ITUD20110090A1 - PHOTOVOLTAIC CELL PROVIDED WITH AN IDENTIFICATION CODE AND PROCEDURE TO REALIZE IT - Google Patents

Description

Description

"PHOTOVOLTAIC CELL PROVIDED WITH AN IDENTIFICATION CODE AND PROCEDURE FOR REALIZING IT"

FIELD OF APPLICATION

The present invention finds application in photovoltaic cells which can be, for example, both of the EWT (Emitter Wrap Trought) type and of the MWT (Metal Wrap Trought) type, on which an identification code is advantageously formed which allows both to identify them individually, and to carry out their traceability during the processing phases, or downstream of the same.

STATE OF THE TECHNIQUE

It is known the use of photovoltaic cells each equipped with an information code for identification and tracing within a production system. This code is able to provide data concerning the technical characteristics of the cells themselves, their progress in the production process, or the input data for a positioning or storage system for the cells themselves. Moreover, through this code, each single cell can be traced so that its history can be reconstructed over time.

It is known to create codes for the identification of photovoltaic cells, both MWT and EWT type, which have an external surface, to be exposed to the sun, which for functional reasons is provided with a plurality of very small holes, in diameter between about 50 Î1⁄4Ï € ιand 100 Î1⁄4Ï € ι. In the cells of the EWT type these holes are very dense, with a surface density of approximately 1 hole every mm <2> or every 2 mm <2>.

Various identification codes are known, such as the QR ID code (Quick Response Identifying code), the two-dimensional barcodes and the alpha-numeric OCR (Optical Character Recognition) code, which are imprinted on the external surface of each cell by means of the using a laser.

A drawback of the known art is that the identification code must be positioned in a free area of the external surface of the cell between the aforementioned holes; an operation that is difficult, given that this area is formed by a plurality of small surfaces, substantially square in shape, each with an area varying from about 1 mm to about 4 mm.

Another drawback of the known art is that the use of a laser writing apparatus for the realization of the identification codes is complex and expensive, both due to the high costs of the apparatus itself and its maintenance, and because it requires the '' use of highly specialized personnel.

Proof of the complexities of using a laser system are the numerous parameters that must be optimized in order to make the marking clearly visible. The main parameters are: the frequency of the laser pulse, the speed of the scanner, the distance between adjacent incisions.

Furthermore, some production processes of the cell, such as the so-called etching-texturization, the deposition of the anti-reflective coating (cell blue color), the steps of the process in high temperature ovens, can change the color and properties of the wafer surface, making it difficult to identification and reading of the code itself.

An object of the present invention is to obtain a photovoltaic cell of the EWT, or MWT type, provided with an identification code placed on an external surface that is simple and economical to produce, and in which the code itself is permanent and without possibility of error.

Another object of the present invention is to obtain a photovoltaic cell of the EWT, or MWT type, provided with an identification code placed on an external surface, which is compatible with the perforation (throughput) of the screen printing lines, which process, for example , about 1,400 wafers / hour.

In order to obviate the drawbacks of the known art and to obtain these and further objects and advantages, the Applicant has studied, tested and implemented the present invention.

EXPOSURE OF THE FOUND

The present invention is expressed and characterized in the independent claims. The dependent claims disclose other characteristics of the present invention or variants of the main solution idea.

In accordance with the aforementioned purposes, a photovoltaic cell, according to the present invention, comprises an external surface having a certain total extension suitable for being exposed to light, and a plurality of holes arranged transversely to this surface and functional to the production of electrical energy in association with at least one emitting layer arranged in correspondence with said external surface. According to a characteristic aspect of the present invention, identification means are provided on a portion of the total extension of the external surface to define an identification code using a determined pattern, which involves the presence or absence of a part of said holes.

The aforementioned portion of the total extension of the external surface is not necessarily defined by a certain continuous area, or zone, but can also be obtained from the sum of the individual areas defined by the holes involved in the definition of the aforementioned pattern.

The pattern that defines the identification means is for example drawn, using a laser programmed to selectively not pierce the cell in certain positions, where normally there should be holes belonging to the aforementioned plurality. Not making certain holes is particularly advantageous in EWT type cells, where the totality of holes present is of the order of several thousand, for example 20,000, for each cell.

According to a variant, instead of not making certain holes, it is possible to fill holes that have already been made. This variant is advantageous both for EWT type cells and for MWT type cells, where the number of holes per cell is of the order of a few tens.

The absence of certain holes, or the filling of certain holes, can draw different codes which can be of alpha-numeric type, bar, OCR, QR ID, or other type, as long as the area is not perforated, or having holes filled, does not exceed a defined percentage, for example about 3%, of the total external surface of the photovoltaic cell. In other words, the number of holes not drilled, or holes filled, must not exceed a defined percentage, for example about 3%, of the total number of holes.

The aforesaid identification means thus realized can be read by the human eye and / or electronically identified, for example using known identification means, including detection means such as CCD cameras.

According to another aspect of the present invention, said pattern is therefore defined by the absence, or filling, of a part of said holes, which are arranged according to a matrix of rows and columns.

According to a variant of the present invention, the identification means comprise a filling material which selectively fills at least a part of the aforementioned holes.

The filling of the holes is particularly advantageous in MWT-type cells where the filling of the holes is part of the process of making the cell itself.

To fill the holes in a different way, a dedicated device can be used, which can be, for example, a syringe dispenser, which, moving over the cell, closes the holes by drawing a predefined pattern.

According to another aspect of the present invention, the filling material has a color which stands out visually with respect to the color of the external surface of the photovoltaic cell.

The resulting drawing on the external surface of the photovoltaic cell from the set of holes not made, or filled with the filling material, shows a sequence of characters, for example, but not limited to, alphanumeric, which form the identification code of the photovoltaic cell.

According to a further characteristic aspect of the present invention, the area involved in the recognition of the cell comprises a matrix with a certain number of rows, for example from about 5 to about 15, and a certain number of columns, for example from about 40 to about 120 .

The identification code is advantageously positioned in a precise portion of the aforementioned external surface of the cell, so as to make it automatic identification by the electronic systems and simple by any person.

According to another characteristic aspect of the present invention, a method for producing an identification code on a photovoltaic cell comprises a first step in which at least a part of the holes present on the sun-exposed surface of the photovoltaic cell is selectively not present, or filled with material filling, readable by an electronic system and / or by the human eye.

Furthermore, the possibility of drawing specific patterns in accordance with the present invention also allows information to be obtained, not only on the location of the cell on the production line (for example in a known type of screen printing line), but also on its position. in space: in fact, each detection unit placed on the aforementioned line (for example a CCD camera) can read the position and / or orientation of the pattern and consequently also that of the cell.

In other words, in addition to the possibility of tracing the life of a cell by identifying it with a specific pattern, the pattern itself can also be used to collect other information including that of the positioning and / or orientation of the cell itself in order to take any corrective actions in case of need. Such corrective actions can be, for example, the centering of the cell itself with a special centering device located downstream of the detection unit (camera).

ILLUSTRATION OF DRAWINGS

These and other characteristics of the present invention will become clear from the following description of a preferential embodiment, given by way of non-limiting example, with reference to the attached drawings in which:

- fig. 1 is a perspective view of a portion of a photovoltaic cell according to the present invention;

- fig. 2 is a cross section of a photovoltaic cell of the EWT type according to the present invention;

- fig. 3 is a cross section of a photovoltaic cell of the MWT type according to the present invention;

- fig. 4 is a top view of a portion of a photovoltaic cell of the EWT type according to the present invention, with an example of an identification code highlighted.

For ease of understanding, identical reference numbers have been used wherever possible to identify identical common elements in the figures. It should be understood that elements and features of one embodiment can be conveniently incorporated into other embodiments without further specification.

DESCRIPTION OF SOME PREFERENTIAL MANUFACTURING FORMS

With reference to Figures 1 or 2, a photovoltaic cell 10 of the EWT type, according to the present invention, comprises a protective layer 11, having an external surface F to be exposed to light, an n-type emitting layer 12, a base substrate 13 of p type, a plurality of first electrical contacts 14 associated with the emitting layer 12, a plurality of second electrical contacts 15 associated with the base substrate 13 and a p-n junction 16.

The photovoltaic cell 10 further comprises a plurality of through holes 17, arranged according to a matrix of rows and columns, which extend transversely from the surface F of the protective layer 11 to a lower surface B opposite the surface F. The density of the holes 17 is ̈ very high, for example between a hole per mm <2> and a hole every 2 mm <2>, therefore in a cell of 200 cm <2> there can also be 20,000 holes 17. Furthermore, each hole 17 has a diameter included between 50 Î1⁄4ιΠ· and 80 Î1⁄4ιΠ·.

When sunlight hits the junction 16 p-n, between the layer 12 and the substrate 13, a current is generated which flows through the electrical circuit consisting of the electrical contacts 15, the substrate 13, the layer 12 and the electrical contacts 14.

In this case, the photovoltaic cell 10 is of the EWT type in which the emitting substrate 12 is also arranged in contact with the internal surface of each hole 17 and reaches the lower surface B to define a hole 18 coaxial to the hole 17.

According to a variant, illustrated in Figure 3, another photovoltaic cell 100, according to the present invention, is of the MWT type in which, unlike the photovoltaic cell 10, the emitting layer 12 is arranged only on the upper surface of the base substrate 13, but not inside the holes 17. In such MWT cells, each hole 17 is internally coated with a metal layer 21 which puts the emitting layer 12 in contact with the corresponding electrical contact 14. The metal layer 21 defines in each hole 17 the hole 18 coaxial to it.

A certain number of holes 17, advantageously up to about 3% of the total holes 17, may not be present, without compromising, or significantly altering, the efficiency of the photovoltaic cell 10, 100 itself.

As a variant, a part of the holes 18 can be filled with filling material 22 having a color which visually stands out clearly with respect to the color of the surface F.

In this case, and by way of example, the holes 18 that can contain the filling material 22 are included in a specific area A (fig. 4), which for example is rectangular in shape, of the surface F. In particular the area A, it comprises a plurality of x rows, for example 10, and y columns, for example 60, of holes 18.

The holes 18 which actually contain the filling material 22 constitute the identification code 30 of the photovoltaic cell 10, 100, which, for example, is made up of alphanumeric characters. In this way it is possible to have a substantially indelible identification code 30 on each of the photovoltaic cells 10, 100.

According to the present invention, a method for producing an identification code on photovoltaic cells 10, 100 comprises at least one step in which identification means are provided on a portion of the total extension of the external surface F to define the identification code 30 using a specific pattern involving the presence or absence of a part of said first holes 17.

According to a variant, instead of not making certain holes 17, certain holes 18 can be filled with filling material 22 and in any case define the pattern that defines the identification code 30.

It is clear that modifications and / or additions of parts or phases can be made to the photovoltaic cell provided with an identification code and to the process for making it described up to now, without thereby departing from the scope of the present invention.

It is also clear that, although the present invention has been described with reference to some specific examples, a person skilled in the art will undoubtedly be able to produce many other equivalent forms of photovoltaic cells provided with an identification code and procedures for making them, having the characteristics expressed in the claims and therefore all falling within the scope of protection defined by them.

Claims (1)

CLAIMS 1. Photovoltaic cell comprising a surface (F) having a certain total extension suitable for being exposed to light, and a plurality of first holes (17) arranged transversely to said first surface (F) and functional to the production of electrical energy in association with at least one emitting layer (12), characterized in that identification means are provided on a portion of said total extension of said surface (F) to define an identification code (30) using a determined pattern that affects the presence, or the absence, of a part of said first holes (17) 2. Photovoltaic cell as in claim 1, characterized in that said portion is about 3% of said total extension of said surface (F). 3. Photovoltaic cell as in claim 1 or 2, in which said first holes (17) are arranged according to a matrix of rows and columns, characterized by the fact that said pattern is defined by the absence, or by the covering, of a part of said first holes (17). 4. Photovoltaic cell as in claim 3, in which each of said first holes (17) is superficially coated with a layer of conductive material which defines a second hole (18) coaxial to the corresponding first hole (17), characterized in that said identification means comprise a filling material (22) which selectively fills at least a part of said second holes (18) in correspondence with said surface (F). 5. Photovoltaic cell as in claim 4, characterized in that said filling material (22) has a color which stands out with respect to the color of said surface (F). 6. Photovoltaic cell as in claim 4 or 5, characterized in that the number of said second holes (18) which are selectively filled with said filling material (22) is about 3% of the total number of said first holes ( 17). 7. Photovoltaic cell as in claim 4, 5 or 6, characterized in that said surface (F) comprises a determined area (A) inside which is arranged said part of said second holes (18) which are selectively filled with said filling material (22). 8. Photovoltaic cell as in claim 7 characterized in that said second holes (18) contained in said determined area (A) are arranged according to a matrix of x rows and y columns. 9. Photovoltaic cell as in claim 8, characterized in that the number x of said rows is between about 5 and about 15 and that the number y of said columns is between about 40 and about 120. 10. Photovoltaic cell as in any one of the preceding claims, characterized in that said identification code (30) is suitable for being read by the human eye, by means of an electronic system and / or by a CCD camera. 11. Process for making an identification code (30) on a photovoltaic cell having a surface (F) which has a certain total extension suitable for being exposed to light and a plurality of first holes (17) arranged transversely to said surface (F) and functional to the production of electrical energy in association with at least one emitting layer (12), characterized in that it comprises at least a first phase in which identification means are provided on a portion of said total extension of said surface (F) to define said identification code (30) using a determined pattern which affects the presence, or absence, of a part of said first holes (17). 12. Process as in claim 11, characterized in that said portion is about 3% of said total extension of said surface (F). 13. Process as in claim 11 or 12, in which said first holes (17) are arranged according to a matrix of rows and columns, characterized by the fact that said pattern is defined by the absence, or by the covering, of a part of said first holes (17). 14. Process as in claim 13, characterized in that each of said first holes (17) is superficially coated with a layer of conductive material which defines a second hole (18) coaxial to the corresponding first hole (17), and that said identification means comprise a filling material (22) which selectively fills at least a part of said second holes (18) in correspondence with said surface (F). 15. Process as in claim 14, characterized in that said filling material (22) has a color which stands out with respect to the color of said surface (F). 16. Process as in claim 14 or 15, characterized in that the number of said second holes (18) which are selectively filled with said filling material (22) is about 3% of the total number of said first holes (17 ). 17. Process as in claim 16, characterized in that said second holes (18) which are selectively filled with said filling material (22) are arranged in a determined area (A) which is a portion of said surface (F) . 18. Process as in claim 17, characterized in that said second holes (18) of said part which are selectively filled with said filling material (22) are arranged according to a matrix of x rows and y columns. 19. Process as in claim 18, characterized in that the number of said x rows is between about 5 and about 15 and that the number of said y columns is between about 40 and about 120. 20. Use of a photovoltaic cell as in any one of claims 1 to 10, characterized in that said identification code defined by said pattern allows to monitor the centering of the cell itself and possibly, using centering means, to center the cell if it is displaced and / or rotated, with respect to a predetermined position referred to the Cartesian axes.