NL8900660A - INTERCONNECTION OF SOLAR CELLS WITH ELECTRICALLY CONDUCTIVE CONNECTION MEDIUM. - Google Patents

Abstract

The method is for connecting solar-cells in series. A connecting strip is provided over the full width of the front of the first solar cell and this has a previously defined quantity of electrically conductive joining material i.e. glue. This first solar cell is positioned in a first position in a first position with the front pointing upwards. The glued connection strip lays against the support part extending above the surface of the container and so that the strip is to the right. A connecting strip is provided with a connecting strip and is positioned in the container at a second position so that its back part rests on the connecting strip of the first and cells can be joined in this way forming a roof-tile pile. A heater is conveyed through the container to harden the glue. @(10pp DWg.No.30/3)@.

Description

INTERCONNECTION OF SOLAR CELLS WITH ELECTRICALLY CONDUCTIVE CONNECTION MEDIUM

The invention relates to a method of connecting solar cells in series.

The operation of solar cells is based on the well-known photovoltaic principle, whereby light (such as sunlight) falling on a thin disc or slice of semiconductor material (such as silicon) generates an electric voltage.

In this way, light energy can be directly converted into electrical energy without the need for moving parts.

Such thin slices or slices of silicon with dimensions of, for example, 10x10x10.03 cm are processed into solar cells by chemical and mechanical treatment. A number of such solar cells can be interconnected and encapsulated into a solar panel.

For example, the cells are behind a plate of chemically hardened glass, while the back of the solar panel consists of, for example, a durable (silicone) plastic. For example, the whole can be mounted in a frame. At the back there is at least one connection cable or connection box for the cabling.

Solar panels can be further combined into an almost infinite number of configurations complete with a support structure, electrical connections, batteries and junction boxes to form a user-adapted system.

Solar cells are usually interconnected via one or more connecting strips, each of which is individually applied to the solar cells with several solderings.

This is a labor-intensive issue for large numbers of solar cells. The delicate mechanical properties and coarseness of the soldering process often also result in a relatively high failure rate.

Disadvantages of the existing method are therefore: 1) labor intensive; 2) many actions; 3) relatively large mechanical load, resulting in a relatively high failure rate.

The invention overcomes these drawbacks and now provides a method in which 1) the solar cells are provided with a special metallization pattern; 2) a small amount of electrically conductive connecting medium is applied per solar cell; 3) the matrix of solar cells is then placed one on top of the other in a tile; 4) the resulting structure is cured before or during the encapsulation of the solar cells.

According to the invention, the activities can be mechanized easily and with relatively low investments, while the throughput speed of this process is high. Furthermore, the solar cells no longer come into contact with relatively large mechanical forces, as a result of which the failure can be considerably reduced.

To this end, the method according to the invention is characterized in that a) a connecting member is provided on the front side of a first solar cell over its full width and this is provided with a predetermined amount of electrically conductive connecting medium; b) positions this first solar cell face up in a designated holder in a first position such that the connecting medium provided with connection medium is against support members projecting above the surface thereof and the connection means is on the right; c) repeat step a) for a second solar cell; d) step b) repeats for the second solar cell at a second position of the holder, such that the back of the second cell rests on the connecting medium of the first cell provided with connecting medium, whereby a pile-like stack is created; e) steps a) and bj repeat for a third, fourth and subsequent solar cell until the container is full; then f) heat-treating the bonding medium; and g) removes the container.

In this way the number of actions decreases; large mechanical loads are no longer applied to the solar cells; and no more interconnection material (tinned copper strips) is used.

The invention will now be explained in more detail below with reference to the drawings and the description.

Fig. 1 is a front view of a solar cell, whereby an electrical series connection of 2 or more solar cells is effected by a conventional method;

Fig. 2 is a front view of a solar cell, whereby an electrical series connection of 2 or more solar cells is effected by an advantageous method according to the invention; and

Fig. 3A and 3B show a top view and a side view, respectively, of a special container used in the method according to the invention.

With reference to FIG. 1, the electrically negative front side of a solar cell is partially covered with metal such that a metal pattern is formed (usually 37% lead, 63% tin) shown in FIG. 1 is shown as a white line pattern.

The (electrically positive) back of the solar cell (not shown) is completely covered with the metal.

According to a conventional method, an electrical series connection of 2 or more solar cells (interconnection) is effected by soldering two metal strips (tin-plated copper), on the one hand to the soldering spots S on the front of the first cell and on the other hand to solder the same strips to the back of the next cell.

By repeating this process, chains of solar cells are made that realize a greater electrical voltage. In this process, the following processing steps are distinguished: 1) Position solar cell No. 1 with the front facing up.

2) Apply solder flux to the 4 soldering spots.

3) Cut 2 tinned copper strips to size.

4) Solder the two strips to the front of cell 1 (on the soldering spots).

5) Position the thus treated solar cell No. 1 with the back facing up.

6) Repeat steps 1 to 4 with solar cell No. 2.

7) Apply solder flux to the back of cell # 1.

8) Position solar cell No. 2 behind solar cell No. 1 so that a) cell No. 2 faces back and b) the strips soldered on cell No. 2 are on the back of cell No. 1.

9) Solder the strips of cell No. 2 to the back of cell No. 1 (4 places).

10) Repeat for all subsequent cells (3 on 2, 4 on 3, etc.).

Fig. 2 now shows the front side of a solar cell with a modified metal pattern, shown as a white line pattern.

Instead of solder points S, the metal pattern is now provided with a connection strip D over the full width of the solar cell.

The connecting strip D now becomes the connecting member in series connection of solar cells.

Fig. 3A and 3B show a special container used in the method according to the invention. A number of positions A, B, C, D, E are indicated on the holder, as well as dots a which protrude above the surface of the holder and serve as support members for the solar cells. Figures 3A and 3B show the dimensions of a favorable embodiment of the container in millimeters. The width of the container can be, for example, 52 mm.

The following steps are distinguished according to a first advantageous embodiment of the method according to the invention: a) provide the front side of solar cell no. 1 (on the connecting strip) with, for example, 3 drops of electrically conductive glue; b) position solar cell no. 1 with the front side facing upwards in the special holder (see Fig. 3) at position A, such that a) the adhesive-bonded connection strip lies against the points a and b) the connection strip is on the right; c) repeat step a) for solar cell No. 2; d) repeat step b) for solar cell No. 2 (at position B) such that the back of cell No. 2 rests on the adhesive interconnecting strip of cell No. 1 ("tile stacking"); e) repeat steps a) and b) for solar cell No. 3, No. 4 etc. until the special container is full; f) transport the special container through a heating device (not shown) to cure the glue; and g) remove the container.

Any suitable electrically conductive adhesive, for example silver-filled 2-component adhesive, can be used.

According to another advantageous method of the invention, the connecting medium may also consist of an amount of solder paste which is applied in step a) evenly distributed over the length of the connecting strip.

In that case, in step f), the full container is transported by a heating source (for example, an infrared source) with sufficient thermal power to flow the solder paste so as to make a metallic connection between the interconnection strip of a solar cell and the back of the subsequent solar cell .

Claims (11)

Method for connecting solar cells in series, characterized in that a) a connector is arranged over the full width thereof on the front of a first solar cell and this is provided with a predetermined amount of electrically conductive connecting medium; b) positions this first solar cell face up in a designated holder in a first position such that the connecting medium provided with connection medium is against support members projecting above the surface thereof and the connection means is on the right; c) repeat step a) for a second solar cell; d) step b) repeats for the second solar cell at a second position of the holder, such that the back of the second cell rests on the connecting medium of the first cell provided with connecting medium, whereby a pile-like stack is created; e) steps a) and b) repeat for a third, fourth and subsequent solar cell until the container is full; then f) heat-treating the bonding medium; and g) removes the container. Method according to claim 1, characterized in that the connecting member is a connecting strip. Method according to claim 1 or 2, characterized in that the electrically conductive connecting medium is adhesive. Method according to claim 3, characterized in that the predetermined number of drops of glue is three. Method according to claim 3 or 4, characterized in that the glue is cured by transporting the container through a heating device. 6. Method according to any one of claims 3-5, characterized in that the glue is silver-filled 2-component glue, A method according to claim 1 or 2, characterized in that the electrically conductive connecting medium is solder paste. A method according to claim 7, characterized in that the amount of solder paste is evenly distributed over the length of the connector. Method according to claim 7 or 8, characterized in that the container is transported through a heating source with sufficient thermal power to allow the solder paste to flow. Method according to claim 9, characterized in that the heating source is an infrared heating source. 11. Solar cells connected in series using the method according to claims 1-10,