EP2761669A1

EP2761669A1 - Photovoltaic module, method and production installation for producing a photovoltaic module

Info

Publication number: EP2761669A1
Application number: EP12711807.3A
Authority: EP
Inventors: Wilhelm Stein
Original assignee: Individual
Current assignee: Individual
Priority date: 2011-09-27
Filing date: 2012-03-06
Publication date: 2014-08-06
Also published as: DE202012013580U1; WO2013045117A1

Abstract

A photovoltaic module having a multiplicity of segments (5, 7) which are electrically connected in series comprises: a layer stack (9) which is arranged on a substrate (1) and has: a first electrode (2) arranged on the substrate, a photoactive absorber (3) arranged on said first electrode, a second electrode (4) arranged on said photoactive absorber, a dividing line (31) which interrupts the layer stack (9) for the purpose of forming the segments (5, 7), a plurality of contact connection regions (6) which are arranged at a distance from one another along the dividing line (31) and which each have: an electrical insulation (30) for the second electrode (4), a contact connection (32, 33) by means of which the second electrode (4) is electrically coupled to the first electrode (2) for the purpose of connecting the segments (5, 7) in series, an electrically conductive material (32) which has been put onto that side (10) of the second electrode (4) which is averted from the absorber (3) for the purpose of electrically bypassing the dividing line.

Description

description

Photovoltaic module, process and manufacturing facility for

Production of a photovoltaic module

The invention relates to a photovoltaic module, a method for producing a photovoltaic module and a

Manufacturing plant for producing a photovoltaic module according to such a method.

Thin-film solar cell modules, too

Thin-film photovoltaic modules called, have photoactive

Layers with layer thicknesses of the order of

Microns. The semiconductor material used in the photoactive layer or layers may be amorphous or

be microcrystalline. Also a combination of layers of amorphous and layers of microcrystalline

Semiconductor material within a cell is possible, for example in the so-called tandem cells and the like

called triple cells. The semiconductor materials used are Si, Ge and compound semiconductors such as CdTe or Cu (In, Ga) Se2 (abbreviated CIS or CIGS) as well as compound semiconductors based on III-V (GaAs) and organic substances. To economic modules with the largest possible area

to be able to use without the laterally dissipated in the electrodes of the solar cells current is so large that high ohmic losses occur

Thin-film photovoltaic modules usually divided into a plurality of segments. The strip-shaped and usually a few millimeters to centimeters wide segments usually run parallel to an edge of the module. The segments are formed by continuous substrate individual layers of the layer structure of the solar cell are interrupted by thin dividing lines. On the one hand, the separating lines lead to the fact that identical layers of adjacent segments are electrically insulated from one another and, on the other hand, that layers subsequently applied along one

Contacting with underlying layers can be electrically connected. With a suitable arrangement of

Dividing lines can be achieved in this way a series connection of the individual segments. In the area of

Dividing lines no electric current is generated.

It is desirable to provide a photovoltaic module that is efficient. It is further desirable to provide a method of manufacturing an efficient photovoltaic module

indicate that allows a cost-effective production. Furthermore, it is desirable to specify a manufacturing plant for producing an efficient photovoltaic module.

In one embodiment of the invention comprises

Photovoltaic module with a plurality of electrically connected in series segments arranged on a substrate layer stack. The layer stack has a first electrode arranged on the substrate, a photoactive absorber arranged thereon and a second electrode arranged thereon. A dividing line interrupts the layer stack to form the segments. The photovoltaic module includes a plurality of contacting areas spaced apart along the dividing line. The contacting areas each have an electrical

Isolation of the second electrode. The

Contact areas always have one

Contacting, via which the second electrode is electrically coupled to the first electrode for series connection the segments. The contacting regions furthermore each have an electrically conductive material, which is on the side of the second electrode facing away from the absorber

is applied to electrically bridge the dividing line.

The contacting areas for series connection of the segments are provided only in individual areas along the dividing line. As a result, the area not usable for energy conversion is reduced or the usable area is increased. The dividing line has, for example, a width of about 10 μπι to 40 μπι, in particular 20 to 40 μπι. The

Contact areas have a width of about 100 μπι to 500 μπι, in particular from about 200 μπι to 300 μπι, on. The distance between the individual contacting regions is for example approximately between 1 mm and 100 mm, in particular between 40 mm and 80 mm. The dividing line

the individual layers of the layer stack are electrically isolated from each other on both sides of the dividing line. Due to the electrically conductive material, this interruption for the second electrode is bridged again, so that the

Series connection of the two segments is reached.

Characterized in that for the electrical contact between the second electrode and the first electrode only

Sectionally takes place at several points of the photovoltaic module, the contacting area, which is not for

Conversion of radiation energy into electrical energy contributes, formed between a first and a second segment of the photovoltaic module with the smallest possible proportion of the total area of the photovoltaic module. Thus, with respect to the photovoltaic module as little as possible surface area required for contacting and accordingly there is more area available, which in operation for the conversion of Radiation energy contributes to electrical energy. With constant module size thus the efficiency of the photovoltaic module is increased. According to further embodiments, this is electrical

conductive material in a range of electrical

Insulation applied on the side facing away from the substrate of the first electrode, so that the second electrode is electrically coupled by means of the electrically conductive material with the first electrode.

The conductive material is applied in such a way that it at least partially covers both the side of the second electrode facing away from the absorber in the contacting regions and partially protrudes into the electrical insulation and is electrically coupled to the first electrode. The electrical insulation is not completely filled by the conductive material, so that the second

Electrode in the field of electrical insulation

is electrically isolated. So that can be for the

Contacting areas required area can be further reduced.

According to further embodiments, the contacting comprises a conductive material compound and / or a conductive alloy of elements of the photoactive absorber and the second electrode. In particular, the second electrode and the photoactive absorber are locally limited melted by irradiation of laser light, but not evaporated. By diffusion processes in the melt, either a silicide, for example AgAISi with a quasi-metallic conductivity or a eutectic of Si and Ag, which also has a high conductivity, are formed. This can be done this point current from the backside electrode into the

Front electrode flow. The conductive material serves to contact the second electrode on one side of the parting line with the conductive material compound

and / or the conductive alloy on the other side of the dividing line. So it is possible that for the

Contact areas further reduce required area.

According to the embodiments, in which the electric

conductive material in the field of electrical

Insulation on the side facing away from the substrate of the first electrode is applied, so that the second electrode is electrically coupled by means of the electrically conductive material with the first electrode, it is no longer

necessary to form the conductive material compound and / or the conductive alloy of elements of the photoactive absorber and the second electrode to the second

Electrode with the first electrode to electrically couple. The dividing line interrupts the layer stack according to further embodiments linearly completely along the entire length of the layer stack. Thus, a simple production of the parting line is possible and the series resistance of

Photovoltaic module is low.

According to further embodiments of the invention, a photovoltaic module comprises a plurality of electrically connected in series segments. The photovoltaic module comprises a layer stack arranged on a substrate with a first electrode arranged on the substrate, a photoactive absorber arranged thereon and one thereon

arranged second electrode. A dividing line interrupts the layer stack to form the segments in areas. The Photovoltaic module has a plurality of

Contacting areas, which are spaced from each other along the dividing line. The

Contact areas each have an electrical

Isolation of the second electrode and a contact, via which the second electrode is electrically coupled to the first electrode for series connection of the segments, on. The first electrode is interrupted in the contacting areas in each case by a further dividing line. The first

The electrode has locally different physical properties in the region of the further separating line than outside the further separating line. The locally different physical

Properties in the region of the further separating line are based on a change in the doping after a recrystallization of the first electrode in the region of the further separating line and / or on the formation of an oxide of an element from the photoactive absorber adjacent to the first electrode in the region of the further separating line. The second electrode extends in the contacting regions in each case above the other

Dividing line throughout. The further dividing line is introduced into the first electrode after the absorber and the second electrode are arranged on the first electrode. In particular, the further separation line is produced by irradiating a laser radiation which has no or only a slight influence on the photoactive absorber and the second electrode.

Embodiments of the invention include a

Manufacturing plant and a method for producing a photovoltaic module. A layer stack on a substrate is provided with an electrode disposed thereon, a photoactive absorber disposed thereon, and a second electrode disposed thereon. Below is the module segmented by a dividing line. The back contact is severed in regions in a plurality of regions. The regions are arranged along the dividing line. Of the

Rear contact is separated by the dividing line severed. A plurality of ohmic contacts between each of the first electrode and the second electrode become regions between the insulating line and the region

Traction formed.

Further advantages, features and developments will become apparent from the following in conjunction with the figures

explained examples. The same, similar and equally acting elements may be provided in the figures with the same reference numerals. The illustrated elements and their proportions to each other are basically not to be regarded as true to scale, but rather individual

Elements, such as areas or layers to be shown exaggerated large or thick dimensioned for clarity.

Show it:

FIG. 1A shows a schematic illustration of a plan view of a photovoltaic module according to an embodiment,

Figures 1B and 1C each show a schematic representation of a

Sectional view of the photovoltaic module according to an embodiment,

FIG. 2 shows a schematic representation of a detailed view of the photovoltaic module according to FIG. 1A, FIG. 3 shows a schematic representation of a contacting according to an embodiment,

Figure 4 is a schematic representation of a contact according to an embodiment, and

Figure 5 is a schematic representation of a contact according to an imple mentation form. Figure 1A shows schematically an embodiment of a

Photovoltaic module 40 in supervision. The photovoltaic module 40 is set up to convert radiant energy into electrical energy when ready for operation. The photovoltaic module 40 is a type of a thin-film photovoltaic module, too

Called Dünnfilmfotovoltaikmodul. The photovoltaic module 40 has a plurality of segments 5, 7 which are arranged on a common substrate 1 (FIGS. 1B, 1C, 3 to 5). The segments 5, 7 also become photovoltaic cells

called .

Each two immediately juxtaposed segments, for example, the segments 5 and 7 are by a

Separation line 31 and a contacting region 6 separated. The photovoltaic module 40 is, for example, a silicon thin-film photovoltaic module, a CIS thin-film photovoltaic module, a CdTe thin-film photovoltaic module or a III-IV thin-film photovoltaic module. The photovoltaic module 40 is, according to other embodiments, a photovoltaic module comprising organic materials.

Along the dividing line 31, a plurality of regions 15 are arranged in the contacting region, in each of which a series connection of the two segments 5 and 7 is realized. Outside the regions 15, the segments 5 and 7 are completely electrically isolated from each other. In particular, outside the regions 15, all layers of the

Layer stack 9 of the segment 5 electrically from all

Layers of the layer stack 9 of the segment 7 isolated.

The dividing lines 31 each extend linearly along the photovoltaic module 40. The dividing lines 31 are in accordance with FIG

Executions do not form non-linear ones

Interruptions. The dividing lines 31 extend in the

Essentially parallel to each other.

FIG. 1B schematically shows a section of the

Photovoltaic module 40 in cross section according to embodiments. A first electrode 2 is in operation of the sun

or the incident radiation (100) arranged facing. A second electrode 4 is arranged facing away from the sun or the incident radiation (100) during operation. The substrate 1 is in operation of the sun

or the incident radiation (100) arranged facing. The substrate 1 is transparent. The

Photovoltaic module 40 is for example of the type

Silicon thin film photovoltaic modules. The first electrode 2 is in particular transparent, for example a TCO. The second electrode 4 is in particular metallic and

for example, reflective.

Figure IC schematically shows a section of the

Photovoltaic module 40 in cross section according to embodiments. The first electrode 2 is in operation of the sun

or the incident radiation (100) facing away. The second electrode 4 is in operation of the sun or the incident radiation (100) arranged facing. The substrate 1 is in operation of the sun

or the incident radiation (100) facing away. The photovoltaic module 40 is, for example, of the type of a CIS thin-film photovoltaic module. The second

In particular, electrode 4 is transparent, for example a TCO. The first electrode 2 is in particular metallic and, for example, reflective. According to embodiments, a substrate (not shown) is arranged on the side of the second electrode 4 facing away from the substrate 1.

Figure 2 shows a schematic detail view of a region 15. The dividing line 31 is linearly linear. An electrical insulation 30 runs starting at the

Dividing line 31 transversely to the dividing line 31, then spaced from the dividing line 31 rectified, substantially parallel to the dividing line 31 and then again transverse to the dividing line 31. The electrical insulation 30 has a U-shape. The

Dividing line 31 and electrical insulation 30 include a region in which the electrical contact between the second electrode 4 of the segment 5 and the first electrode 2 of the segment 7 (Figures 1B, IC, 3 to 5) is realized. According to further embodiments, the electrical insulation 30 has a V-shape. The electrical insulation 30 has, according to further embodiments, a form

Semicircle shape on. The electrical insulation 30 has, according to other embodiments, a further shape that allows the electrical insulation 30 and the

Dividing line 31 delimit an area in which the

electrical contact between the second electrode 4 of the segment 5 and the first electrode 2 of the segment 7 can be realized. According to the illustrated embodiment, which is shown in cross-section in Figure 3, between the electrical insulation 30 and the dividing line 31 a

Material compound and / or alloy 33 is formed. The material compound and / or alloy 33 is electrically conductive. The material compound and / or alloy 33 is electrically coupled to an electrically conductive material 32. The electrically conductive material 32 extends transversely to the longitudinal direction of the dividing line 31 and extends from one side of the dividing line 31 to the other side of the dividing line 31

Dividing line 31. The electrically conductive material 32 couples the region between the dividing line 31 and the electrical insulation 30 with the side of the dividing line 31 facing away from the electrical insulation 30.

Figure 3 shows a schematic representation of

Series connection according to an imple mentation form. Figure 3 shows a sectional view of the representation of Figure 2 along the line AA '.

The photovoltaic module 40 has the electrically conductive layer 2 on the extensively extended substrate 1 transversely to the main propagation direction of the substrate 1. The electrically conductive layer 2 serves as the first electrode of the

Photovoltaic module 40. On a side facing away from the substrate 1

Page 11 of the first electrode 2 is a photoactive absorber

3 arranged. On the surface of the absorber 3 facing away from the substrate 1, the further electrically conductive layer

4 arranged. The further electrically conductive layer 4 serves as a second electrode.

By way of example, the substrate 1 is flat glass, in the case of the first electrically conductive layer 2 it is a flat glass Front side electrode made of TCO (TCO = transparent conductive oxide layers, transparent conductive oxide layer) and the absorber 3 to a photoactive layer sequence with a sequence of p-doped, substantially intrinsic and n-doped amorphous or microcrystalline silicon. The first electrically conductive layer 2 and the photoactive

Layer sequence 3 and the other electrically conductive

Layer 4 are in consecutive

Vacuum coating processes applied without the substrate 1 has to be removed from the vacuum. It is also possible to start with a substrate 1 that is already provided with a TCO layer as the first electrically conductive layer 2. In this case, only the photoactive

Layer sequence 3 and the further electrically conductive layer 4 apply.

In accordance with embodiments, the first electrically conductive layer 2, which faces the sun during operation, is the first one

Electrode includes, for example Sn02, ZnO or ITO. The embodiments according to embodiments in the operation of the sun

remote second electrically conductive layer which forms the second electrode may also have a TCO layer or be formed by metals such as Ag, Al, No or combinations of TCO and a metal layer.

The absorber 3 typically comprises at least one p- and one n-doped semiconductor layer. In case of

Silicon-based thin-film photovoltaic cells are usually still separated by an extended substantially intrinsic (ie undoped) layer (I-layer) of the p- and n-doped layers. To make better use of the wavelength spectrum, several pin Layer sequences with different absorber spectra

be provided one above the other in the absorber 3. Such a silicon tandem cell has, for example, a pin layer sequence of amorphous silicon and a pin layer sequence of crystalline silicon. It can also be provided a further pin layer sequence of amorphous silicon germanium. In this case we speak of triple cells.

Typically, during operation of the photovoltaic module, the p-doped layer faces the sun. It is also possible that the n-doped layer faces the sun. As a growth substrate glass or a (metal) film is used. The substrate through which the

Sunlight is incident, when using a metal foil until the end of the manufacturing process on the module

laminated. The layer stack remains with the

Growth substrate connected.

As active semiconductor material for the absorber 3, amorphous or microcrystalline semiconductors of group 4, for

Example A-Si, A-SiGe, μΟ-Ξί, or compound semiconductors, such as CdTe or Cu (In, Ga) Se2 (short CIS or CIGS called) are used. Furthermore, the absorber may comprise organic material that is set up,

To convert radiant energy into electrical energy. In this case, layers of different materials mentioned can also be combined in the absorber 3. Furthermore, in the absorber 3 partially reflective layers (intermediate reflectors) of a conductive oxide and / or a

be provided conductive semiconductor layer.

The electrical insulation 30 is introduced into the second electrode 4 and the absorber. In other aspects, the Insulation 30 is introduced only in the second electrode 4. The electrical insulation 30 separates the second electrode 4 so that the two adjacent regions of the second electrode 4 on both sides of the electrical insulation 30 electrically

are separated from each other. In the exemplary embodiment shown, the electrical insulation 30 is a recess in the second electrode 4 and the absorber 3. The first electrode 2 is intact in the region of the electrical insulation 30.

Between the dividing line 31 and the electrical insulation 30 is an ohmic contact through the material connection

and / or alloy 33 is formed. The material compound and / or alloy 33 is generated in particular by irradiation of laser light of suitable wavelength from a range of, for example, 200 nm to 10 μm. As a result, the second electrode 4 and the photoactive layer sequence 3 are locally limited melted, but not evaporated. By

Diffusion processes in the melt form either a silicide, for example AgAISi with a quasi-metallic conductivity or a eutectic of Si and Ag, the

also has a high conductivity. As a result, electric current can flow from the second electrode 4 into the first electrode 2 at this point. For electrical coupling of the material connection and / or

Alloy 33 with the second electrode 44, the electrically conductive material 32 is applied to a side facing away from the absorber 3 10 of the second electrode 4. The electrically conductive material 32 is during the manufacture of

Photovoltaic module according to embodiments forms a viscous mass, such as a paste or ink. The electric

Conductive material 32 is capable of being applied by a printing process. The electrically conductive material 32 For example, it is applied with ink jet printing. According to further embodiments, this becomes electrical

conductive material 32 with mask technologies or with

Screen printing applied. The electrically conductive material 32 is different in shape from the material of the second electrode 4. For example, the electrically conductive material is Ag ink or Cu or Ni or Al ink. The dividing line 31 is filled according to embodiments with electrically insulating material 14. The electrically insulating material 14 is introduced into the dividing line 31, for example by a printing process. The dividing line 31 is

in particular a recess in the layer stack 9, which extends from the side 10 of the second electrode to the substrate 1.

By the electrically conductive material 32 and the

Material connection and / or alloy 33 is an ohmic contact between the second electrode 4 and the first

Electrode 2. The material compound and / or alloy 33 extends from the side 10 to the absorber facing side 11 of the first electrode 2. The arrows in the first electrode 2, the absorber 3 and the second electrode 4 symbolize the current flow and the

Series connection of segments 5 and 7.

Figure 4 shows a series circuit in the

Contacting regions 6 according to another

Execution form. The series connection corresponds to

Essentially the embodiment of Figure 3. Im

Difference to the embodiment of Figure 3 was on the formation of the material compound or alloy 33rd waived. For electrical contacting of the second

Electrode 4 of the segment 5 with the first electrode 2 of the segment 7, the electrically conductive material 32 is applied so that it is in the electrical insulation 30th

protrudes and with the side 10 of the first electrode 2, a common contact surface in a portion 12 of the

Insulation 30 has. Another subsection 13 of the

Insulation 30 adjacent to the segment 7 is free of electrically conductive material 32, so that the second

Electrode 4 of the segment 7 electrically from the second

Electrode 4 is separated in the contacting region 6 and 5 segment. By the electrically conductive material 32 is an ohmic contact between the second electrode 4 on the side facing the segment 5 of the parting line 31 and the first electrode 2 on the segment 7 facing side of

Dividing line 31. The drawn arrows in the first

Electrode 2, the absorber 3 and the second electrode 4 symbolize the current flow and the series connection of the segments 5 and 7.

Figure 5 shows a series connection in the

Contacting regions 6 according to another

The series connection according to FIG. 5 essentially corresponds to the exemplary embodiment of FIG. 3. In contrast to the exemplary embodiment of FIG. 3, the photovoltaic module 40 according to the exemplary embodiment of FIG. 5 has no electrically conductive material 32 and no separation line 31 in the contacting regions 6 that cuts through the entire layer stack 9.

A dividing line 34 for electrical insulation of the first electrode 2 is inserted into the first electrode 2, that the absorber 3 and the second electrode 4 on the Substrate 1 side facing away from the first electrode. 2

are intact. As a result, the electrical conductivity of the second electrode 4 above the dividing line 34 is maintained. For forming the separation line 34, laser radiation of a wavelength absorbed in the front side electrode, for example, 1064 nm, is introduced through the substrate 1. The power of the laser radiation and the processing time is chosen so that the first electrode 2 is locally heated and excited to recrystallization processes, without material being physically removed.

In contrast to the examples described in connection with Figures 3 and 4 is in the present

Embodiment of the separation line 34 material so not removed, but only in its properties, in particular its conductivity, changed. There will be no gap

educated. The reason for the reduction in the conductivity in the region of the dividing line 34 is that the conductivity of TCO layers is essentially attributable to dopants which are no longer incorporated in the crystal as a result of the recrystallization process. A possible second

Mechanism that leads to a reduction in conductivity is a mixing of the material of the first

Electrode 2 with the material of the overlying absorber 3. The oxygen of the TCO material of the first electrode 2 forms with the silicon of the absorber 3 electrically insulating silicon oxide (SiO or S1O2).

Outside the contacting regions 6, the dividing line 31, as explained in connection with FIGS. 1 to 4, is arranged, which completely cuts through the layer stack 9. The dividing line 31 and the dividing line 34 immediately adjoin one another and thus extend alternately linearly along along the entire length of the layer stack 9. The first electrode 2 is electrically interrupted over the entire length of the layer stack 9 by the dividing lines 31 and 34.

The photovoltaic module 40 according to the exemplary embodiment of FIG. 5 has in the contacting regions 6

silicon-containing material compounds and / or alloys 33 in the second electrode 4 and the absorber 3, which are electrically conductive. Furthermore, the

Photovoltaic module 40, the recrystallized or silicon oxide-containing separation line 34 in the first electrode 2. The series connection and the current flow are symbolized by the arrows.

The dividing line 34 can also without irradiation of

Laser radiation are formed. According to embodiments, the dividing line 34 is through the material of the photoactive

Absorbers 3 formed. For electrically insulating the first electrode 2 to the left and to the right of the dividing line 34, a recess in the region of the dividing line 34 is introduced into the first electrically conductive layer 2 before the photoactive absorber 3 is arranged on the first electrode 2. During the application of the photoactive absorber 3 to the first electrode 2, the material of the photoactive absorber 3 then settles in this recess and has an electrically insulating effect.

Regardless of the type of series connection in the

Contacting 6 is used to manufacture the

Fotovoltaikmoduls 40 first of the layer stack 9 completely deposited on the substrate. After the layer stack is completely applied, the segmentation of the Layer stack performed by the dividing line 31. The transection of the back contact by the electrical

Insulation 30 and forming the ohmic contacts

between the dividing line 31 and the electrical insulation for series connection, after the layer stack 9 has been completely separated.

The structuring takes place in particular by

Laser irradiation. For the production of the photovoltaic module 40, it is possible in a manufacturing plant the

Process steps for structuring the layers of the

Layer stack 9 summarize. This is the result

Manufacturing process more effective in terms of time, since fewer infeed and outfeed processes must be performed and

Structuring measures are summarized in a process header. This also leads to a cost savings, both in the manufacturing plants, as well as during production.

Also becomes less area for the manufacturing plants

needed. Additional purification steps between the individual coating processes can be dispensed with.

This can be dispensed with the necessary production facilities.

Due to the island-like patterning structure in the

Contact areas 6 are the dead zones, which can not contribute to the conversion of energy, compared to conventional modules in which the contacting areas elongated elongated over the entire length of the module run reduced. The module becomes, for example, the

Reduction of the series resistance over the entire length of the layer stack by the dividing line 31 isolated. Outside the contacting regions 6 in the regions 15, however, no series connection between the segments 5 and 6 is generated. The electrical insulation 31 has a width of approximately 20 to 40 μπι. As a result, as much as possible of the existing module surface for the conversion of the radiant energy in

used electrical energy and thus that is

Photovoltaic module 40 effectively. For series connection of

Segments 5 and 7 enter regions 15, respectively

Contacting formed 6, which is limited locally. For this purpose, the non-linear, U-shaped insulation 30 is attached to the linear separation line 31, which together with the

Dividing line 31 includes a plurality of spaced apart islands for series connection. In these islands, the ohmic contact is formed for series connection. In each case two of the immediately adjacent regions 15 have a distance of approximately 1 mm to 100 mm from each other. Thus, the high efficiency of the photovoltaic module 40 through

Reduction of the dead zone to quasi the dividing line 31 achieved.

Claims

claims

A photovoltaic module having a plurality of electrically series connected segments (5, 7), comprising:

a layer stack (9) arranged on a substrate (1) with:

a first electrode (2) arranged on the substrate, a photoactive absorber (3) arranged thereon,

a second electrode (4) arranged thereon,

a dividing line (31) which interrupts the layer stack (9) to form the segments (5, 7),

- A plurality of contacting areas (6), the

spaced apart along the dividing line (31)

are arranged and each have:

an electrical insulation (30) of the second electrode (4),

a contact (32, 33), via which the second electrode (4) is electrically coupled to the first electrode (2) for series connection of the segments (5, 7),

- An electrically conductive material (32) on the absorber (3) facing away from side (10) of the second electrode (4) is applied for electrically bridging the parting line.

2. Photovoltaic module according to claim 1, wherein the electrically conductive material (32) in a region (12) of the

electrical insulation (30) on the side facing away from the substrate (11) of the first electrode (2) is applied, so that the second electrode (4) by means of the electrically conductive material (32) with the first electrode (2) is electrically coupled.

3. Photovoltaic module according to claim 2, wherein the first

Electrode (2) in a further region (13) of the parting line is free of the electrically conductive material (32).

4. Photovoltaic module according to claim 1, wherein the contacting a conductive material connection (33).

and / or a conductive alloy (33) of elements of the photoactive absorber (3) and the second electrode (4).

5. Photovoltaic module according to one of claims 1 to 4, wherein the separating line (31) with an electrically insulating

Material (14) is filled.

6. Photovoltaic module according to one of claims 1 to 5, wherein the electrical insulation (30) interrupts the second electrode (4) and the photoactive absorber (3).

7. Photovoltaic module according to one of claims 1 to 6, wherein the separating line (31) the layer stack (9) linearly completely along the entire length of the layer stack (9)

interrupts.

a layer stack (9) arranged on a substrate (1) with:

a second electrode (4) arranged thereon,

a dividing line (31) which intersects the layer stack (9) in regions to form the segments (5, 7),

- A plurality of contacting areas (6), the

spaced apart along the dividing line (31)

are arranged and each have:

an electrical insulation (30) of the second electrode (4), - A contact (32, 33), via which the second electrode (4) is electrically coupled to the first electrode (2) for series connection of the segments (5, 7), wherein

- The first electrode (2) in the contacting regions (6) is interrupted in each case by a further separating line (34) and the first electrode (2) in the region of the other

Separation line (34) locally different physical properties, than outside the further dividing line (34), wherein the locally different physical properties in the region of the further dividing line (34) on a change in the doping after recrystallization of the first electrode (2) in the another parting line (34) and / or on a

Formation of an oxide of an element from the first

Electrode (2) adjacent photoactive absorber (3) in

Area of the further dividing line (34) is based, and wherein

- The second electrode (4) in the contacting regions (6) in each case above the further parting line (34) extends continuously.

9. Method for producing a photovoltaic module,

full :

- Providing a layer stack (9) on a substrate (1) with:

a first electrode (2) arranged thereon,

a photoactive absorber (3) arranged thereon,

- a second electrode (4) arranged thereon;

following

Segmenting the module by a dividing line (31),

segmental severing (30) of the back contact (4) in a plurality of regions (15) along the parting line

(31) are arranged, spaced from the dividing line (31), - forming a plurality of ohmic contacts respectively between the first electrode (2) and the second electrode (4) in areas between the dividing line (31) and the

divisional division (30).

10. The method of claim 9, comprising:

- Forming the ohmic contact by laser irradiation, so that an electrically conductive material compound (33) of material of the second electrode (4) and the absorber (3) is formed.

A method according to claim 9 or 10, comprising:

- Applying electrically conductive material (32) on a side facing away from the absorber (3) (10) of the second electrode (4).

12. The method according to any one of claims 9 to 11, comprising:

- Applying electrically conductive material (32) in a region (12) of the electrical insulation (30) on a side facing away from the substrate (1) (11) of the first electrode (2) to the second electrode (4) by means of the electrically conductive material (32) to be electrically coupled to the first electrode (2).

13. The method according to any one of claims 11 or 12, wherein the electrically conductive material (32) by a

Printing process is applied.

14. The method according to any one of claims 11 to 13, wherein the electrically conductive material (32) is applied so that the side (11) of the first electrode (2) in a further region (13) of the electrical insulation (30) free from the electrically conductive material (32) remains.

15. Manufacturing plant, which is designed for producing a photovoltaic module according to a method according to one of claims 9 to 14.