WO2013020590A1

WO2013020590A1 - Rectangular solar cell and associated solar cell arrangement

Info

Publication number: WO2013020590A1
Application number: PCT/EP2011/063721
Authority: WO
Inventors: Ingram Eusch; Johann SUMMHAMMER
Original assignee: Kioto Photovoltaics Gmbh
Priority date: 2011-08-09
Filing date: 2011-08-09
Publication date: 2013-02-14

Abstract

This invention relates to the formatting of a solar cell and to the connection technique between solar cells.

Description

Rectangular solar cell and associated solar cell arrangement

description

Technical field of the invention

The invention relates to a rectangular solar cell and associated solar cell arrangement.

This includes the formatting of silicon solar cells and the series connection of such solar cells to solar cell modules to bring the electrical power with a minimum of losses to the outside.

Previous state of the art

Crystalline silicon solar cells are disc-shaped semiconductor bodies in which electrical DC voltage is generated by the incidence of light. In order to achieve a dense coverage of larger areas, the discs are usually square or rectangular. In some types of solar cells, the corners of the discs are rounded due to production. Usual sizes of the discs are 100 x 100 mm ² to about 200 x 200 mm ² . The thickness is usually between 150 and 350 μηι, In the vast majority of silicon solar cells produced today represents the light-facing side of the disc one polarity, and the side facing away from the light the other polarity. Mitteis metallic conductor, in ohmic Contact with these surfaces, electrical current is dissipated to the outside. The shape of these metallic conductors is on the side facing away from the light - the back - designed either as a full-surface coverage or as a dense mesh. As a result, the ohmic losses are kept low. On the side facing the light - the front - the metallic conductors are usually applied in the form of thin parallel lines, which on the one hand to ensure low shading of the active semiconductor body, and on the other hand also low ohmic losses in the current dissipation. These thin lines are called fingers. They collect the current from the semiconductor body and lead it to one or more thick lines. These thick lines are called buses. The buses collect all the electricity generated by the solar cell and direct it to an edge of the disc where it is tapped. For a given shape and number of buses, the arrangement and number of fingers are obtained according to known physical principles from an optimization calculation, the aim of which is to obtain the maximum electrical power from the solar cell for a given incident light output.

Since the voltage generated in a solar line is usually too low for direct applications, a suitable number of solar lines are connected in series. For this purpose, the solar cells are first connected to linear chains, so-called strings, and then several strings are placed side by side and also connected in series, but sometimes also in parallel to each other. Such a connection is called a module. To make a module resistant to weathering, there are several methods of encapsulation, e.g. Embedding the solar cells, which have already been assembled into modules, into clear plastic films and then optically sealing them onto a glass plate so that they protect the solar cells from the front.

To produce a string, metallic wires, which are frequently shaped as flat bands, are electrically conductively fixed to the buses of a solar cell and led to the back of an immediately adjacent second solar cell, where they are likewise fastened in an electrically conductive manner. As attachment methods are, for example Soldering, ultrasonic welding, gluing with electrically conductive adhesive, and mechanical pressing in use. The buses of the second solar cell are in turn electrically conductively connected to the back of a third solar cell adjacent to this solar cell, etc. The most common type of this series connection is shown in Figure 1. Where:

(1) Front of the solar cell facing the sun

(2) fingers of good conducting metal for collecting the current from the front of the solar cell

(3) Bus of good conducting and solderable metal to collect the current from the fingers

(4) Conductor strip of good conducting metal which is soldered, glued or pressed onto a bus (3) to carry the current to the back of the next solar cell

(5) Symmetry lines, which allow to divide a solar cell mentally into 4 identically functioning parallel electrical units

This series connection leads to a noticeable reduction in performance. This is now quantified for the type of silicon solar cell most commonly used today, namely the one with the size 156 mm x 156 mm, for a solar irradiation of 1000 W / m ² :

• Shading by the buses or on the buses soldered metal bands.

These bands are usually 2.5 mm wide. Based on the total width of the solar cell, this results in a relative loss of 3.2% by unused area for two belts.

• Distance between the individual solar cells of a string. This distance is at least 2 mm. For a string with 10 solar cells this results in a relative loss of at least 1.1% due to unused area.

• Electrical resistance losses in the metal strips on the front side of the solar cell. These metal strips are made of surface tinned copper, their cross section is often 2.5 x 0.15 mm ² . Larger cross sections would either more shading or greater height above the solar cell and, consequently, more complex processing technology in the production of Modules. The solar cell delivers about 3.8 watts of power at a current of 8 amps and a voltage of 0.475 volts. In the presence of two metal bands, each carries a current that increases linearly from 0 to 4 A over a length of 156 mm. This gives a relative power loss of 1, 8%.

• Electrical resistance losses in the metal bands on the back of the solar cell. These losses are similar to those of the metal strips at the front but reduced because the back of the solar cell is usually provided with a good conductive metal layer. In today's metal layer of about 15 μηη sintered aluminum, the resistance losses in the metal strips can be calculated with about 0.8%.

Overall, a relative power loss of the solar cell string of

6.9%.

Technical object of the invention

The object of the present invention, while maintaining the semiconductor material and the production technique of the solar cell itself, as far as possible to minimize this loss of power of a solar cell string, and thus better use the available, irradiated by the sun surface.

Description of the invention

The invention relates to a rectangular solar cell made of crystalline material having a front side facing the light in use and having a first polarity and a rear side facing away from the light when used with a second polarity, having the following features:

- On the front of the solar line runs along a first longitudinal edge of the

Solar cell at least one bus to collect and forward on the

Solar cell generated electricity,

on the back runs along a second longitudinal edge of the

Solar cell at least one bus to collect and forward on the

Solar cell generated electricity. According to one embodiment, at least one bus is designed as a linearly extending flat conductor. It can also be all buses designed.

This solar cell can be formed with a plurality of fingers arranged parallel to and spaced from one another on the front side, which extend perpendicular to the at least one bus on the front side of the solar cell and are electrically connected thereto.

The back of the solar cell is designed, for example, as a full-surface or network designed as a metallic conductor and electrically connected to the at least one bus on the back of the solar cell.

As can be seen from the introduction to the description, one feature of the invention is to form the solar cell rectangularly and with short electrical paths in order to optimize the efficiency. Accordingly, the length to width ratio of the solar cell should preferably be> 3, better:> 4 or> 6.

The energetically effective area of the solar cell is further optimized if the buses run without distance to the respective longitudinal edge of the solar cell, ie directly to the longitudinal edge of the solar cell connect (while the associated fingers perpendicular thereto or parallel to the broad sides of the solar cell in the respective bus open out).

The solar cell according to the invention may have a length £ 150mm, for example 56mm or> 200mm and a thickness 1 300pm, for example <300μηπ.

The described design of the solar cells allows the following arrangement to a string and corresponding further to a complete module:

The solar cells are arranged side by side along their respective longitudinal edges, and the respective at least one bus on the front side of a solar cell is electrically connected to the respective at least one bus on the rear side of the adjacent solar cell. In this case, the busses of the front and rear side of adjacent solar cells can lie on top of one another, that is, an overlapping area is created, so that a series of solar cells arranged next to one another (a string) runs in an imbricated manner to each other, as shown in FIG. According to the invention, this overlapping area is minimized and preferably limited to the width of the corresponding buses in order to keep the soiarnt unusable area as small as possible.

In this arrangement, the height (thickness) of the string at the overlap areas increases approximately to 2 times the thickness of the single solar cell. However, this does not interfere with the small thickness of each solar cell, especially as the solar cells are subsequently assembled (laminated) between glass and / or plastic layers. In that regard, reference is made to the disclosure of the contents of EP2237325 B1.

The busses of front and back of adjacent solar cells can be directly or indirectly electrically connected; directly, for example by direct soldering or indirectly, for example via at least one connector to which the buses are glued, soldered or otherwise connected.

An alternative arrangement provides for laying the buses of front and rear adjacent solar cells side by side and to connect electrically via a connector. This arrangement avoids thickened zones in the terminal area of adjacent solar cells. The connection between the connector (adapter) and the buses can be made as shown above.

The connector between adjacent buses of front and back adjacent solar cells may be stepped to compensate for the (very small) height difference between the front of a solar cell and the back of an adjacent solar cell.

An embodiment provides that the respective at least one bus on the front side of a solar cell with the respective at least one bus on the Rear side of the adjacent solar cell is soldered via at least one connector in the form of an electrically conductive strip.

To solve the technical problem, it is assumed that the losses in collecting and removing the electric current from the front side of a rectangular solar cell can in principle be kept smaller than those of a square solar cell of the same area. For example, For example, as shown in Fig. 1, a conventional square solar cell can be divided into four equal, smaller solar cells by division along the lines of symmetry (5). These new solar cells can now be connected in series along their long sides. Since the electrical path lengths shrink during the transport of electricity from one solar cell to the next to a fraction, the electrical losses decrease. In addition, the series connection can be shingled, so that the proportion of the total area of the string, which is shaded by buses, as well as the unused by intervals between the cells area fraction completely disappears.

FIG. 2 outlines the inventive principle of the series connection of the solar cells on the basis of a view of the front side of four solar cells. Where:

(6) Front side of the solar cell

(7) Metal fingers on the front of the solar cell to collect the current

(8) solderable metal bus for collecting the current from the fingers

(9) electrically conductive connector between two solar cells

(10) Solar cell A

(1 1) Solar Cell B

FIG. 3 outlines the inventive principle of this series connection on the basis of a view of the back side of four solar cells, viewed from below. Where:

(12) solderable metailbus for collecting the current from the back

(13) Metallization of the remaining back side of the solar cell for better electrical conductivity in the direction of Metalibus (12) It should now be determined the expected losses that occur in this type of series connection. For this purpose, it is assumed that rectangular solar cells of size 156 x 39 mm, since they can be easily produced by dividing the common format of 156 x 156 mm along the symmetry lines (5). In general, however, it will be necessary to adapt the metallization patterns of the front and the back in order to obtain four rectangular solar cells with identical metallization after division of the square disk. Above all, the position of the rear buses (12) with respect to the front buses (8) is to be optimized.

The losses in the fingers (7) of the solar cell according to the invention are the same as in the fingers (2) of the conventional square solar cells, since they have the same length and nature. Also, the losses due to the contact resistance between the bus (8) and the connector (9) can be set as the same as those between the bus (3) and the conductor strip (4) in the conventional square solar cells because of the same current density. This is ensured when the bus (8) has half the width of the bus (3). The unused area through the bus (8) can be completely eliminated if the connector (9) is located on the solar cell so that it does not cover more than the bus (8), and the solar cell above it also no more than the bus ( 8) covers. As a result, in a solar cell string, there are neither surface losses due to shading nor the distance between the solar cells (with the exception of the shading by the fingers (7), which is the same as in the conventional square solar cells). Therefore, only the losses due to the ohmic resistance in the connector (9) and its contact with the back of the respective overlying solar cell must be considered. The latter can be regarded as the same size as the losses on the back of a square solar cell (FIG. 1), ie around 0.8% of the electrical power generated. The ohmic losses in the connector (9) depend on its material and cross-section. For example, if it consists of a copper strip with a cross-section of 0.05 x 5.00 mm ² and a length of 154 mm (with an edge length of the solar cell of 156 mm), and it is further assumed that the current of 2 A is the maximum possible distance of 5 mm flow, this results in a relative loss of about 0.006% of the solar cell's electrical power at solar irradiation of 1000 W / m ² . The losses of a solar cell string given length are therefore only about 0.8% of the generated power, which is significantly less than a string of square solar cells, where the same losses made up 6.9%.

The connector (9) has the task of conducting the current from the front side of the solar cell A (10) to the back of the solar cell B (11) and thereby causing the lowest possible ohmic losses. There are several forms of the connector conceivable, as shown by way of example in Figure 4. Here are:

(9-1) Connector in one piece as a thin metallic band

(9-2) A connector composed of a plurality of unconnected portions of a metallic strip to reduce stress due to differential thermal expansion of the solar cell and the connector

(9-3) Connectors consisting of short pieces of wire to reduce thermal stress and keep the metal consumption of the electrical connection as low as possible

For the way in which the electrical and mechanical connection between solar cells and connectors is produced, various methods are also conceivable:

1 . A thin band (9-1), or several thin bands (9-2), of a good conducting metal, e.g. Copper, coated with solder. In the preparation of the compound, the two solar cells with the band, or the tapes between them pressed firmly together and heated so that the solder melts and after cooling a firm connection between the two solar cells by means of the band, or the tapes is formed.

2. Short pieces of wire (9-3) sheathed with suitable soldering tin. In the preparation of the compound, the two cells are firmly pressed together with the pieces of wire between them and heated, so that the solder melts and after cooling, a firm connection between the two solar cells by means of the wire pieces is formed.

3. A thin strip (9-1), or several thin strips (9-2), of a well-conductive metal, with roughened surfaces. When squeezing two adjacent solar cells with the connector in between penetrate protruding tips of the rough surface of the connector into the front side bus (8) of one solar cell and into the back side bus (12) of the other solar cell, or at least make good mechanical contact. This also good electrical contact is achieved. To maintain this connection for a long time, permanent pressure is necessary. This pressure is achieved automatically in the conventional production of photovoltaic modules, since the strings are embedded between a glass plate and a Rückseitenfoüe and sealed tightly under vacuum.

The invention comprises the following embodiments:

1, solar array consisting of a disc-shaped semiconductor with a rectangular outline, which generates an electrical voltage between the front and the back of the disc, which has a metallization of the front and back for electrical contacting, wherein the metallization on the front of a solderable bus (8), which is located very close to an edge and parallel to this, and the metallization on the back contains a solderable bus (12) which also runs close to and parallel to an edge, and the buses (8) and (12) are parallel to each other,

2, connection technology for solar cells as mentioned under 1, wherein a connector (9) is placed in the form of a solder-coated Metaflbandes on the bus (8) of a solar cell A (10), wherein the metal strip may consist of several sections, so the bus (8) is at least partially covered and a solar cell B (1 1) is placed on this connector so that it contacts the back side bus (12) of the solar cell surface and then solar cell A (10), connector (9) and solar cell B (1 1) firmly pressed together and briefly heated, so that a solid solder joint is formed,

3, connection technology for solar cells as under 1. called, are coated with solder coated straight wire pieces on the bus (8) of the solar cell A (10), that they are approximately at right angles to this, and thereon one

Solar cell B (1 1) is placed so that the wire pieces their back bus (12) well then contact solar cell A (10), wire pieces and solar cell B (1 1) firmly together and heat briefly, so that a firm solder joint is formed,

4. Connection technology for solar cells as mentioned under 1., wherein a connector (9) in the form of provided with both sides roughened surface metal band on the bus (8) of the solar cell A (10) is placed, wherein the metal strip may consist of several sections such that the bus (8) is at least partially covered and a solar cell B (1 1) is placed on this connector such that it contacts the rear side bus (12) of the solar cell B (1 1) and then solar cell A (10) , Connector (9) and solar cell B (1 1) are pressed firmly against each other, so that the protruding parts of the roughened surfaces of the connector (9) into both the bus (8) of the solar cell A (10) and in the back side bus (12 ) penetrate the solar cell B (1 1) or at least establish firm mechanical and electrical contact.

I i

Claims

claims

1. Rectangular solar cell made of kristaliinem material with a in the

Application of the light-facing front with a first polarity and a remote from the light in the application

Rear side with a second polarity, with the following features:

1.1 on the front of the solar cell runs along a first

Longitudinal edge of the solar cell at least one bus (8) for collecting and forwarding the electricity generated on the solar cell,

1.2 on the back extends along a second longitudinal edge of the solar cell at least one bus (12) for collecting and forwarding the electricity generated on the solar cell.

2. Solar cell according to claim 1 with several, parallel and spaced

Fingers (7) arranged on the front side extend perpendicular to the at least one bus (8) on the front side of the solar cell and are electrically connected thereto.

3. Solar cell according to claim 1, whose back is designed as a full-surface or network formed as a metallic conductor and to which at least one bus (12) is electrically connected.

4. Solar cell according to claim 1 with a length to width ratio of 3.

5. Solar cell according to claim 1 with a length to width ratio of 4.

6. Solar cell according to claim 1 with a length to width ratio ä 6.

7. Solar cell according to claim 1, wherein the buses (8,12) extend without a distance to the respective longitudinal edge of the solar cell.

8. Solar cell according to claim 1 with a length> 150mm and a thickness <300 m.

9. Arrangement of a plurality of solar cells (10, 1 1) according to one of claims 1 to 7, wherein the solar cells (0, 1 1) along their respective longitudinal edges next to each other victories and the at least one bus (8) on the front of a solar cell with the in each case at least one bus (2) is electrically connected on the rear side of the adjacent solar line.

10. Arrangement according to claim 7, wherein the buses (8,12) of front and back of adjacent solar cells lie on each other.

1 1. Arrangement according to claim 8, wherein the buses (8, 12) of the front and back of adjacent solar cells via at least one connector (9) are electrically connected.

12. Arrangement according to claim 7, wherein the buses (8.12) of front and back of adjacent solar cells are adjacent to each other and are electrically connected via a connector (9).

13. Arrangement according to claim 10, wherein the connector (9) between

adjacent buses (8, 12) of the front and back of adjacent solar cells is stepped.

14. Arrangement according to claim 7, wherein the respective at least one bus (8) on the front side of a solar line with the respective at least one bus (12) on the back of the adjacent solar line over

at least one connector (9) is soldered in the form of an electrically conductive strip.