EP2668040A1 - Printing stencil for applying a printing pattern to a substrate, and method for producing a printing stencil - Google Patents

Abstract

The present invention relates to a printing stencil (2), for example for applying a contact (contact fingers 101, busbar/busbars 102) to a substrate (1) of a solar cell (100) and to a method for producing a printing stencil (2) of this type. The printing stencil (2) comprises a carrier layer (21) and a structure layer (22) which lies under the carrier layer (21), wherein the structure layer (22) has at least one printing image opening (23a) which corresponds to at least part of the printing image of the contact (contact fingers 101, busbar/busbars 102), the carrier layer (21) has one or more carrier layer openings (23b), and the one or more carrier layer openings (23b) overlap in a plan view of the printing stencil (2) with the printing image opening (23a), in such a way that the printing stencil (2) has an opening (23) which is formed from the at least one printing image opening (23a) and the one or more carrier layer openings (23b) and is suitable for applying contact material to the substrate (1) through the opening (23).

Description

 PRINT TEMPLATE FOR APPLYING ONE

 PRINT PATTERNS TO A SUBSTRATE AND METHOD FOR PRODUCING A PRINT TEMPLATE

description

The present invention relates to a printing stencil for applying a printing pattern, in particular a contacting, to a substrate, in particular to a substrate of a solar cell, comprising a carrier layer and a structural layer underlying the carrier layer, the structural layer corresponding at least to at least one part of the printed image of the printing pattern Print image opening and the carrier layer has one or more carrier layer openings. The present invention further relates to a method for producing a

Printing template for applying a printing pattern, in particular a contacting, to a substrate, in particular to a substrate of a solar cell, comprising a carrier layer and a structural layer underlying the carrier layer, wherein the structural layer has at least one printed image opening corresponding to at least a part of the printed image of the printing pattern and the carrier layer comprising one or more carrier layer openings, with the steps of providing the carrier layer, providing a structural layer located below the carrier layer, working out at least one printed image opening in the structural layer corresponding to at least one part of the printed image of the printed pattern and working out one or more carrier layer openings in the carrier layer.

Background of the invention

From the prior art it is conventionally known in technical solar cell printing to apply a contact to a substrate of a solar cell by means of a printing screen. In particular, it is conventionally known to print a metallization, contacting or conductor tracks of a contacting of a solar cell substantially with printing screens by applying a mostly silver, comprehensive printing paste by means of a doctor blade through printed image openings of a printing screen on a substrate of the solar cell, wherein the print image openings of the Print screen essentially correspond to the printed image of the contact to be printed the solar cell.

Such. Printing screens have a wire mesh cloth clamped in a frame which is embedded in a photoemulsion layer (see, for example, DE 10 2007 052 679 A1). The

CONFIRMATION COPY The photoemulsion layer has the print image openings corresponding to the print image of the contact to be printed, wherein the screen fabric also fills the print image openings. In the production of such printing screens usually the wire mesh fabric is stretched onto a frame and then coated with a photosensitive material. Subsequently, the structuring of the printed image.

However, the use of such printing screens in the application of the contacting of the solar cell to the solar cell substrate disadvantages, especially with regard to the printing of the so-called contact fingers of a front contacting the solar cell, the contact fingers should be printed with the smallest possible width on the substrate To reduce shading of the solar cell substrate by the front side contacting and thus to increase the energy efficiency of the solar cell. At the same time must be made possible with respect to the energy efficiency of the solar line by the contact fingers a power line with the lowest possible electrical resistance, i. The contact fingers must be formed with the largest possible aspect ratio, since the electrical resistance of the contact fingers depends on the cross section of the contact fingers. The aspect ratio of the contact fingers should in particular be formed uniformly over the entire length of the contact fingers as possible.

The use of printing screens in applying the contacting of the solar cell to the solar cell substrate results in particular the disadvantages described below. The screen fabric and in particular crossing points of the screen fabric in the region of the print image openings of the photoemulsion layer impair the uniformity of the paste application to the substrate of the solar cell during printing. This results in disadvantageous constrictions in the conductor cross section of the contact fingers and a disadvantageous wavy edge of the printed image. Furthermore, the maximum achievable paste strength, and thereby the maximum achievable height of the printed contact fingers, to which the aspect ratio is directly proportional, severely limited by the Siebgewebestruktur in the print image openings.

In addition, when printing by the pressure of the doctor blade due to the elastic properties of the mesh fabric, an elongation of the fabric, whereby a distortion of the printed image may result. In the case of multiple printing on the substrate with different printing screens, a printing process is usually carried out in several steps with different screens in order to print in each case parts of the contacting. In transition regions of the overall print image, in which print images of different printing screens adjoin one another, irregularities in the overall printed image can arise with conventional printing screens due to the above-described distortion of the individual partial printed images. In addition, with the use of printing screens by the desired large exposed surface of the printing pattern of the screens a very fine fabric for stabilizing the printing screen needed, but which is very prone to damage and thus allows only low downtime.

Summary of the invention

In view of the above-described disadvantages of the use of conventionally known printing screens in the printing of solar cell substrates for applying a contact to a substrate, in particular to a substrate of a solar cell, it is an object of the present invention an improved solution for applying a contact to a Substrate, in particular to provide a substrate of a solar cell, in which the disadvantages described above, occurring when using conventionally known printing screens can be avoided.

A further object of the present invention is to provide an improved solution for applying a contacting to a substrate, in particular to a substrate of a solar cell, in which the contacting and in particular the contact fingers can be applied with a uniform printed image. In particular it is. It is an object of the present invention to provide an improved solution for applying a contacting to a substrate, in particular to a solar cell, in which the contact fingers can be applied with the highest possible uniform aspect ratio over the entire length of the contact fingers.

Furthermore, it is an object of the present invention to provide an improved solution for applying a contacting to a substrate, in particular to a substrate of a solar cell, in which irregularities in the overall printed image when using different printing means with different printed images can be avoided and continue Higher service life can be achieved.

To achieve the above-described objects of the present invention, there is proposed a printing stencil for applying a printing pattern to a substrate according to claim 1 and a method for producing a stencil sheet according to claim 12. Dependent claims relate to preferred embodiments of the present invention.

A printing stencil for applying a printing pattern, in particular a contacting, to a substrate, in particular a substrate of a solar cell, according to The present invention comprises a carrier layer and a structural layer lying below the carrier layer or arranged below the carrier layer. In this case, it is preferably provided to provide the carrier layer on the rakel side and the structural layer on the substrate side.

According to the invention, the structural layer has at least one printed image opening corresponding to at least one part of the printed image of the printed pattern, the carrier layer has one or more carrier layer openings and the one or more carrier layer openings overlap one another in a top view of the printing template with the printed image opening such that the printing stencil forms one of the at least one a printing image opening and the one or more carrier layer openings formed opening and is adapted to a printing medium such as Apply contact material through the opening on the substrate.

The use of such a printing stencil according to the invention for applying a printing pattern, in particular a contacting, to a substrate, in particular to a substrate of a solar cell, instead of a conventional screen printing stencil, results with the carrier layer, preferably of a stable carrier material, such as e.g. Metal or plastic, a lot of advantages.

In particular, it is advantageously possible according to the invention to open the print image opening of the printing template specifically for the printed image of the printing pattern, in particular the contacting and, in particular, the contact fingers of a contacting, the disadvantage of the printing screens concerning the masking of the printed image opening through stitches and in particular mesh nodes of the screen fabric can be avoided. Thus, particularly advantageous contact fingers with high and at the same time over the entire length of the contact fingers uniform aspect ratio can be printed. In particular, it is thus possible to increase the paste application, to ensure a uniform over the entire length Kontaktfingerquerschnitt and to obtain straight print edges. Thus, e.g. the conductivity of a contact and in particular the contact fingers are improved even at the smallest finger widths.

In addition, the support layer, which preferably forms the entire surface of a main body of the printing stencil, results in an advantageously higher mechanical strength. Thus, the stretching of the pressure body can be reduced upon pressure application by the doctor, whereby a more uniform, positionally accurate and especially undistorted total print image is made possible, even when printing the printing pattern or the contacting in several steps (so-called stacking) with a plurality of different printing images having printing stencils , Finally, a longer service life than when using the conventionally known pressure screens is still possible. Compared to the use of standard stencils without a structural layer (eg sheet metal stencils), there is advantageously an improved sealing effect on the substrate side. Preferably, the one or more carrier layer openings have circumferentially exposed opening walls. This has the advantage that the printing stencil can be produced in a particularly simple manner, since no sections of the structural layer protrude into the region of the carrier layer openings. This also results in a higher resistance to aggressive media, since the upper areas of the printing openings. the more resistant carrier layer material is formed.

Preferably, the at least one print image opening according to a first embodiment of the present invention is narrower, i. in particular with a smaller opening width, is formed as the one or more carrier layer openings. This has the advantage that a cleaning of the printing stencil after printing from the doctor side can be further facilitated. In addition, this makes it possible to work more efficiently when working out the carrier layer openings with lower accuracy, since a high accuracy of the geometry of the carrier layer openings for high quality of the printed image is not required because the printed image and its quality depends only on the narrower openings in the structural layer. The production of the carrier layer can thus be carried out more simply and more efficiently, since lower quality requirements can be imposed on the geometry of the carrier layer openings.

According to a particularly preferred second alternative embodiment of the present invention, which is alternative to the first exemplary embodiment, the one or more carrier layer openings are narrower, ie in particular with a smaller opening width, than the printed image opening. Thus, there is the advantage that the structural layer can be stabilized from above by the carrier layer during the application of pressure by means of the doctor blade in the entire region of the structural layer, in particular up to the edge regions of the printed image openings of the structural layer, so that when printing in the edge region of the ^' print image openings an even better sealing effect between the substrate surface and the structural layer can be achieved. Furthermore, the paste can be applied to the substrate during printing through the narrower openings of the carrier layer with a higher squeegee pressure, so that the paste can be completely and uniformly filled in the area between the carrier layer and the substrate to be printed, in particular also in areas below any Webs of the carrier layer, which optionally separate a plurality of carrier layer openings for stabilizing the template and below which no material of the structural layer is provided. Another great advantage of a printing stencil in which the one or more carrier image openings narrower, ie, in particular formed with a smaller opening width than the one or more print image openings, results from the flexibility regarding the possibilities in the manufacturing process of the printing stencil. In such a printing stencil, it is both possible to work out the carrier layer openings before and after application of the structural layer and working out of the printed image openings in the structural layer, for example preferably by laser cutting, etching or electroplating. On the other hand, in the case of printing stencils with a narrower printing image opening, it is only possible to first provide the carrier layer with the carrier layer openings and then apply the structural layer and apply the printed image openings in the structural layer, since otherwise the structure layer could be damaged during the working out of the carrier layer openings. Preferably, the print image opening and / or the one or more

Carrier layer openings formed substantially rectangular. Essentially rectangular is intended to mean that the corners can be rounded.

The printing stencil preferably has a first carrier layer opening and a second carrier layer opening which are separated by a web of the carrier layer, in particular preferably a web having a width of less than or equal to 50 μm, particularly preferably less than 35 μm. In the case of an elongated print image opening and / or in the case of elongated carrier openings, such a web preferably runs transversely, in particular preferably perpendicular, to the longitudinal direction of the print image opening and / or carrier openings.

By means of a web in the carrier layer, there is the advantage that the printing stencil itself, even with an elongated printing image opening, e.g. can be formed according to an elongated contact finger of the contacting by one or more webs between adjacent carrier layer openings. Below the webs, preferably no material of the structure layer is provided, in particular the web preferably bridges the print image opening in the structure layer, so that the first and second carrier layer openings separated by the web overlap with the same print image opening of the structure layer. Preferably, one or more webs are provided, wherein the distance between two

Webs or the distance of a web to an end portion of the support opening in a range between 100 and 500 μιη is, preferably between 250 and 500 pm. With printing image opening widths in the range between 50 and 100 pm, this results in a high Stability of the printing stencil while avoiding irregularities in the printed image due to a too high web density similar to irregularities due to the Siebgewebemaschen and mesh knots in the printing area in the printing screens described above.

The material of the carrier layer preferably comprises metal, in particular stainless steel or nickel, and / or plastic. Preferably, the carrier layer consists of metal, in particular stainless steel or nickel, and / or plastic. Preferably, the carrier layer comprises one or more metal layers and / or one or more plastic layers. The carrier layer preferably comprises or the carrier layer consists of a metal sheet.

The carrier layer preferably has a layer height of greater than or equal to 10 μm.

Preferably, the structural layer is made of a liquid or solid, preferably photosensitive, material, especially preferably a photosensitive photoemulsion. Thus, the structural layer can be easily applied to the carrier layer or a further intermediate layer, wherein the print image openings thereafter can be worked out particularly precisely and efficiently by substrate-side exposure of the printing stencil and subsequent development of the structure layer, in particular photoemulsion layer, produced from the photosensitive material. Preferably, the photosensitive material is negatively exposable or positively exposed.

The structural layer preferably has a layer height of greater than or equal to 5 μm. Preferably, the structural layer is on the carrier layer or one between the

Structured layer and the carrier layer lying intermediate layer applied.

The carrier layer preferably has a surface structure on the side on which the structural layer is applied. This facilitates the application of the structural layer to the carrier layer by providing a higher adhesive effect on the substrate-side surface of the carrier layer, in particular when using photoemulsions.

Preferably, the carrier layer and / or the entire stencil is surface-treated to improve the printing behavior, in particular by at least one of painting, coating and roughening.

Preferably, the width of the print image opening is greater than or equal to 35 m and / or less than or equal to 150 pm. According to the present invention, there is further provided a method of manufacturing a stencil sheet according to at least one of the above aspects. The method according to the invention comprises the steps of providing a carrier layer, providing a structural layer below (ie in particular on the substrate side), working out at least one corresponding print image opening in the structural layer and working out one or more carrier layer openings in at least one part of the print image of the print pattern the carrier layer. According to the invention, the print image opening and the one or more

Carrier layer openings worked out such that the one or more carrier layer openings overlap in plan view of the printing template with the print image opening such that the printing stencil has an opening formed from the at least one print image opening and the one or more carrier layer openings and is suitable, a pressure medium through the opening to apply to the substrate.

Preferably, the step of providing a structural layer overlying the carrier layer comprises a step of coating the structural layer with the material of the structural layer or coating an intermediate layer with the material of the structural layer.

According to a first preferred embodiment, the print image opening and the one or more carrier layer openings are preferably worked out in such a way that the print image opening is narrower than the one or more carrier layer openings. According to a second, alternative to the first embodiment preferred

Embodiment, the print image opening and the one or more carrier layer openings are preferably worked out such that the one or more carrier layer openings are formed narrower than the print image opening. Preferably, the steps of the method are carried out in the following order: first providing the carrier layer, eg by clamping in a frame, then working out the one or more carrier layer openings in the carrier layer, eg by laser processing, etching and / or galvanic methods, then providing the under the structure layer already having the support openings and then working out the at least one print image opening in the structure layer, eg by exposure and development, when a photoemulsion layer or photosensitive structure layer is used. Alternatively, the steps of the method according to another embodiment are performed in the following order: first providing the carrier layer, eg by clamping in a frame, then providing the structural layer underlying the carrier layer, then working out at least one print image opening in the structural layer, eg by exposure and developing when a photoemulsion layer or photosensitive structural layer is used, and then working out the one or more carrier layer openings in the carrier layer. However, this is only advantageous if the print image opening is wider or of the same width as the at least one support layer opening to be worked out, since otherwise the structure layer could be damaged when working out the support layer opening.

The step of working out the one or more carrier layer openings in the carrier layer is preferably carried out by means of laser cutting, etching and / or a galvanic method.

Preferably, the structural layer is made of a liquid or solid photosensitive material, in particular of a photosensitive photoemulsion, wherein the step of working out at least one printed image opening in the structural layer preferably comprises the following steps: exposing the structural layer by means of electromagnetic radiation of a predetermined wavelength or a predetermined wavelength range, in particular by means of infrared, visible and / or ultraviolet light, with a printed image and developing the exposed photosensitive material of the structural layer.

Preferably, the step of providing the structural layer underlying the carrier layer comprises the steps of providing an intermediate layer under the carrier layer and applying the structural layer on the intermediate layer. Alternatively, the step of providing the structural layer underlying the carrier layer preferably comprises the step of applying the structural layer to the carrier layer.

Preferably, the method comprises the further step of working out a surface structure on the side of the carrier layer facing the structural layer in order to be able to improve an adhesion effect when the structural layer is applied and to facilitate the application of the structural layer.

The method preferably comprises the further step of surface-treating the carrier layer and / or the entire stencil to improve the printing behavior, in particular by means of at least one of painting, coating and roughening. Brief description of the figures

Fig. 1 shows a plan view of a known from the prior art solar cell.

Fig. 2A is a plan view of a portion of a prior art screen and Fig. 2B is a cross-sectional view of the prior art screen of Fig. 2B.

3A shows a cross-section through a section of a printing stencil according to a first exemplary embodiment of the present invention, FIG. 3B shows a blade-side plan view of the section of the printing stencil from FIG. 3A, and FIG. 3C shows a substrate-side plan view of the section _. the printing stencil of Fig. 3A.

4A shows a cross section through a section of a printing template according to a second embodiment of the present invention, FIG. 4B shows a squeegee-side plan view of the section of the printing template from FIG. 4A, and FIG. 4C shows a substrate-side plan view of the section of the printing template from FIG. 4A ,

Detailed description of the figures and

 Preferred embodiments of the invention

Hereinafter, various embodiments of the present invention will be described in detail with reference to the drawings. Identical or similar elements in the figures are denoted by the same reference numerals. However, the present invention is not limited to the described embodiments, but further includes modifications of features of the described embodiments and combination of features of various embodiments within the scope of the independent claims.

1 shows, by way of example, a plan view of a solar cell 100 known from the prior art. The solar cell 100 comprises a substantially rectangular photovoltaic semiconductor photovoltaic substrate layer, hereinafter referred to as substrate 1, on the front side a front contact with two (optionally also a plurality of) electrically conductive mutually parallel busbars 102 for dissipating the electrical energy and for connecting the solar cell 100 with other solar cells to a solar cell module. Perpendicular to the busbars 102 are a plurality of also parallel to each other, but extending transversely to the busbars 102 contact fingers 101 as part of the front contacting intended. These conduct the electrical energy generated by the incidence of light in the substrate 1 to the busbars 102. In order to enable a high energy efficiency of the solar cell by low electrical resistances of the conductor tracks and at the same time the lowest possible shading, the contact fingers 101 with a maximum and over the entire length the contact finger 101 uniform aspect ratio, ie high altitude and minimum

Width, be applied.

2A shows by way of example a plan view of a section of a printing screen 200 known from the prior art, and FIG. 2B shows by way of example a cross-section of the section of the printing screen 200 of FIG. 2B known from the prior art. The printing screen 200 includes a photo emulsion layer 201 having a print image opening for printing the front side contact. The photoemulsion layer is stabilized by a screen mesh 202, which is incorporated in the photoemulsion layer 201. This results in particular in the disadvantage that the screen fabric 202 also fills the free print area of the print image opening and thus can lead to an uneven paste imprint when printing the front side contacting, in particular in the area of the mesh nodes of the screen fabric 202.

3A shows, by way of example, a cross section through a section of a printing stencil 2 according to a first exemplary embodiment of the present invention. FIG. 3B shows by way of example a blade-side plan view of the section of the printing stencil 2 from FIG. 3A, and FIG. 3C shows by way of example a substrate-side top view 2 of the section the printing stencil of Fig. 3A. The cross-section in Fig. 3A is taken along the section line A - A in Figs. 3B and 3C.

The printing stencil 2 comprises a squeegee-side carrier layer 21, e.g. made of a metal such as Stainless steel or nickel or even plastic, and a substrate-side structural layer 22, e.g. from a photo emulsion.

The carrier layer 21 comprises elongated, rectangular carrier layer openings 23b, which are separated from each other by a web 21a. The structure layer comprises an elongated, rectangular print image opening 23a which corresponds at least to a part of a print image of a front side contact of a solar cell 100 to be printed, in particular to at least one part of a print image corresponding to a contact finger 101 to be printed on the front side contact.

In the printing stencil 2, an opening 23 is thus provided by the printing image opening 23a and the overlying carrier layer openings 23b, through the printing paste can be applied by means of a doctor blade to the substrate 1 for printing at least a portion of the front contact. The carrier layer openings 23b overlap in particular in plan view of the printing stencil 2 (ie in the viewing direction according to FIG. 3B or 3C) with the printed image opening 23a such that the printing stencil 2 has the openings 23 formed from the printed image opening 23a and the carrier layer openings (23b) and thereto is suitable to apply the printing paste through the openings 23 on the substrate 1. The carrier layer openings 23b in this case have circumferentially exposed opening walls. The webs 21a bridge the printed image opening 23a of the structural layer 22 and no material of the structural layer 22 is located under the webs 21a.

As can be seen in particular in FIGS. 3A and 3C, the carrier layer openings 23b in this exemplary embodiment of the present invention are narrower than the print image opening 23a. In particular, in this embodiment of the present invention, the substrate layer openings 23b have a smaller opening width than the printing image opening 23a. This allows a particularly great flexibility in the production of the printing stencil 2, since the carrier layer openings 23b can be worked out both before and after application of the structural layer 22 to the carrier layer 21 and working out of the printed image opening 23a, without the structural layer 21 or the possibly already worked out Print image opening 23a to damage. In addition, the generally softer structural layer can advantageously be stabilized by the carrier layer up to its edges at the openings 23a of the printed image.

4A shows by way of example a cross section through a detail of a printing stencil 2 according to a second embodiment of the present invention, FIG. 4B shows by way of example a squeegee-side plan view of the detail of the stencil sheet from FIG. 4A, and FIG. 4C shows by way of example a substrate-side plan view of the section of the stencil sheet from Fig. 4A. The cross-section in Fig. 4A is taken along the section line A - A in Figs. 4B and 4C.

The printing stencil 2 in turn comprises a squeegee-side carrier layer 21, e.g. made of a metal such as Stainless steel or nickel or even plastic, and a substrate-side structural layer 22, e.g. from a photo emulsion.

The carrier layer 21 comprises elongated carrier layer openings 23b, which are separated from each other by a web 21a. The structure layer comprises an elongated print image opening 23a.

In the printing stencil 2, an opening 23 is thus provided by the printing image opening 23a and the overlying carrier layer openings 23b, through the printing paste can be applied by means of a doctor blade to the substrate 1 for printing the front contact. The carrier layer openings 23b overlap in particular in a top view of the printing template 2 (ie in the viewing direction according to FIG. 4B or 4C) with the printed image opening 23a such that the printing template 2 has the openings 23 formed from the printed image opening 23a and the carrier layer openings 23b ^" and is suitable for this purpose is to apply the printing paste through the openings 23 on the substrate 1. The carrier layer openings 23b have circumferentially exposed opening walls.The webs 21a bridge the print image opening 23a of the structure layer 22 and below the webs 21a in the region of the print image opening 23a is no material of the structure layer 22nd

As can be seen in particular in FIGS. 4A and 4C, the carrier layer openings 23b in this embodiment of the present invention are made wider than the press image opening 23a. In particular, in this embodiment of the present invention, the substrate layer openings 23b have a higher opening width than the printing image opening 23a. This advantageously makes possible a simpler and more efficient production of the carrier layer, since the accuracy requirements in the working out of the carrier layer openings can be reduced, since the accuracy of the printed image is determined by the accuracy of the geometry of the processed print image openings in the structure layer, which results from an exposure method easy way can be guaranteed.

In summary, in comparison with the use of printing screens, the present invention provides an improved solution for applying a contacting to a substrate, in particular to a substrate of a solar cell, in which the contacting and in particular the contact fingers can be applied with a more uniform printed image. In particular, the present invention provides an improved solution for applying a contacting to a substrate, in particular to a substrate of a solar cell, in which the contact fingers can be applied with the highest possible uniform aspect ratio over the entire length of the contact fingers. Finally, in particular, provides an improved solution for applying a

Contacting a substrate, in particular on a substrate of a solar cell, ready, can be avoided in the irregularities in the overall printing image when using different printing media with different print images and continue also longer service life can be achieved. When using a stencil, stencil changes are less frequently required than changing screens when using printing screens, so that time savings can be achieved by fewer changes (i.e., less machine downtime).

Claims

1. printing template for applying a printing pattern (101, 102) on a substrate

(1), comprising:

 a carrier layer (21) and

 a structural layer (22) underlying the carrier layer (21), wherein

 the structural layer (22) at least one at least part of the printed image of the

Print pattern (101, 102) has corresponding print image opening (23a),

 the carrier layer (21) has one or more carrier layer openings (23b) and the one or more carrier layer openings (23b) are in plan view of the

 Cover printing template (2) with the printed image opening (23a) such that the printing stencil

(2) one of the at least one print image opening (23a) and the one or more

Carrier layer openings (23b) formed opening (23) and is adapted to apply a pressure medium through the opening (23) on the substrate (1).

2. Printing template according to claim 1, characterized in that the one or more carrier layer openings (23b) have circumferentially exposed opening walls.

3. Printing template according to claim 1 or 2, characterized in that

the print image opening (23a) is narrower than the one or more

Carrier layer openings (23b).

4. Printing stencil according to claim 1 or 2, characterized in that the one or more carrier layer openings (23b) are narrower than the printed image opening (23a).

5 printing stencil according to at least one of claims 1 to 4, characterized

in that the print image opening (23a) and / or the one or more

Carrier layer openings (23b) are formed substantially rectangular or round opening edges.

6. Printing template according to at least one of claims 1 to 5, characterized

in that the printing stencil has a first carrier layer opening (23b) and a second carrier layer opening (23b) which are separated by a web (21a) of the carrier layer (21), in particular a web (21a) with a width of less than or equal to 50 μm.

7. Printing stencil according to at least one of claims 1 to 6, characterized in that the material of the carrier layer (21) comprises metal, in particular stainless steel or nickel, and / or plastic.

8. Printing stencil according to at least one of claims 1 to 7, characterized

in that the structural layer (22) is made of a liquid or solid material, and in particular comprises a photosensitive material.

9. Printing stencil according to at least one of claims 1 to 8, characterized

in that the structural layer (22) is applied to the carrier layer (21) or to an intermediate layer located between the structural layer (22) and the carrier layer (21).

10. Printing stencil according to at least one of claims 1 to 9, characterized

in that the carrier layer (21) has a surface structure on the side on which the structural layer (22) is applied.

11. Printing stencil according to at least one of claims 1 to 10, characterized

in that the surface of the carrier layer (21) and / or the surface of the entire stencil is surface-treated to improve the printing behavior, in particular by at least one of painting, coating and roughening.

12. A method for producing a printing stencil according to at least one of

Claims 1 to 11, comprising:

 Providing a carrier layer (21),

 Providing a structural layer (22) underlying the carrier layer (21), working out at least one printed image opening (23a) in the structural layer (22) and corresponding to at least one part of the printed image

 Working out one or more carrier layer openings (23b) in the carrier layer

(21)

 wherein the print image opening (23a) and the one or more carrier layer openings (23b) are machined such that the one or more carrier layer openings (23b) overlap the print image opening (23a) in plan view onto the print template (2) in such a way that the print template (23) 2) has an opening (23) formed from the at least one print image opening (23a) and the one or more carrier layer openings (23b) and is adapted to apply a print medium to the substrate (1) through the opening (23).

13. The method according to claim 12, characterized in that the step

Providing a structural layer (22) overlying the carrier layer (21) one step Coating the structural layer (22) with the material of the structural layer (22) or coating an intermediate layer with the material of the structural layer (22).

14. The method according to claim 12 or 13, characterized in that the

 Print image opening (23 a) and the one or more carrier layer openings (23 b) are machined out such that the print image opening (23 a) is formed narrower than the one or more carrier layer openings (23 b).

15. The method according to claim 12 or 13, characterized in that the

 Print image opening (23a) and the one or more carrier layer openings (23b) are machined out such that the one or more carrier layer openings (23b) are formed narrower than the print image opening (23a).

16. The method according to claim 14 or 15, characterized in that the steps of the method are carried out in the following order:

 Providing the carrier layer (21),

 Working out of the one or more Trägerschichtöffnüngen (23 b) in the

Carrier layer (21),

- Providing the under the support layer (21) lying structural layer (22) and

 Working out the at least one print image opening (23a) in the structural layer (22).

17. The method according to claim 15, characterized in that the steps of

Process in the following order:

Providing the carrier layer (21),

 Providing the structural layer (22) underlying the carrier layer (21),

 Working out at least one printed image opening (23a) in the structural layer (22) and working out the one or more carrier layer openings (23b) in the

Carrier layer (21).

18. The method according to at least one of claims 12 to 17, characterized

characterized in that the step working out one or more

Carrier layer openings (23b) in the carrier layer (21) by means of laser cutting, etching and / or a galvanic process is performed.

19. The method according to at least one of claims 12 to 18, characterized

characterized in that the structural layer (22) is made of a liquid or solid material.

20. The method according to at least one of claims 12 to 19, characterized

in that the structural layer (22) comprises a photosensitive material, in particular a photosensitive photoemulsion, wherein the step comprises working out at least one printed image opening (23a) in the structural layer (22):

 Exposure of the structure layer (22) by means of electromagnetic radiation of a predetermined wavelength or a predetermined wavelength range, in particular by means of infrared, visible and / or ultraviolet light, with a printed image of the

Printed pattern of the solar cell and

Developing the photosensitive material of the structural layer (22).

21. The method according to at least one of claims 12 to 20, characterized

characterized in that the step of providing the structural layer (22) underlying the carrier layer (21) comprises the steps of providing an intermediate layer under the carrier layer (21) and applying the structural layer (22) to the intermediate layer or providing the step below the carrier layer (21) lying structural layer (22) comprises the step of applying the structural layer (22) on the carrier layer (21).

22. The method according to at least one of claims 12 to 21, characterized by the further step working out a surface structure on the said structural layer (22) facing side of the carrier layer (21).

23. The method according to at least one of claims 12 to 22, characterized by the further step of surface treating the carrier layer (21) and / or the entire stencil for improving the printing behavior, in particular by at least one of painting, coating and roughening.