DE102007041057A1 - Process for producing a solar cell - Google Patents

Abstract

In a method for producing a solar cell (10, 11), in which the solar cell (10, 11) is screen-printed in a plurality of production steps, the solar cell (10, 11) is in a first orientation to the printing direction (10, 11) for a first printing operation ( 18) of a doctor blade and arranged in a second printing operation in a different orientation to the printing direction. As a result, the solar cell (10, 11) for the printing of elongated structures is always optimally aligned.

Description

The Invention relates to a method for producing a solar cell, in which the solar cell in several manufacturing steps by screen printing is printed.

It is known, both the back as well as the front of solar cells during their production in Screen printing process to print. This show in the prior art the solar cell to be printed and the printing direction a fixed predetermined, not changeable relative orientation to each other.

In Today, two types of printing units are commonly used in screen printing technology: Flat screen printing units and rotary screen printing units. As printing direction The direction of movement is generally referred to in flat screen printing units the squeegee over the print material. For rotary screen units, the printing direction is defined by the transport direction of the printed material.

One important criterion in screen printing is the detachment of the screen from the print material, after the squeegee over drove the sieve: the so-called Siebabsprung.

The following execution explained on the basis of a flat screen printing unit the relationships, which in principle also apply to rotary screen printing units.

There the printing pastes highly viscous liquids are strong adhesion forces that act the sieve after the squeegee over has driven a point to be printed on the printed material (solar cell) first hold tight. The detachment is made possible by the relatively strong tension of the sieve. The Siebabsprung needed but a certain amount of time, different pressure parameters dependent is (paste, sieve texture, printed image). The time required for the Siebabsprung is an important size because the print material as long as it is not allowed to move until it is done safely. That is another reason why it is common today Sieve before the further transport of the print product upwards (from the printed material away), which promotes the Siebabsprung. The sieve jump designed always difficult if a printed image across the width of the object without interruption, such as the full-surface Back print or the busbars, called busbars, or the fingers at Solar cells. Individual interruptions of the printing structure, such. B. the many individual fingers when printing the solar cell front, simplify the Siebabsprung when printed in Rakelbewegungsrichtung become.

The Printing the busbars and the fingers for the front-side contact, so the printing of the solar cell front, technically represents the biggest challenge The positioning of the solar cells for the alignment of the printing screen or the Rakelbewegungsrichtung therefore for this process step after possibility optimally chosen. This means that the fingers of the solar cell front in the direction of movement the squeegee will be printed. The busbars on the solar cell back However, they are aligned transversely to the fingers of the solar cell front. If the solar cell is thus aligned so that an optimal printing the solar cell front side possible This also means that because of the rigid arrangement of the squeegee movement for the solar cell the printing of the solar cell backside under bad conditions takes place because the full width of the solar module without interruption must be printed transversely to Rakelbewegungsrichtung. The sieve jump here is the hardest and needs to have appropriate process settings be ensured.

A possible solution is to implement a wait. This, however, extends the printing cycle. Alternatively or additionally, the screen after printing be driven up. This also prolongs the printing cycle. Farther it is conceivable to increase the screen tension. This shortens, however the life of the sieve.

task It is therefore an object of the present invention to provide a method which shortens the printing cycle and the life of the sieve can be increased.

According to the invention this object is achieved in a particularly simple and surprising manner by a method of the type mentioned, in which the solar cell and the printing direction are aligned for at least a first printing operation in a first orientation to each other and in at least one further printing operation in a different orientation aligned with each other. The solar cell is thus arranged for at least one first printing operation in a first orientation to the doctor movement direction of a doctoring or transport direction of the solar cell and in at least one further printing operation in a different orientation to the doctor movement direction of a doctor blade or the transport direction of the solar cell. By this measure, it is ensured that the solar cell is optimally aligned for each printing process to Rakelbewegungsrichtung or transport direction, in particular for printing elongated structures, so that the disadvantages described above at Siebabsprung can be largely avoided. This means that the printing screens are exposed to a lower load and thus a longer service life of the printing screens is reached. In addition, the printing cycle is shortened considerably. The productivity of the plant on which the process is carried out is increasing. In addition, the quality of the individual printing processes increases. The advantages of this new method apply to flat screen printing units in the same way as for rotary screen printing units.

at a particularly preferred variant of the method can be provided that the solar cell to be printed before at least one printing operation turned by 90 degrees becomes. This will make the solar cell compared to the previous one Printing in a different orientation to Rakelbewegungsrichtung or transport direction brought. Thus, elongated structures can be perpendicular to previously printed structures are arranged in the same Squeegee movement direction or transport direction are applied like the elongated ones applied in the previous printing process Structures. in principle would it be also conceivable, instead of rotating the solar cell by 90 °, the direction of movement the squeegee to 90 ° change or a second squeegee with offset by 90 ° movement direction to use. In any case, the solar cell according to the invention for two different printing operations different orientations with respect to a blade movement direction or transport direction.

A further optimization regarding Siebabsprungs arises when at least in each printing some oblong Structures in the printing direction, ie the direction of movement of a Doctor blade or transport direction of the solar cell to be printed.

at a variant of the method can be provided that in a first Printing busbars, in particular with a printing paste, z. B. silver paste, are printed on the back of the solar cell, wherein the printing direction in the direction of extension of the aufzudruckenden Busbars runs. This process variant represents the exact opposite of the known Prior art, where the busbars on the solar cell back are oriented transversely to Rakelbewegungsrichtung, making the top mentioned disadvantages arise when Siebabsprung. For a flat screen printing unit This means that the squeegee when printing in the direction of extension the busbars to be printed is moved.

Farther can be provided that in a second printing process, the solar cell rear side in particular with a printing paste, z. B. aluminum paste, is printed, wherein the printing direction in the direction of extension of previously printed busbars runs. In a flat screen printing unit, this means that the squeegee in Direction of extension of previously printed busbars is moved. This means that the first and second printing are the same permanent orientation of the solar cell with respect to the Rakelbewegungsrichtung or transport direction of the cell, which corresponds to the printing direction, carried out become.

advantageously, become in a third printing busbars and fingers in particular with a printing paste, z. B. silver paste, on the solar cell front imprinted, wherein the printing direction in the direction of extension the finger to be printed passes. In a flat screen printing unit, this means that the squeegee when Printing is moved in the direction of the extension of the fingers aufjudruckenden. This will ensure that the very thin fingers with an optimal Accuracy be printed and run without interruption. It is also conceivable, first the solar cell front and then the solar cell back to print. In this case would have to the solar cells after printing the solar cell front side with respect to Squeegee movement direction be reoriented. The expressions "first, second and third printing "can Therefore, it must relate to a chronological sequence of printing operations but not.

Special Benefits arise when before at least one printing the Solar cell is detected with a gripper and with respect to the Printing direction is aligned. Here, in particular, a Bernoulli gripper be used. Preferably, the solar cell is before the third Printing, in which the solar cell front side is printed by the gripper turned 90 °.

The productivity An installation in which the procedure is carried out may be increased if in at least one printing multiple solar cells simultaneously be printed. Preferably, multiple print jobs are used Solar cells printed simultaneously. This means that before at least a printing process several solar cells, in particular by a Bernoulli grippers, be reoriented.

In falls within the scope of the invention also one Screen printing machine with a gripper, in particular a Bernoulli gripper to carry out of the procedure. The screen printing machine can be a flat screen printing unit, in which the printing direction corresponds to the direction of blade movement, or a rotary screen printing unit, wherein the printing direction of the transport direction of the printed material (solar cell) corresponds.

Further features and advantages of the invention will become apparent from the following detailed description of embodiments of the invention with reference to the figures of the drawing, the invention Essential details shows, as well as from the claims. The features shown there are not necessarily to scale and presented in such a way that the features of the invention can be made clearly visible. The various features may be implemented individually for themselves or for a plurality of combinations in variants of the invention.

In the schematic drawing are embodiments of the invention shown and explained in more detail in the following description.

It demonstrate:

1 a plan view of the back of two solar cells after a first printing operation;

2 a plan view of the back of two solar cells after a second printing operation; and

3 a plan view of the front of the solar cells after a third printing operation.

In the 1 are two solar cells 10 . 11 shown, with their back 12 . 13 is visible. The solar cells 10 . 11 show on their back 12 . 13 in each case by screen printing simultaneously printed in a first printing so-called busbars 14 to 17 on. The printing direction, ie the blade movement direction in flat screen printing units or the transport direction in rotary screen printing units, is indicated by the arrow 18 indicated. This means that the busbars 14 to 17 in the printing direction 18 were printed. This facilitates the sieve jump. The busbars 14 to 17 were created by printing a silver paste.

The 2 shows the solar cells 10 . 11 , on the other hand, at the same time an aluminum paste 19 . 20 was printed. The printing direction is again by an arrow 21 indicated. This means that the printing direction 18 . 21 and orientation of the solar cells 10 . 11 was the same for both printing processes.

In the 3 is a top view on the front 25 . 26 the solar cells 10 . 11 shown. The solar cells 10 . 11 are opposite to the representations of 1 and 2 turned by 90 degrees. This allowed fingers 27 . 28 in printing direction 29 be applied in a third printing process, wherein the printed as a silver paste finger 27 . 28 opposite the bus bars 14 to 17 the solar cell back are offset by 90 °. The busbars 30 . 31 the fronts 25 . 26 were transverse to the printing direction 29 also printed in the third printing process. The printing directions 18 . 21 . 29 are therefore the same for all printing processes. The orientation of the solar cells 10 . 11 with respect to the printing direction 29 however, was for printing on the solar cell front 25 . 26 changed.

Claims (11)

Method for producing a solar cell ( 10 . 11 ), in which the solar cell ( 10 . 11 ) is screen printed in several production steps, characterized in that the solar cell ( 10 . 11 ) and the printing direction ( 18 . 21 . 29 ) are aligned for at least one first printing operation in a first orientation to each other and are aligned in at least one further printing operation in a different orientation to each other. A method according to claim 1, characterized in that the solar cell to be printed ( 10 . 11 ) is rotated by 90 ° before at least one printing operation. A method according to claim 1 or 2, characterized in that in each printing at least some elongated structures in the printing direction ( 18 . 21 . 29 ) to be printed. Method according to one of the preceding claims, characterized in that in a first printing process busbars (busbars (busbars) 14 to 17 )) on the back of the solar cell ( 12 . 13 ) are printed, wherein the printing direction in the direction of the extension of the busbars to be printed ( 14 to 17 ) runs. Method according to one of the preceding claims, characterized in that in a second printing process, the solar cell rear side ( 12 . 13 ) is printed, wherein the printing direction in the direction of extension of previously printed busbars ( 14 to 17 ) runs. Method according to one of the preceding claims, characterized in that in a third printing process busbars and fingers ( 27 . 28 ) on the solar cell front ( 25 . 26 ), the printing direction being in the direction of the extension of the fingers to be printed ( 27 . 28 ) runs. Method according to one of the preceding claims, characterized in that before at least one printing operation, the solar cell ( 10 . 11 ) is detected with a gripper and with respect to the printing direction ( 18 . 21 . 29 ) is aligned. Method according to one of the preceding claims, characterized in that in at least one printing process a plurality of solar cells ( 10 . 11 ) are printed simultaneously. Screen printing machine with a gripper to carry out the Method according to one of the preceding claims. Plant according to claim 9, characterized in that that the printing unit is a flat screen printing unit, wherein the Pressure direction of the blade movement direction corresponds. Plant according to claim 9, characterized in that that the printing unit is a rotary screen printing unit, wherein the printing direction corresponds to the transport direction of the solar cell.