KR101120101B1 - Solar Cell Module with Structure improved Glass - Google Patents

Abstract

The present invention relates to a solar cell module equipped with an improved glass structure. According to the present invention, a bus bar 110 and a ribbon 120 formed on a portion of the front surface of the solar cell 100 are formed, and the front surface of the solar cell 100 includes the bus bar 110 and the ribbon 120. EVA 130 is formed. The glass 150 to which sunlight is applied is formed on the EVA 130. The glass 150 is formed so that the half arc shape portion 170 coincides only with the bus bar 110 and the ribbon 120, and the uneven pattern portion 180 is formed at the center portion of the half arc shape portion 170. Is formed. A plurality of pyramidal shapes are formed in the uneven pattern portion 180. Thus, when light is incident on the glass 150, the region in which the half arc portion 170 is not formed is directly incident into the solar cell 100, and the uneven pattern portion is formed in the region where the half arc portion 170 is formed. In the region where 180 is not formed, incident light is incident into the solar cell 100 by one refraction. In the region where the uneven pattern portion 180 is formed, the surface of the ribbon 120 and the glass 150 are formed. The solar cell 100 is incident to the solar cell 100 through at least two reflections from the surface. According to the present invention, it is possible to minimize the loss of the incident light, there is an advantage that the efficiency of the solar cell module is improved.

Solar cell, Solar cell module, Glass, Unevenness, Pyramid, Reflection

Description

Solar Cell Module with Structure improved Glass

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to glass for solar cells, and more particularly, to a solar cell module having a structure improved glass so that light incident on the front surface of the solar cell can be more absorbed into the solar cell substrate.

Recently, as interest in environmental problems and energy depletion has increased, interest in solar cells is increasing as alternative energy with abundant energy resources, no problems with environmental pollution, and energy efficiency.

The solar cell is an energy conversion element that converts light energy of the sun into electrical energy by applying a photovoltaic phenomenon, the efficiency is different depending on the structure of the solar cell. Accordingly, the solar cell may be said to absorb the maximum amount of sunlight as the greatest issue. To this end, various structures of solar cells are being developed, and researches to further increase the absorption efficiency of solar light have been continuously developed in relation to the solar cell front structure.

On the other hand, the solar cell has a very small voltage coming from one cell (Cell) is a small unit, it is easily affected by the external environment. Therefore, the cell is packaged to manufacture a solar cell module. Such solar cell modules are used in the field to substantially obtain electrical energy, and the size of the solar cell modules is designed to be variable according to power generation capacity.

The solar cell module is equipped with a glass on the front. The sunlight passes through the glass and is incident on the solar cell.

However, when the glass most used on the front surface of the solar cell module is flat, about 8% of the incident light is first reflected by the glass surface and loss occurs.

In addition, if the bus bar formed on the surface of the solar cell is also flat, light passing through the glass and entering the solar cell module secondly is reflected by the bus bar, causing loss.

For this reason, in the solar cell module, it is proposed to form a separate lens on the glass or to form a specific pattern on the busbar in order to improve the absorption of sunlight.

First, a lens is formed on the glass. The lens is a microlens, and generally has a structure of at least about 60% of the total area of the glass, the number of microlenses is formed at least 160 / cm2.

This refracts the light reflected from the glass surface when the light is incident at a non-vertical angle, thereby minimizing light reflection.

Next, a V-shaped groove is formed on the bus rock by using metal forming technology. This is to prevent light incident on the busbar from being absorbed and reflected by the busbar and exiting the module.

When the pattern is formed on the bus bar, the light that has been incident to the bus bar at 90% and then totally reflected and lost is reflected by changing the angle of reflection by using the pattern, thereby reflecting back to the secondary in the glass to be absorbed into the module.

In this way, it was confirmed that the efficiency of the solar cell module was increased by about 2% compared to the case where no pattern was formed on the bus bar.

However, the above techniques have the following problems.

When the microlens is formed on the glass, the light refracted by the microlens formed on the glass may also be incident on the upper surface of the busbar surface or the side surface of the busbar and may be reflected back or absorbed to cause light loss. have.

In the case of forming a pattern on the busbar, when improper bonding during the tabbing and string of the solar cell module manufacturing process or damage to the ribbon surface during the process, light incident on the busbar ribbon The amount of sunlight reflected and absorbed into the solar cell substrate may be reduced.

Accordingly, an object of the present invention is to solve the above problems, while maintaining the shape of the busbar ribbon, while refracting the light incident on the upper side of the busbar ribbon to the inside of the solar cell to improve the absorption rate It is to provide a glass for batteries.

Another object of the present invention is to provide a solar cell module equipped with an improved solar cell glass.

According to a feature of the present invention for achieving the above object, a solar cell: a bus bar and a ribbon formed on a portion of the front surface of the solar cell: a protective sheet formed on the front surface of the solar cell including the bus bar and ribbon: And a glass formed on the protective sheet, wherein the glass has a half arc-shaped portion coincident with only the upper portion of the bus bar and the ribbon, and an uneven pattern is formed at the center portion of the half arc-shaped portion.

The uneven pattern is a pyramid pattern.

When light is incident on a region where the uneven pattern is not formed in the half arc shape portion, the incident light is refracted and incident directly to the solar cell.

When light is incident on a region where the uneven pattern is formed in the half arc shape portion, the incident light is incident on the solar cell through at least two reflections of the ribbon surface and the glass surface.

In the present invention, the surface of the glass for solar cell module is formed in a concave shape in a half arc shape, and a concave-convex pattern (that is, a pyramid shape) is formed in the center portion of the half arc shape.

Then, the light incident on the flat surface of the glass among the light incident on the glass is directly incident on the solar cell, and the light incident on the region where the uneven pattern is not formed among the light incident on the half arc shape is refracted once and the solar cell The light incident on the cell and incident on the region where the uneven pattern is formed is incident on the solar cell through the reflection operation between the ribbon surface and the glass surface.

Therefore, since most of the light incident on the glass for the solar cell module is induced to enter the solar cell, the probability of generating electron-holes inside the solar cell is increased, thereby increasing the efficiency of the solar cell. It has an effect.

Hereinafter, exemplary embodiments of a solar cell module equipped with an improved glass structure according to the present invention will be described in detail with reference to the accompanying drawings.

In this embodiment, a specific pattern is formed on the glass of the solar cell module so that the light incident on the bus bar / ribbon is refracted into the solar cell to improve the light absorption rate.

1 is a cross-sectional view showing the structure of a glass for solar cells according to an embodiment of the present invention.

1, the solar cell 100 is provided.

In addition, a bus bar 110 is formed on a part of the front surface of the solar cell 100 to transfer a minority carrier generated by incident sunlight to an electrode, and the sun is formed on an upper surface of the bus bar 110. A ribbon 120 for connecting the battery cells 100 is formed.

The upper surface of the solar cell 100 and the lower surface of the solar cell 100 on which the bus bar 110 / ribbon 120 is formed are EVA (protective sheet) to prevent foreign matter or moisture from invading from the outside. Ethylene Vinyl Acetate) 130 and 140 are formed. The EVA on the top surface of the solar cell 100 is shown by reference numeral '130', and the EVA on the bottom is shown by reference numeral '140'.

A glass 150 is formed on the upper side EVA 130, and a back sheet 160 is formed below the lower side EVA 140.

The glass 150 is formed with a half arc shape 170 concave on the surface. The half arc shape portion 170 is formed to coincide with an area where the bus bar 110 / ribbon 120 is formed.

The uneven pattern portion 180 is formed at the central portion of the half arc shaped portion 170. The uneven pattern portion 180 refers to a plurality of pyramid patterns are formed. The pyramid pattern is formed along the surface of the half arc shaped portion 170. In the embodiment, five pyramid patterns are formed.

The pyramid pattern is for changing the angle of the incident angle of the incident light when the light is incident. That is, when light is incident on the oblique surface forming the pyramid, the incident light is refracted toward the inside of the solar cell 100 through two or more reflection processes on the surfaces of the ribbon 120 and the glass 150.

The pattern formation of the glass 150 may be formed during a tempering process of heating and polishing glass in a general glass manufacturing process.

2 is a state diagram illustrating a traveling direction of incident light when light is incident on the glass for solar cells of FIG. 1.

When light is incident from the outside, light incident to the region A other than the half arc is directly incident to the inside of the solar cell 100 via the glass 150 and the EVA 130. In the figure, the solid lines are shown. The incident light generates electron-hole pairs in the solar cell 100.

The following is a case where light is incident on the region B in which the half arc portion 170 is formed.

In this case, the semi-arc portion 170 may be divided into a non-uneven pattern region B ′ in which the uneven pattern portion 180 is not formed, and a uneven pattern region B ″ in which the uneven pattern portion 180 is formed. have.

First, it is a case where sunlight is incident on the non-concave-convex pattern region B '.

Since the angle of refraction is larger than the center of the half arc portion 170 in the region, most of the incident light is refracted at the surface of the half arc portion 170 and directed toward the inside of the solar cell 100. Incident light is indicated by a dotted line.

The following is a case where sunlight is incident on the uneven pattern area B ″.

Since the region is in the central portion of the half arc portion 170, the angle at which the incident light is refracted is low and the angle of incidence is nearly 90 °.

However, since the uneven pyramid pattern is formed in the half arc shaped portion 170, the light reaching the oblique surface of the pyramid is the upper surface of the ribbon 120 due to the formation position of the pyramid and the incident angle when the light reaches the oblique surface. In the reflection occurs, the glass 150 is reflected to the side, and the light reaching the glass 150 is reflected again to be directed into the solar cell 100. This state is indicated by a dashed-dotted line and a double-dotted line in the figure.

As such, it can be seen that most of the incident light is incident into the solar cell 100.

That is, according to the present embodiment, the half arc shaped portion 170 is formed on the glass 150, and the uneven pattern portion 180 having the pyramid shape is formed at the center portion of the half arc shaped portion 170. The uneven pattern portion 180 is refracted to enter the solar cell 100 through two or more reflection processes by changing the refractive angle of the incident light.

Although described with reference to the illustrated embodiment of the present invention as described above, this is merely exemplary, those skilled in the art to which the present invention pertains various modifications without departing from the spirit and scope of the present invention. It will be apparent that other embodiments may be modified and equivalent. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

That is, in the present embodiment, a pyramidal shape is formed in the uneven pattern portion, but other structures that can refract most of the incident light into the solar cell 100 in addition to the pyramid shape are applicable to the present invention.

1 is a cross-sectional view showing the structure of a glass for solar cells according to an embodiment of the present invention

FIG. 2 is a state diagram illustrating a traveling direction of incident light when light is incident on the glass for solar cells of FIG. 1; FIG.

* Description of the symbols for the main parts of the drawings *

100: solar cell 110: bus bar

120: ribbon 130, 140: EVA

150 glass 160 rear sheet

170: half arc shape part 180: uneven pattern part

Claims (4)

Solar cell: Bus bars and ribbons formed on a portion of the front surface of the solar cell: A protective sheet formed on the front surface of the solar cell including the bus bar and a ribbon: And It includes a glass formed on the protective sheet, The glass has a concave half-arc portion formed only at the upper portion of the bus bar and the ribbon, and a concave-convex pattern is formed at a central portion of the concave half-arc portion. Solar module. The method of claim 1, The concave-convex pattern is a pyramid pattern solar cell module with a glass structure improved. The method of claim 1, When light is incident on a region in which the uneven pattern is not formed in the half arc shape portion, the incident light is refracted and directly incident on the solar cell. The method of claim 1, When light is incident on a region where the uneven pattern is formed in the half arc shape, the incident light is incident on the solar cell through at least two reflections of the ribbon surface and the glass surface. Installed solar cell module.

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