KR20190119268A - Solar cell module with half-cut cell - Google Patents

Abstract

The present invention relates to a solar cell module using division cells which optimizes geometrical shape of a string connector and a parallel connection ribbon to minimize reflection by the string connector and the parallel connection ribbon while increasing a re-incidence rate of light. According to the solar cell module using division cells, which is configured by using a plurality of division cells, the plurality of division cells are classified by a first cell assembly set and a second cell assembly, the first assembly or the second cell assembly has a plurality of cell strings, each of cell strings has a plurality of division cells serially connected, and neighboring cell strings are serially connected by means of the string connector. Cell strings facing the first cell assembly and the second cell assembly are connected in parallel by means of the parallel connection ribbon. A cross section area of the string connector is a half to one time of a cross section area of the parallel connection ribbon.

Description

Solar cell module using split cell {Solar cell module with half-cut cell}

The present invention relates to a solar cell module using a split cell, and more particularly, by optimizing the geometry of the string connector and the parallel connection ribbon to minimize the reflection by the string connector and the parallel connection ribbon and improve the re-incidence rate of light. It relates to a solar cell module using a split cell.

Various structures have been proposed to improve the photoelectric conversion efficiency of solar cells. As a method for increasing the light receiving area, a back electrode solar cell has been proposed, and a double-sided light receiving solar cell that receives light through both sides of the solar cell has been applied. In addition, a method of applying a wire-type interconnector to a solar cell module has recently been proposed in order to avoid a reduction in light receiving area by a ribbon interconnector.

Another method for improving the photoelectric conversion efficiency of the solar cell is a method using a split cell. The divided cell refers to a conventional solar cell (hereinafter, referred to as a "normal cell") divided into two or more equal parts. The normal cell generally has a width of 6 inches (about 156 mm x 156 mm), which is divided into two or more parts, called a split cell. As the divided cell is smaller in size than the normal cell, the resistance decreases, thereby improving the output of the solar cell. Reportedly, a solar cell module consisting of a split cell is known to have an output of about 2% or more superior to a solar cell module consisting of a normal cell.

When the solar cell module is composed of the divided cells, it has a circuit configuration as shown in FIG. Specifically, the solar cell module includes a plurality of split cells 1, and the plurality of split cells 1 is divided into a plurality of cell strings S1, S2, S3, S4, S5, and S6. do. The plurality of cell strings S1, S2, S3, S4, S5, and S6 are arranged side by side in a plurality of rows, and each cell string is divided into a plurality of split cells 1 in a column. It is composed. In other words, a plurality of split cells 1 are arranged in a column direction to form one cell string, and the cell strings are arranged in a plurality of row directions.

On the other hand, when the solar cell module is composed of a split cell (1), for example, a split cell (1), the short-circuit current is 1/2 times and the open voltage is It has twice the electrical properties. In order to solve the electrical characteristics different from those of the normal cell solar cell module product, in the case of the solar cell module composed of the split cells 1, the plurality of split cells 1 constituting the solar cell module are divided into two cell aggregates. The circuit is designed so that two cell aggregates are connected in parallel.

For example, in the case of a solar cell module composed of 60 normal cells, 10 cells form one cell string and the solar cell module consists of 6 cell strings. In the case of a solar cell module composed of split cells 1, the solar cell module is composed of 120 split cells 1, with 60 split cells 1 forming the first cell assembly 10 and the remaining 60 split cells. (1) constitutes the second cell aggregate 20, and the cell strings S1 (S2) (S3) consisting of ten divided cells 1 in each of the first cell aggregate 10 and the second cell aggregate 20. ) (S4) (S5) (S6) forms a form arranged six.

The first cell aggregate 10 and the second cell aggregate 20 are connected in parallel in the following manner. The parallel connection ribbon 40 is provided between the first cell assembly 10 and the second cell assembly 20, and the divided cells 1 and the first cell assembly 10 of the first cell assembly 10 adjacent to the parallel connection ribbon 40 are provided. The divided cells 1 of the two cell aggregate 20 are connected in parallel to the parallel connection ribbon 40. For the parallel connection, the divided cells 1 of the first cell aggregate 10 and the divided cells 1 of the second cell aggregate 20 connected to the parallel connection ribbon 40 have the same polarity. For example, the interconnector 1a connected to the front electrode of the division cell 1 of the first cell assembly 10 and the interconnector 1a connected to the front electrode of the division cell 1 of the second cell assembly 20. ) Is connected to the parallel connection ribbon (40). As such, the strings facing each other of the first cell assembly 10 and the second cell assembly 20 are connected to the parallel connection ribbon 40.

Meanwhile, as described above, each of the first cell aggregate 10 and the second cell aggregate 20 includes cell strings S1, S2, S3, S4, and S5, each of which is composed of five divided cells 1. S6) forms a six-array form, and neighboring cell strings are connected in series by the string connector 30.

The string connector 30 serves to serially connect neighboring cell strings in each cell aggregate, and the parallel connection ribbon 40 is a cell string of the first cell aggregate 10 and a cell string of the second cell aggregate 20. It acts as a parallel connection.

The string connector 30 and the parallel connection ribbon 40 generally use a conductor having a rectangular cross section. However, there is a problem in that the received light is partially reflected by the surface of the string connector 30 or the parallel connection ribbon 40 by using a conductor having a rectangular cross section.

Korean Registered Patent Publication No. 1199822

The present invention has been made to solve the above problems, by minimizing the reflection by the string connector and parallel connection ribbon by optimizing the geometry of the string connector and parallel connection ribbon and can improve the re-incidence of light. The purpose is to provide a solar cell module using a split cell.

In the solar cell module using a split cell according to the present invention for achieving the above object in the configuration of a solar cell module using a plurality of split cells, the plurality of split cells are the first cell aggregate and the second cell aggregate The first cell aggregate or the second cell aggregate includes a plurality of cell strings, each cell string includes a plurality of divided cells connected in series, and neighboring cell strings are serially connected through a string connector. The cell strings facing the first cell assembly and the second cell assembly are connected in parallel via a parallel connection ribbon, and the cross-sectional area of the string connector is 1/2 to 1 times that of the parallel connection ribbon.

The string connector includes a plurality of wire string connectors having a wire shape. The plurality of wire string connectors are arranged side by side in a direction orthogonal to the cell string, and the interconnector extending from the split cell adjacent to the wire string connector is electrically connected to the plurality of wire string connectors.

At least one of the parallel connection ribbon and the string connector is designed to have a slant. In addition, the inclined surface of the string connector is directed toward the inside of the solar cell module.

The dividing cells of the first cell assembly and the dividing cells of the second cell assembly, which are adjacent to the parallel connection ribbon, are connected in parallel through a parallel connection interconnector, and the parallel connection ribbon and the parallel connection interconnector are provided in an intersecting form. And can be electrically connected.

The plurality of divided cells belonging to the first cell aggregate or the second cell aggregate are connected in series by an interconnector for electrically connecting neighboring divided cells, and the parallel interconnector is adjacent to the parallel connection ribbon and faces the first cell. The divided cells of the aggregate and the divided cells of the second cell aggregate can be connected with the same polarity.

The parallel interconnector extends from the front or rear of the split cell of the first cell aggregate adjacent to the parallel ribbon and extends across the parallel ribbon to the front or rear of the split cell of the second cell aggregate adjacent to the parallel ribbon. . In addition, an interconnector extending from each of the divided cells of the first cell assembly and the divided cells of the second cell assembly facing adjacent to the parallel connected ribbon may be connected to the parallel connected ribbon, respectively.

The solar cell module using the split cell according to the present invention has the following effects.

By minimizing the reflection of light by the string connector and the parallel connection ribbon, the string connector that connects the neighboring cell strings in series is composed of a plurality of wire string connectors and the parallel connection ribbon that connects the cell assemblies in parallel has a slope. It can improve the reincident rate of light. String connectors can also be designed to have an inclined plane, which also minimizes light reflection and improves light re-incidence.

1 is a block diagram of a solar cell module using a split cell according to the prior art.
2 is a block diagram of a solar cell module using a split cell according to an embodiment of the present invention.
3 is a cross-sectional view taken along line AA ′ of FIG. 2.
Figure 4 is a reference diagram showing the cross-sectional shape of the string connector and parallel connection ribbon.
5 is a block diagram of a solar cell module using a split cell according to another embodiment of the present invention.

The present invention proposes a technique for optimizing the geometry of the string connector and parallel connection ribbon in configuring a solar cell module using a split cell.

As mentioned above in the background technology of the present invention, when configuring a solar cell using a plurality of divided cells, a string connector and a parallel connection ribbon are required. A string connector is a conductor that connects neighboring cell strings in series, and a parallel connection ribbon is a conductor that mediates parallel connection between cell aggregates. The parallel connection ribbon is provided in the space between the cell aggregates, and the string connector is provided at one end of the cell aggregates. Such string connectors or parallel connection ribbons generally have a thin, long, rectangular parallelepiped shape and have a large surface area. As the string connector or the parallel connection ribbon has a large surface area, the incident light is reflected by the surface of the string connector or the parallel connection ribbon.

The present invention minimizes the reflection of light by the string connector and the parallel connection ribbon and induces the reentry by designing the parallel connector ribbon with the inclined surface while replacing the rectangular-shaped string connector with the wire-shaped string connector. To present. The string connector may be designed to have a slant like the parallel connection ribbon in addition to the plurality of wire string connectors, and the slant of the string connector may be directed toward the inside of the solar cell module.

In addition, the present invention proposes a technology that can reduce the material cost required for the string connector by designing the cross-sectional area of the string connector to 1/2 to 1 times the cross-sectional area of the parallel connection ribbon. As described above, when the normal cell is configured of a solar cell module using a divided cell divided into two, the solar cell module is composed of a first cell aggregate and a second cell aggregate, the first cell aggregate and the second cell aggregate A parallel connector structure is constructed. In the first cell assembly or the second cell assembly, only half of current flows in the string connector connecting neighboring cell strings compared to the parallel connection ribbon. In consideration of this, the cross-sectional area of the string connector can be designed to be 1/2 times the cross-sectional area of the parallel connection ribbon, or the cross-sectional area of the string connector can be designed to be 1/2 to 1 times the cross-sectional area of the parallel connection ribbon. The cost of materials can be reduced.

Hereinafter, a solar cell module using a split cell according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

2, a solar cell module using a split cell according to an embodiment of the present invention includes a plurality of split cells 1. The dividing cell 1 refers to a conventional solar cell, that is, a normal cell divided into two or more equal parts, and the normal cell may be formed to be 6 inches wide (about 156 mm x 156 mm) or another size. .

The plurality of split cells 1 constituting the solar cell module are divided into a first cell assembly 50 and a second cell assembly 60. When the plurality of split cells 1 constituting the solar cell module is 60, 30 split cells 1 belong to the first cell assembly 50, and 30 split cells (1) belong to the second cell assembly 60. 1) This belongs. Here, the number of cell aggregates is set differently according to the divided cell 1 divided into normal cells. When the divided cells 1 are n equal parts of the normal cells (n is a natural number), the number of cell aggregates is set to n. In the following description, for convenience of description, the divided cells 1 will be described in the form of bisecting normal cells, two cell aggregates, and a total number of divided cells 1.

Thirty divided cells 1 belonging to the first cell assembly 50 or the second cell assembly 60 are divided into six cell strings. Each cell string is composed of five divided cells 1 connected in series, and neighboring cell strings are connected in series through a string connector.

The string connector is provided at one end of the first cell assembly 50 or the second cell assembly 60 to electrically connect the neighboring cell strings, for example, the first cell string and the second cell string. In order for the first cell string and the second cell string to be connected in series by a string connector, the arrangement direction of the split cells 1 of the first cell string and the second cell string is opposite to each other. If the polarity of the split cell 1 of the first cell string in contact with the string connector is a positive electrode, the polarity of the split cell 1 of the second cell string in contact with the string connector is a negative electrode. In other words, the interconnector 1a connected to the front electrode of the division cell 1 of the first cell string is connected to the string connector, and the interconnector 1a connected to the rear electrode of the division cell 1 of the second cell string. ) Is connected to the string connector.

The string connector may be composed of a plurality of wire string connectors 70 having a wire shape of a predetermined diameter (see FIGS. 2 and 3). The plurality of wire string connectors 70 are arranged side by side adjacent to each other, and the interconnector 1a extending from the front electrode or the rear electrode of the split cell 1 is electrically connected to the plurality of wire string connectors 70. As the string connector is composed of a plurality of wire string connectors 70 having a wire shape, reflection of the received light by the wire string connector 70 is reduced as compared with the rectangular parallelepiped string connector. In addition, as the cross-section of the wire string connector 70 is circular, the probability that the received light is diffusely reflected is greater than that of the rectangular parallelepiped string connector, thereby inducing the re-incidence of light.

As described above, the string connector may be designed to have a slanted surface in another embodiment, in addition to the embodiment of the plurality of wire string connectors. That is, the string connector can be configured so that the cross section has a trapezoidal shape or an uneven shape (see FIGS. 4A to 4C). In this case, in order to induce diffused reflection into the solar cell module, the inclined surface of the string connector is preferably designed to face the solar cell module.

On the other hand, the first cell aggregate 50 and the second cell aggregate 60 are connected in parallel via a parallel connection ribbon (80). Specifically, the parallel connection ribbon 80 is provided between the first cell assembly 50 and the second cell assembly 60, and the divided cells 1 of the first cell assembly 50 adjacent to the parallel connection ribbon 80 are provided. ) And the split cell 1 of the second cell assembly 60 are connected in parallel via the parallel connection ribbon 80. The split cell 1 of the first cell aggregate 50 adjacent to the parallel connected ribbon 80 and the split cell 1 of the second cell aggregate 60 connected in parallel are divided into two segments adjacent to the parallel connected ribbon 80. As the cells 1 are connected with the same polarity, each string of the first cell assembly 50 and each string of the second cell assembly 60 are arranged in a symmetrical form with respect to the parallel connection ribbon 80. do.

The parallel connection ribbon 80 is designed to have a slope. Like other embodiments of the above-described string connector can be designed to have a bevel. That is, the parallel connection ribbon 80 can be comprised so that a cross section may form trapezoid shape or an uneven | corrugated shape (refer FIG. 4 (a)-(c)). As the parallel connection ribbon 80 has a slope, the light received through the slope can smooth the angle of reflection, thereby increasing the re-incidence rate of the light.

On the other hand, when looking at the parallel connection structure by the parallel connection ribbon 80 in detail, the two divided cells 1 adjacent to the parallel connection ribbon 80 is the same interconnector (1a) (hereinafter, 'parallel connection' Interconnection (1b) 'is connected to each other, and the parallel connection interconnector (1b) forms a structure in which the parallel connection ribbon 80 is electrically connected through soldering or the like. That is, the parallel connection interconnector 1b connects two split cells 1 facing each other adjacent to the parallel connection ribbon 80, and the parallel connection interconnector 1b and the parallel connection ribbon 80 are electrically connected to each other. do. Here, the interconnector (1a) refers to a conductor that electrically connects the neighboring split cells (1), the parallel interconnector (1b) is two adjacent to the parallel connection ribbon (80) The interconnector 1a that connects the division cells 1 is specified. Such an interconnector 1a or a parallel connection interconnector 1b is provided on a bus bar (not shown) or a conductive pad (not shown) of the division cell 1.

In addition to the parallel connection structure as described above, that is, the structure connecting two split cells 1 adjacent to the parallel connection ribbon 80 through the same parallel connection interconnector 1b, as shown in FIG. It is also applicable to a structure in which the interconnectors 1a extending from each of the two split cells 1 adjacent to the ribbon 80 are connected to the parallel connection ribbons 80, respectively.

Further, in designing a string connector composed of a plurality of wire string connectors 70, the cross-sectional area of the string connector, that is, the total cross-sectional area of the plurality of wire string connectors 70 is 1/2 of the cross-sectional area of the parallel connection ribbon 80. It can design by -1 times. This takes into account that the current flowing through the string connector is 1/2 of the current flowing through the parallel connection ribbon, thereby reducing the material cost of the string connector.

1: Split cell 1a: Interconnect
1b: parallel connection interconnect 50: first cell assembly
60: second cell assembly 70: wire string connector
80: parallel connection ribbon

Claims (9)

In constructing a solar cell module using a plurality of divided cells,
The plurality of divided cells are divided into a first cell aggregate and a second cell aggregate, and the first cell aggregate or the second cell aggregate includes a plurality of cell strings, and each cell string includes a plurality of divided cells connected in series. ,
Neighboring cell strings are connected in series via string connectors.
Opposite cell strings of the first cell assembly and the second cell assembly are connected in parallel via a parallel connection ribbon.
Cross-sectional area of the string connector is a solar cell module using a split cell, characterized in that 1/2 to 1 times the cross-sectional area of the parallel connection ribbon.
The solar cell module of claim 1, wherein the string connector comprises a plurality of wire string connectors having a wire shape.
3. The plurality of wire string connectors of claim 2, wherein the plurality of wire string connectors are arranged side by side in a direction orthogonal to the cell string, and the interconnectors extending from the split cells adjacent to the wire string connectors are electrically connected to the plurality of wire string connectors. Solar cell module using a split cell.
The solar cell module of claim 1, wherein at least one of the parallel connection ribbon and the string connector is designed to have a slanted surface.
The solar cell module of claim 4, wherein the inclined surface of the string connector faces the inner side of the solar cell module.
The method of claim 1, wherein the divided cells of the first cell aggregate and the divided cells of the second cell aggregate adjacent to the parallel connected ribbon are connected in parallel through a parallel interconnect interconnector.
The parallel connection ribbon and the parallel connection interconnector are provided in a cross shape and the solar cell module using a split cell, characterized in that electrically connected.
The method of claim 6, wherein the plurality of divided cells belonging to the first cell aggregate or the second cell aggregate are connected in series by an interconnector for electrically connecting neighboring divided cells.
The parallel connection interconnector is a solar cell module using a split cell, characterized in that to connect the divided cells of the first cell assembly and the second cell assembly facing each other adjacent to the parallel connection ribbon with the same polarity.
7. The method of claim 6, wherein the parallel interconnector extends from the front or the rear of the split cell of the first cell aggregate adjacent to the parallel ribbon and extends from the split cell of the second cell aggregate adjacent to the parallel ribbon. Solar cell module using a split cell, characterized in that extending to the front or back.
2. The divided cell according to claim 1, wherein the divided cells of the divided cells of the first cell aggregate and the divided cells of the second cell aggregate adjacent to the parallel connected ribbon are connected to the parallel connected ribbon, respectively. Solar cell module used.

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