WO2020114807A1 - Solar cell string, solar module and method for producing a solar cell string - Google Patents

Abstract

The invention relates to a solar cell string (1), comprising a connector (5), which is electrically connected to the contact of a solar cell (3) and to the additional contact of an additional solar cell (4). The connector (5) comprises a first connector portion (51), which is arranged adjacent to the solar cell (3), a second connector portion (52), which is arranged adjacent to the additional solar cell (4), and a third connector portion (53), which extends between the solar cell (3) and the additional solar cell (4) and connects the first connector portion (51) to the second connector portion (52). The first connector portion (51) and/or the second connector portion (52) has a cross section having a first aspect ratio, and the third connector portion (53) has a cross section having a second aspect ratio, which is less than the first aspect ratio. The invention also relates to a corresponding method for producing the solar cell string (1), in which method the third connector portion (53) is deformed in such a way that the third connection portion (53) has a cross section having the second aspect ratio, which is less than the first aspect ratio.

Description

Solar cell string, solar module and method for producing a

Solar cell strings

Description:

The invention relates to a solar cell string, a solar module and a method for producing a solar cell string. In particular, the invention relates to a solar cell string which comprises a plurality of solar cells which are electrically connected to one another, a solar module which comprises such a solar cell string, and a method for producing the solar cell string in which the plurality of solar cells are electrically connected to one another.

In contrast to thin-film solar modules, in the manufacture of which a monolithic connection of the individual solar cells to form a solar module can be realized, wafer solar cells are usually in a hybrid

Structure electrically connected to one another via metallic connectors, for example in the form of solder strips. A plurality of solar cells interconnected in this way in a row are usually referred to as a solar cell string, with a plurality of strings arranged side by side being electrically coupled to one another to form a solar module.

Such a solar cell string comprises a solar cell formed from one

Wafer substrate with a contact, for example in the form of a flat electrode contact section such as a busbar, a further solar cell arranged adjacent to the solar cell, formed from a further wafer substrate with a further contact and at least one along one

Extension direction from the contact of the solar cell to the further contact of the further solar cell extending connector. The connector is usually band-shaped and has a connector width and a connector height. The connector height and the connector width extend perpendicular to a connector length, which extends in an extension direction, along which adjacent solar cells are arranged, which are interconnected by means of the connector. 2 shows a solar cell string according to the prior art. The

Solar cell string (not shown) has a solar cell 3 with a contact (not shown), a further solar cell 4 with a further contact (not shown), which are electrically connected to one another via a connector 5.

The solar cell 3 has a material unit 31 that is positively doped on one side and a material unit 32 that is doped negatively on one side for forming a p-n junction, and the further solar cell 4 has a further material unit 41 that is positively doped on one side and another negatively doped on one side

Material unit 32 for forming a further p-n transition.

The connector 5 extends with its connector length (not shown) along an extension direction E, along which the solar cells 3, 4 are arranged adjacent to one another. The connector 5 has a first connector section 51, which is arranged adjacent in particular below the solar cell 3, a second connector section 52, which is arranged adjacent in particular above the further solar cell 4, and a third connector section 53, which is located between the solar cell 3 and the 4 extends and connects the first connector section 51 to the second connector section 52. The third connector section 53 is therefore an intermediate section between the first connector section 52 and the second connector section 52.

The connector 5 is designed as a round wire connector, so that the

Connector sections 51, 52, 53 all have a circular cross section and the same connector width and height, each extending perpendicular to the direction of extension. The connector sections 51, 52, 53 are integrally formed and all have the same cross section.

The connector 5 connects the positively doped in the solar cell 3

Material unit 31 with the further negatively doped material unit 42 of the further solar cell 4 for generating the series-connected solar cell string 1. The connector 5 contacts a light-facing front side (not shown) of the solar cell 3 with a light-facing one

Rear side (not shown) of the further solar cell 4. A geometric jump of a defined height is created in an intermediate space between the solar cells 3, 4, which is also referred to below as the jump height.

Typically, connectors with a copper core and an outer coating of a solderable tin alloy are used for the electrical connection with the contact of the solar cell or the further contact of the further solar cell. However, connectors with other metallic or non-metallic conductive base materials and coatings are also conceivable (e.g. aluminum, conductive plastics, carbon fiber, etc.). Due to the material used, connectors are opaque and inevitably lead to shading effects on the active solar cell surface facing the light and thus to loss of light output in the solar module. Connectors of different shapes are used in the photovoltaic industry. Flat wire connectors and round wire connectors are known. Flat wire connectors have a rectangular cross section, while round wire connectors have a circular cross section.

Flat wire connectors have a comparatively higher shading on the active solar cell surface, lead to a high one

Material cross-section in the conductor at comparatively low ohmic

Loss of material resistance, however, at the same time lead to comparatively small geometric jumps in overlap areas in which the

Connector is arranged in a space between the adjacent solar cells. The low jump height results in lower mechanical loads.

Round wire connectors offer the advantage of an optimized

Light reflection angle for returning light rays actually reflected by the connector via total reflection at a glass-encapsulation interface back to the active solar cell surface, which increases

Performances / efficiencies can be achieved in the solar module. However, it is in the nature of geometry that round cross sections with the same area have a larger diameter than the height of a rectangle of the same width. This increases the problem of the introduced mechanical stress due to the geometric jump in the spaces between the solar cells, since this in turn results from the addition of a height of the

Solar cells and the connector height. In addition own

Round wire connectors have higher moments of inertia and are therefore significantly more resistant to bending than the flat wire connectors, especially when combined with higher yield strengths in the material due to the manufacturing process. This construct therefore leads to increased mechanical stress inputs on the solar cells in the overlap areas. Forces caused by the bending of the connectors are transferred to the edges of the brittle-refracting silicon crystal of the solar cell.

All of the correlations shown result in a problem between optimal light output including electrical loss minimization on the one hand and the mechanical problem of the geometry jump in

Interplay with the brittle and fragile material properties of silicon solar cells on the other hand.

It is an object of the invention to provide a solar cell string, a solar module and a method for producing the solar cell string with which the above problems are overcome or at least minimized.

According to the invention, this problem is solved by a solar cell string with the features of claim 1, a solar module with the features of claim 5 and a method with the features of claim 6. Advantageous refinements and developments of the invention result from the subclaims explained below.

The invention relates to a solar cell string comprising a solar cell with a contact, a further solar cell with a further contact and a Has connector which is electrically connected to the contact of the solar cell and to the further contact of the further solar cell, so that the connector forms an electrical connection between the contact and the further contact. The connector has a first connector section which is arranged adjacent to the solar cell, a second connector section which

is arranged adjacent to the further solar cell, and a third

Connector portion that extends between the solar cell and the other solar cell and connects the first connector portion with the second connector portion. The first connector section and / or the second connector section each have a cross section with a first aspect ratio and the third connector section has a cross section with a second aspect ratio that is smaller than the first

Aspect ratio.

In the solar cell string according to the invention, local mechanical stress inputs from the connector into the solar cell are particularly good

Overlap area, i.e. in the space between the solar cells, reduced without hindering an electrical flow through the connector and thus at the same time the optical and electrical advantages of a connector with a relatively high aspect ratio on the majority of the active solar cell area

maintain. Furthermore, this is local at the overlap areas

Aspect ratio of the connector is reduced so that the area moment of inertia is reduced in the bending direction in order to minimize the mechanical stresses in this area. This reduces the rigidity, above all by reducing the moment of inertia in the bending direction. In addition, a relatively small distance between the solar cell and the further solar cell can be realized, so that smaller solar modules are produced and materials can be saved. Increased area efficiency of the solar modules is achieved.

The solar cell string according to the invention has a comparatively low cell rupture behavior, a comparatively high production yield due to comparatively little rework and rejects, and an increased rate Longevity of the solar cell string and of the solar module having the solar cell string and a comparatively low complaint rate. Furthermore, the solar cell string in the solar module has a comparatively high module performance class or area efficiency in the solar module, because a comparatively small distance between the solar cell and the further solar cell can be realized and a connector with a comparatively low shading can be used on the active solar cell surface. The

Solar cell string is still inexpensive. In addition, there is comparatively little transport damage when transporting the solar cell string or

Expected solar module.

The connector extends in the extension direction from one solar cell to another solar cell, and has a connector width and one

Connector height to. The connector height extends perpendicular to

Extension direction of the connector and perpendicular to the solar cell surface, and the connector width extends parallel to the solar cell surface, thus perpendicular to the connector height and the direction of extension. The

The direction of extension, connector height and connector width therefore form a Cartesian coordinate system in which the connector width is an x-axis, the direction of extension is a y-axis and the connector height is a z-axis. The aspect ratio is calculated from the connector height divided by the connector width. The cross section that defines the aspect ratio is a cross section of the connector and extends along the x-z axis in the definition used herein.

The first and second connector sections each preferably have a connector height that is greater than the connector height of the third

Connector section. The first and second connector sections each preferably have a connector width that is smaller than that

Connector width of the third connector section.

In a preferred embodiment, a first area of the first connector section is the same or substantially the same as a second Area of the second connector section and / or to a third area of the third connector section. In other words, the first connector section has a cross section with a first surface area that is greater than one or both of the surface areas of the cross sections of the other two connector sections. The first, the second and the third area are preferably the same or substantially the same. This means there are no electrical losses in the connector.

The cross section of the first connector section and of the second connector section are preferably each rectangular, oval or circular. That is, these connector sections are formed as a flat or round wire, the advantages of which are described above. The cross section of the first connector section and of the second connector section is more preferably each circular. The advantages of round wire connectors that

described above can thus be used in the first and second

Connector sections are maintained on much of the active solar cell surface because their geometry is the same or substantially the same as the round wire connectors. While the connector width of flat wire connectors to an almost 100% shading that is below the

Active solar cell surface located connector is the

Shading effect of a round wire connector due to its width significantly less, in the range of about 35%, due to its reduced overall width compared to the flat wire connector and an internal reflection in the

Solar panel. Round wire connectors offer the advantage of optimized

Light reflection angle for returning light rays actually reflected by the connector via total reflection at the glass-encapsulation interface back to the active solar cell surface, thus increasing

Achievements / efficiencies can be achieved.

In a preferred embodiment, the third connector section extending between the solar cell and the further solar cell furthermore has a transition region adjacent to the solar cell and / or the further solar cell. The transition area is an area of the third Connector section in which it connects to the first and the second

The connector section merges in such a way that it runs in the solar cell edge region above or below the solar cell or the further solar cell. This can further reduce a jump height because the

Jump height from the height of the solar cells and the connector height in the

Summed solar cell edge area.

In the sense of the invention, the term “adjacent” is to be understood in such a way that the first or the second connector section is arranged below or above the solar cell, with one possibly being located

Intermediate layer, for example, a busbar can be located between the respective solar cell and the respective connector section. The expression

“Adjacent” is to be understood in such a way that the third connector section is arranged below or above the solar cell, with it resting or not resting on it. The transition area also includes an area in which the third connector section merges into the first and second connector sections and vice versa. The first, second and third connector sections are preferably integrally formed. As a result, there may be transition regions between the first or connecting section and the third connecting section which have different cross sections and / or different aspect ratios

exhibit.

In a preferred embodiment, the first aspect ratio is in the range from 0.8 mm to 1.2 mm and the second aspect ratio is in

Range from 0.8 mm to 1.2 mm. The first connector section preferably has a connector height in the range from 0.15 mm to 0.45 mm and one

Connector width in the range of 0.15 mm to 0.45 mm. The second connector section preferably has a connector height in the range from 0.15 mm to 0.45 mm and a connector width in the range from 0.15 mm to 0.45 mm.

The third connector section preferably has a connector height in the range from 0.05 mm to 0.25 mm and a connector width in the range from 0.2 mm to 0.7 mm. A distance between the solar cell and the further solar cell is preferably in the range from 0 mm to 5.5 mm. Preferably one is Jump height in the range from 0.25 mm to 0.45 mm, the jump height representing a height which the connector has to overcome in order to electrically connect the solar cell to the further solar cell and which extends parallel to the connector height.

The invention further relates to a solar module which has a solar cell string according to one or more of the embodiments described above. The solar module has the solar cell string with the advantages described above.

The invention further relates to a method for producing a

Solar cell strings with a solar cell and a further solar cell, which are electrically connected to one another by means of a connector having a first connector section, a second connector section and a third connector section, comprising the following steps:

a) connecting the first connector section to a contact of the solar cell, which has a cross section with a first aspect ratio, b) connecting the second connector section to a contact of the further solar cell, which has a cross section with the first aspect ratio, and

c) deforming the third connector section such that the third

Connecting section has a cross section with a second aspect ratio, which is smaller than the first aspect ratio.

This is a simple and inexpensive method by means of which a solar cell string is produced with the advantages described above. All three connector sections are made of the same starting material, only the third connector section is deformed. As a result, break points at connection points are avoided in contrast to a method in which the connector sections are connected to one another.

The connector is preferably integrally formed, and the third

Connector section is preferred in step c) by a local one Forming the connector to influence its aspect ratio.

Steps a) and b) are preferably carried out after step c). Step c) is preferred using rollers, rollers or stamping units after a step of unrolling the connector

carried out. This process step can easily be integrated into a production machine in the form of an automatic soldering machine. Process step c) can therefore be embedded directly in a process for realizing steps a) and b). Alternatively, step c) is preferably carried out using rollers, rollers or stamping units before a step of rolling up the connector on transport rollers, coils or spools.

Alternatively, steps a) and b) are preferably carried out before step c). Alternatively or additionally, steps a) and b) are carried out simultaneously with step c). This leads to a

Time saving.

In a preferred embodiment, step c) deforming the third connector section comprises flattening the third connector section. The flattening can easily be realized by the rollers or stamp units described above.

Exemplary embodiments of the invention are shown purely schematically in the drawings and are described in more detail below. It shows schematically and not to scale:

1 is a partial perspective view of a solar module according to the invention; 2 shows a partial cross-sectional view of a solar cell string according to the prior art;

3 is cross-sectional views of connector portions of the connector shown in FIG. 1;

Figure 4 is a partial perspective view of the connector shown in Figure 1; 5 shows a method step of the method according to the invention for

Manufacture of the connector shown in Fig. 4;

6a and 6b cross-sectional views of a solar cell string according to the state of the

Technology (Fig. 6a) and according to the invention (Fig. 6b); and

Fig. 7 is a plan view of the solar cell string shown in Fig. 6b.

Fig. 1 shows a partial perspective view of an inventive

Solar panel. The solar module has a solar cell matrix 2, the two

Has solar cell strings 1. The solar cell strings 1 have several

Solar cells, for example, a solar cell 3 and a further solar cell 4, which are electrically connected to one another by means of a connector 5, which extends along an extension direction E. A detailed partial view is shown in Fig. 6b.

2 shows a partial cross-sectional view of a solar cell string according to the prior art and has already been described above.

3 shows cross-sectional views of connector portions of the connector shown in FIG. 1. Shown are a cross section of the first and second connector sections 51 and 52, which are identical, and a cross section of the third connector section 53. The cross section of the first and second connector sections 51 and 52 is circular and has a first connector height H1, a first connector width B1 and a first

Area A1 on. The cross section of the third connector section 53 has a second connector height H2, a second connector width B2 and a second area A2. The first connector width B1 is smaller than the second connector width B2. The first connector height H1 is greater than the second connector height H2. As a result, the first aspect ratio, which is made up of H1 divided by B1, i.e. H1 / B1 is greater than the second aspect ratio, which is made up of H2 divided by B2, i.e. H2 / B2 results. The first area A1 is equal to the second area A2. The first and second connector widths B1, B2, the first and second connector heights H1, H2 and one

Extension direction (not shown) of the connector (not shown) form one Cartesian coordinate system in which the first and second connector widths B1, B2 extend along an x-axis, the first and second

Connector width H1, H2 extend along a z-axis and the

Extension direction (not shown) extends along a y-axis.

Figure 4 shows a partial perspective view of the connector shown in Figure 1. The connector 5 extends along the extension direction E and has the first connector section 51, the second connector section 52 and the third connector section 53, which is arranged between the first connector section 51 and the second connector section 52. The first

Connector section 51 and the second connector section 52 have a circular cross section and are formed in the form of a round wire. The third connector portion 53 is flattened compared to the first connector portion 51 and the second connector portion 52. That is, the third connector portion 53 has a connector width (not shown) that is larger, a connector width (not shown) of the first connector portion 51 and the second connector portion 52, and a connector height (not shown) that is smaller than a connector height ( of the first connector section 51 and the second connector section 52, as shown in FIG. 3. The connector 5 is formed from a single raw material, i.e. the connector sections 51, 52, 53 are integrally formed.

FIG. 5 shows a method step of the method according to the invention for producing the connector shown in FIG. 4. Fig. 5 shows the

Method step of deforming the third connector section 53 such that the third connection section 53 has a cross section with a second aspect ratio which is smaller than a first aspect ratio of a cross section of the first connector section or the second

Connector section 52. The third connector section 52 is pressed flat by means of rollers 6. 6a and 6b show cross-sectional views of a solar cell string according to the prior art (FIG. 6a) and a solar cell string according to the invention (FIG. 6b).

The solar cell string 1 shown in FIG. 6a corresponds to the solar cell string 1 shown in FIG. 2 with the difference that a distance D1 between the solar cell 3 and the further solar cell 4 and a jump height SH1 are visualized, the jump height SH1 representing a height that the connector 5 must be overcome in order to electrically interconnect the solar cell 3 with the further solar cell 4. The jump height SH1 is obtained by adding a solar cell height (not shown) and the connector height (not shown).

The solar cell string 1 shown in FIG. 6b corresponds to the solar cell string shown in FIG. 6a with the difference that it has the connector 5 shown in FIG. 4 instead of a round wire connector 5. The connector 5 has the first connector portion 51 and the second connector portion 52, which correspond to the connector portions 51, 52 shown in FIG. 6a. The connector 5, however, has the third connector section 53, which in the

Contrary to the third connector portion 53 shown in Fig. 6a and the first and second connector portions 51 and 52 has a smaller second aspect ratio because it is circular compared to them

Cross sections is pressed flat.

The connector portion 53 extends between the first

Connector portion 51 and the second connector portion 52 and connects them. The first connector section 51 and the second connector section 52 are arranged adjacent to the solar cell 3 and the further solar cell 4. The connector section 53 is arranged between the solar cells 3, 4 and each has a transition region 7, in which it is arranged adjacent to the solar cell 3, 4. In the transition region 7, the connector section 53 is arranged below the solar cell 3 or above the further solar cell 4, and may or may not touch the latter. Due to the lower connector height (not shown) in the transition area 7, there is a jump height SH2 is smaller than the jump height SH1 shown in FIG. 6a and a distance D2 between the solar cell 3 and the further solar cell 4 is smaller than the distance D1 shown in FIG. 6a. FIG. 7 shows a top view of the solar cell string shown in FIG. 6b. The first connector section (not shown) and the second connector section 52 are formed as a round wire, so that the solar cell string 1 on a large part of the active solar cell surface of the solar cells 3, 4

Vebinder sections 52 having a circular cross section. The third connector section 53 is locally deformed compared to the circular cross section of the second connector section 52, so that its second aspect ratio is smaller than the first aspect ratio of the

Connector section 52.

Reference symbol list:

A1 area

A1 area

B1 first width

B1 second width

D1 first distance between solar cells

D2 second distance between solar cells

E Extension direction

H1 first height

H1 second height

SH1 first jump height

SH2 second jump height

1 solar cell string

2 solar cell matrix

3 solar cells

31 positively endowed material unit

32 negatively doped material unit

4 more solar cells

41 further positively endowed material units

42 further negatively endowed material units

5 connectors

51 first connector section

52 second connector section

53 third connector section

6 roll

7 transition area

Claims

Claims:

1. Solar cell string (1), having

- a solar cell (3) with a contact,

a further solar cell (4) with a further contact,

a connector (5) which is electrically connected to the contact of the solar cell (3) and to the further contact of the further solar cell (4), so that the connector (5) forms an electrical connection between the contact and the further contact, wherein the connector (5) has a first connector section (51) which is arranged adjacent to the solar cell (3), a second connector section

(52), which is arranged adjacent to the further solar cell (4), and has a third connector section (53) which extends between the solar cell (3) and the further solar cell (4) and the first connector section (51) with the second Connects connector section (52), wherein the first connector section (51) and / or the second connector section (52) each have a cross section with a first aspect ratio and the third connector section

(53) has a cross section with a second aspect ratio that is smaller than the first aspect ratio.

2. Solar cell string (1) according to claim 1, characterized in that a first surface area (A1) of the first connector section (51) is identical or substantially identical to a second surface area (A2) of the second connector section (52) and / or to a third Area (A2) of the third connector section (53).

3. Solar cell string (1) according to claim 1 or 2, characterized in that the cross section of the first connector section (51) and the second connector section (52) each rectangular, oval or

is circular. 4. Solar cell string (1) according to one of the preceding claims, characterized in that the third connector section (53) extending between the solar cell (3) and the further solar cell further a transition region (7) adjacent to the solar cell (3) and / or the further solar cell (4).

5. Solar module, comprising a solar cell string (1) according to one of the

preceding claims.

6. Process for producing a solar cell string (1) with a

Solar cell (3) and another solar cell (4), which by means of a

Connector (5) are electrically connected to one another, which has a first connector section (51), a second connector section (52) and a third connector section (53), comprising the following steps:

a) connecting the first connector section (51) with a contact of the solar cell (3), which has a cross section with a first

Has aspect ratio,

b) connecting the second connector section (52) to a contact of the further solar cell (4), which has a cross section with the first aspect ratio, and

c) deforming the third connector section (53) such that the

third connecting section (53) has a cross section with a second aspect ratio that is smaller than the first aspect ratio.

7. The method according to claim 6, characterized in that steps a) and b) are carried out after step c).

8. The method according to claim 6, characterized in that steps a) and b) are carried out before and / or simultaneously with step c). 9. The method according to claim 7, characterized in that step c) is carried out using rollers (6), rollers or stamping units after a step of unrolling the connector (5).

10. The method according to claim 7, characterized in that step c) using rollers (6), rollers or stamping units before a step of rolling up the connector

Transport rolls / coils / coils is carried out.

11. The method according to any one of claims 6 to 10, characterized in that the deformation of the third connector section (53)

Flattening the third connector portion (53).