layer 200 is formed between the solar cell 500 and the support plate 120.

In this case, the reflective layer 120 forms only the first reflective surface 220 facing the light transmitting plate 110 so that the first reflective surface 220 is positioned between each unit cell 510, or the light transmitting function of the support plate 120 is provided. When having a second reflection surface 240 may be formed only, the first reflection surface 220 and the second reflection surface 240 may be formed at the same time.

In addition, the molding unit 400 undergoes a step of installing the solar cell 500 in a wrapping form, wherein the molding unit 400 is formed between the solar cell 500 and the floodlight panel 110. 420 and the first molding layer 410 formed between the solar cell 500 and the support plate 120.

In addition, the first molding layer 410 is formed separately between the reflective layer 200 and the solar cell 500 or the first molding layer 410 has a solar reflection function so that the first molding layer 410 is a reflective layer, That is, the first reflecting surface 220 may have a function.

The coating layer 300 is further formed on the first reflection surface 220 of the reflective layer 200.

In addition, after the formation of the molding part is completed by transferring the solar cell module between the separate pressure roller to press the light transmitting plate 110 and the pressure plate 120 toward each other by the pressure roller while being integrated by the molding unit 400 As the process is completed, the manufacturing process is completed.

Although the preferred embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concepts defined in the following claims are also the rights of the present invention. It belongs to the range.

100: case 110: floodlight
120: support plate 200: reflective layer
210: reflective layer body 220: first reflecting surface
240: second reflective surface 300: coating layer
400: molding part 410: first molding layer
420: second molding layer 500: solar cell
510: unit cell 600: auxiliary reflective layer
700: packing member S: solar light

Claims (14)

Floodlight and support plate which are located facing each other,
A solar cell having a plurality of unit cells arranged at intervals between the floodlight plate and the support plate; and
A reflective layer positioned between the solar cell and the support plate and having a flat surface and reflecting sunlight passing through the floodlight or the support plate;
Solar cell module comprising. In claim 1,
The reflective layer,
A first reflective surface facing the floodlight plate,
The first reflecting surface is exposed between each unit cell so that the sunlight reflected through the first reflecting surface is supplied to each unit cell.
Solar module. In claim 1,
The support plate is made of a light-transmissive material,
The reflective layer includes a second reflecting surface facing the support plate. The method of claim 1 or 2,
The solar cell module further comprises a coating layer surrounding the first reflecting surface. In claim 4,
The coating layer is a solar cell module made of a light-transmissive material. The method of claim 1 or 2,
The solar cell module further comprises a molding unit surrounding the solar cell. In claim 6,
The molding unit is a solar cell module of a light transmitting material. In claim 7,
The molding layer is a solar cell module is formed between the solar cell and the reflective layer. In claim 6,
The molding part,
A first molding layer formed between the support plate and the solar cell, and a second molding layer positioned between the solar cell and the floodlight plate,
The reflective layer is formed on the surface of the second molding layer facing the light transmitting plate. In claim 1,
Further comprising a packing member formed between the floodlight plate and the support plate to surround the solar cell,
A solar cell module in which the gap between the floodlight plate and the support plate is in a vacuum state. Disposing a solar cell having a plurality of unit cells connected to each other at intervals between the floodlight plate and the support plate facing each other;
Disposing a reflective layer between the solar cell and the support plate having a reflective surface having a flat surface capable of reflecting sunlight on at least one of a surface facing the floodlight plate and a surface facing the support plate;
Solar cell module manufacturing method comprising a. In claim 11,
Wrapping the solar cell with a molding layer between the floodlight plate and the support plate;
Solar cell module production method further comprising. The method of claim 11 or 12,
The solar cell module manufacturing method further comprising the step of covering the reflective surface with a coating layer. The method of claim 11 or 12,
The solar cell further comprises the step of passing the state disposed between the transparent plate and the support plate between the pressure roller to press
Solar cell module manufacturing method.

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