DE102011001207A1 - Solar module for small electrical appliances - Google Patents

Abstract

A solar module for small electrical devices, comprising at least one solar cell (1) arranged on a carrier body (8) with positive and negative solar cell contacts each, which are electrically connected to one another via first and second contact tracks (6, 7) formed on the carrier body (8), comprises, has only on the rear side of the solar cell (1) formed, alternately parallel, linear plus contacts (2) and minus contacts as well as first and second rows of contact tracks arranged on the carrier body (8) for the respective solar cell (1), each consisting of im Distance between two plus or minus contacts arranged in parallel and aligned according to the plus and minus contacts of the solar cell first and second contact tracks (6, 7), the first contact tracks (6) electrically connected to the plus contacts (2) being opposite the second contact tracks ( 7) are arranged offset by the distance between two solar cell contacts. The solar module designed in this way is characterized by its low overall height, simple manufacture and secure contact.

Description

The invention relates to a solar module for small electrical appliances, which comprises at least one arranged on a support body solar cell with each positive and negative solar cell contacts, which are electrically connected to each other via formed on the support body contact tracks.

The solar cells of a solar module which are electrically connected to one another in series, parallel or series parallel connection on an insulating carrier body usually each have a back contact on the rear side and a front contact on the front side, which are formed as a metallized surface region. Rear contact and front contact conductor tracks arranged on the carrier body connect the respectively adjacent rear and front contacts of the individual solar cells with one another depending on the interconnection principle and lead them to a central connection terminal.

At one of the DE 35 20 423 known solar module, the electrical connection between the front contacts of the individual solar cells and the associated Frontkontaktleiterbahnen on the support body by means of conductive adhesive strips, which are formed at a distance and parallel to each other on a film strip extending over the plurality of solar cells. The film strip must be precisely pre-assembled and precisely mounted on the solar module to ensure the safe contacting of all solar cells and to avoid short-circuits. The production of solar modules is therefore associated with a considerable amount of time.

An Indian DE 102 61 876 A1 described solar module provides for the formation of a direct-applied conductive adhesive bridge between the front contact of the solar cell and the associated contact trace on the support body, wherein the conductive adhesive bridge rests on an applied between the front and the back contact of the solar cell insulation layer. In addition to the elaborate production and the space required by the trained Leitkleberbrücken solar modules is relatively large.

The invention has for its object to provide a solar module of the type mentioned above, which ensures a reliable contact between the solar cell contacts and the contact traces on the support body with low height and reduced manufacturing costs.

The basic idea of the invention is that solar cells having back side contacts only, that is to say, solar cells with line-shaped plus and minus contacts formed only on the rear side and running parallel, have first and second contact path rows arranged on a carrier body for the respective solar cell each consist of spaced apart from two plus or minus contacts arranged in parallel and aligned according to the positive and negative contacts of the solar cell aligned first and second contact tracks are electrically connected. In this case, the first contact paths which are electrically connected to the rear-side plus contacts of the solar cell are offset by the distance between two solar cell contacts with respect to the second contact paths connected to the rear negative contacts of the solar cell.

The solar module formed in this way can be manufactured in a simple manner, that is to say with a low expenditure of time, cost and apparatus and with reliable contacting between the solar cell contacts and the contact paths on the carrier body, without risk of short circuits. It is also characterized by an especially important in small electrical appliances low height.

According to a further feature of the invention, the positive and negative contacts of the solar cell with the contact paths of the carrier body are connected to each other via two spaced soldering points. Distortion of the solar module in the contacting is avoided, while a short-circuit contact is prevented by the solder pads due to the staggered arrangement of the contact paths on the carrier body despite the formed at a small distance solar cell contacts.

In an embodiment of the invention, the positive and negative contacts of the solar cell can be connected to the contact tracks on the carrier body by means of a conductive adhesive.

In a further embodiment of the invention, the two contact path rows are each connected via a conductor track which leads via a through-hole in the carrier body to at least one plus and one minus contact point on the free underside of the solar module.

In a further embodiment of the invention, a Abdecklackschicht is formed on the inner and outer surfaces of the carrier body for the isolation of the contact paths and the conductor tracks of the solar module.

According to yet another feature of the invention, an electronics is arranged on the free side of the carrier body to form the solar module directly as an electronic component for controlling and charging a battery.

According to the inventive method for producing a carrier body comprising at least one solar cell solar module for Small electrical appliances are on the support body at least two rows of contact tracks each arranged at a distance, but mutually offset contact paths generated and electrically connected by interconnects. On the inside and outside of the carrier body a Abdecklackschicht is applied for the isolation of the contact tracks and the conductor tracks. The contact tracks are wetted with solder pads or conductive adhesive. At least one solar cell aligned with the contact path rows is placed on the support body thus prepared with only linear formed plus and minus contacts formed on the rear side thereof, and then the solder material or the conductive adhesive is cured under the effect of heat. The production can be carried out with simple devices, that is without the use of complex special machines.

An embodiment of the invention will be explained in more detail with reference to the drawing. Show it:

1 a bottom view of a solar cell with only formed on the rear side strip-shaped contacts (rear side contacts);

2 a plan view of a carrier body of a solar module with two rows of contact tracks for current collection of a solar cell;

3 a sectional view of a solar cell and a carrier body according to 1 and 2 formed solar module; and

4 a detailed view of a carrier body with the current paths for current collection.

At the in 1 shown, in the usual way, a p-layer on the front and an n-layer on the back comprehensive solar cell 1 For example, the P-layer is contacted by the N-layer so that the positive and negative solar cell contacts (usually front and back contacts) are only exposed to the in-plane 1 visible back of the solar cell 1 are formed. The solar cell contacts form on the back of the solar cell a pattern of a small distance, here 0.2 mm, alternating juxtaposed strip-shaped positive contacts 2 and negative contacts 3 ,

To take the electricity from the solar cell 1 That means one of several positive contacts 2 and on the other hand each arranged between these negative contacts 3 are like 2 shows two at right angles to the strip-shaped plus and minus contacts 2 . 3 the solar cell 1 aligned - first and second - contact lane rows 4 . 5 each at a distance 2a between two positive contacts 2 or two minus contacts 3 the solar cell 1 parallel to each other - first and second - contact tracks 6 . 7 on a carrier body 8th educated. The contact tracks 6 the first contact track series 4 are to contact tracks 7 the second contact track series 5 offset, by the distance "a" between a positive contact 2 and a neighboring negative contact 3 ,

3 shows a sectional view of a better illustration with only a single solar cell 1 trained solar module 9 , In fact, a solar module 9 but a plurality of solar cells 1 on a carrier body 8th with a plurality of first and second contact track rows 4 . 5 include, their respective plus and minus contacts 2 . 3 several groups of contact tracks 4 . 5 contact and are interconnected in a suitable manner. As 3 shows are the respective positive contact 2 and the respective negative contact (not shown) of the solar cell 1 with the corresponding first contact track 6 or the second contact track 7 two soldering points consisting of a low-temperature solder (here: tin / bismuth solder paste) 10 connected with each other. Due to the formation of two contact lane rows 4 . 5 with mutually offset contact paths 6 . 7 is an exact connection of only a small distance of, for example, 0.2 mm at the back of the solar cell 1 arranged plus / minus contacts with the on the support body 8th located contact tracks 6 . 7 in a soldering without risk of short circuit possible. One each from the two contact path rows 4 and 5 outgoing, first on the top of the carrier body 8th running track 11 . 12 (Copper track) is via a via hole 13 . 14 on the underside of the carrier body 8th led and forms there (here: several) how 4 shows plus and minus contact points 15 . 16 to the current decrease. On the top and bottom of the carrier body 8th there is a resist layer 17 for mutual isolation of the contact tracks 6 . 7 as well as for the isolation of the conductor tracks 11 . 12 ,

The production of a above-described and reliably interconnected solar module with only formed on the back of the solar cell alternately +/- contacts, which also has a reduced height in comparison with the known solar modules, is associated with little effort. On the carrier body a plurality of rows of contact paths are mounted according to the number of solar cells and preferably wetted with a cost solder paste or a conductive adhesive, due to the offset in two rows of contact lines contact tracks without risk of short circuit. After placing the appropriate number of solar cells on the thus prepared carrier body curing of the conductive adhesive or solder takes place by heat input. The production can - compared to the known methods for the production of solar modules with front and back contacts - largely automated without the use of special machines and therefore be carried out with reduced time and cost.

LIST OF REFERENCE NUMBERS

1

solar cell

2

Positive contacts (solar cell / backside contacts)

3

Negative contacts (solar cell / back side contacts)

4

first contact track row (+) of 8th

5

second contact track row (-) of 8th

6

first contact tracks (+)

7

second contact tracks (-)

8th

support body

9

solar module

10

plumb

11

Conductor on top of 8th

12

Trace on underside of 8th

13

Through hole in 8th

14

Through hole in 8th

15, 16

Plus / minus contact points

17

resist layer

a

distance between 2 and 3

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 3520423 [0003]
• DE 10261876 A1 [0004]

Claims (7)

Solar module for small electrical appliances, the at least one on a support body ( 8th ) arranged solar cell ( 1 ) each having positive and negative solar cell contacts, which on on the carrier body ( 8th ) formed first and second contact tracks ( 6 . 7 ) are electrically interconnected, characterized by only at the back of the solar cells ( 1 ) trained, alternately parallel, line-shaped plus and minus contacts ( 2 . 3 ) as well as on the carrier body ( 8th ) for the respective solar cell ( 1 ) arranged first and second contact track rows ( 4 . 5 ), each consisting of at the distance 2a of two plus or minus contacts ( 2 . 3 ) arranged in parallel and according to the plus and minus contacts ( 2 . 3 ) of the solar cell ( 1 ) aligned first and second contact tracks ( 6 . 7 ), whereas those with the plus contacts ( 2 ) electrically connected first contact tracks ( 6 ) with respect to the second contact tracks ( 7 ) are offset by the distance a between two solar cell contacts. Solar module according to claim 1, characterized in that the positive and negative contacts ( 2 . 3 ) with the contact tracks ( 6 . 7 ) each have two spaced soldering points ( 10 ) are interconnected. Solar module according to claim 1, characterized in that the positive and negative contacts ( 2 . 3 ) of the solar cell ( 1 ) with the contact tracks on the carrier body ( 8th ) are connected by means of a conductive adhesive. Solar module according to one of claims 1 to 3, characterized in that the two contact track rows ( 4 . 5 ) each via a conductor track ( 11 . 12 ) are connected via a through-hole ( 13 . 14 ) in the carrier body ( 8th ) to at least one plus and one minus contact point ( 15 . 16 ) leads to the bottom of the solar module. Solar module according to one of claims 1 to 4, characterized by a on the inner and outer surface of the carrier body ( 8th ) formed resist layer ( 17 ) for the isolation of the contact tracks ( 6 . 7 ) and the tracks ( 15 . 16 ) of the solar module ( 9 ). Solar module according to one of claims 1 to 5, characterized in that it with a on the free side of the carrier body ( 5 ) trained electronics as an electronic component for controlling and charging a battery functions. A method for producing a solar module comprising a support body with at least one solar cell for small electrical appliances, characterized in that on the support body at least two rows of contact paths each arranged at a distance, but mutually offset contact paths are generated and interconnected by interconnects and on the inside and outside the support body is applied a Abdecklackschicht for insulating the contact tracks and the conductor tracks, wherein the contact tracks are wetted with solder pads or conductive adhesive and then on the prepared support body at least one aligned to the Kontaktbahnreihen solar cell with only formed on the back, alternately parallel extending linear plus - And negative contacts placed and the soldering material or the conductive adhesive is then cured under heat.

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