DE102014103437A1 - Solar cell module and method of manufacturing a solar cell module - Google Patents

Abstract

The invention relates to a solar cell module, comprising: at least one solar cell having a front side and a rear side opposite the front side, wherein a connection layer for integrally bonding the solar cell to a cell connector is applied to at least one of the front side and the rear side, a cell connector having a cell connector Upper side and a lower side opposite the upper side, - wherein at least one of the upper side and the lower side is provided with a light catching structure, - at least one of the upper side and the lower side is unbelotiert, - the unbelotete side of the cell connector is arranged on the connecting layer of the solar cell, so that the unbelotete side of the cell connector is integrally connected by means of the bonding layer with the solar cell. The invention further relates to a method for producing a solar cell module.

Description

The invention relates to a solar cell module and a method for producing a solar cell module.

From the patent DE 10 2010 016 814 B3 For example, a method and apparatus for applying solder to a workpiece, such as a solar cell, is known. In this case, for example, a solder material is applied to the solar cell. On the applied solder material, for example, electrical contacts can be soldered. The electrical contacts may be cell connectors, for example.

Such cell connectors can according to the published patent DE 11 2006 003 262 T5 consist of a tinned copper flat wire. Such a flat wire is therefore completely surrounded by a solder material as a rule.

The object underlying the invention can be seen to provide a solar cell module.

The object on which the invention is based can furthermore be seen in providing a method for producing a solar cell module.

These objects are achieved by means of the subject matter of the independent claims. Advantageous embodiments are the subject of each dependent subclaims.

• – zumindest eine Solarzelle mit einer Vorderseite und einer der Vorderseite gegenüberliegenden Rückseite,
• – wobei eine Verbindungsschicht zum stoffschlüssigen Verbinden der Solarzelle mit einem Zellverbinder auf zumindest einer der Vorderseite und der Rückseite aufgebracht ist,
• – einen Zellverbinder mit einer Oberseite und einer der Oberseite gegenüberliegenden Unterseite,
• – wobei zumindest eine der beiden Seiten (also Oberseite und/oder Unterseite) des Zellverbinders unbelotet ist,
• – wobei die unbelotete Seite des Zellverbinders auf der Verbindungsschicht der Solarzelle angeordnet ist, so dass die unbelotete Seite des Zellverbinders mittels der Verbindungsschicht stoffschlüssig mit der Solarzelle verbunden ist.

In one aspect, there is provided a solar cell module comprising:

• At least one solar cell having a front side and a rear side opposite the front side,
• Wherein a connecting layer for integrally bonding the solar cell with a cell connector is applied to at least one of the front side and the back side,
• A cell connector having an upper side and a lower side opposite the upper side,
• - Wherein at least one of the two sides (ie top and / or bottom) of the cell connector is unattenuated,
• - Wherein the unbelotete side of the cell connector is arranged on the connecting layer of the solar cell, so that the unbelotete side of the cell connector is connected by means of the bonding layer materially connected to the solar cell.

• – Bereitstellen zumindest einer Solarzelle mit einer Vorderseite und einer der Vorderseite gegenüberliegenden Rückseite,
• – Aufbringen einer Verbindungsschicht zum stoffschlüssigen Verbinden der Solarzelle mit einem Zellverbinder auf zumindest eine der Vorderseite und der Rückseite,
• – Bereitstellen eines Zellverbinders mit einer Oberseite und einer der Oberseite gegenüberliegenden Unterseite, wobei zumindest eine der Oberseite und der Unterseite unbelotet ist,
• – Anordnen der unbeloteten Seite des Zellverbinders auf die Verbindungsschicht der Solarzelle,
• – mittels der Verbindungsschicht stoffschlüssiges Verbinden der unbeloteten Seite des Zellverbinders mit der Solarzelle.

According to a further aspect, a method for producing a solar cell module, in particular the solar cell module according to the invention, is provided, comprising the following steps:

• Providing at least one solar cell with a front side and a rear side opposite the front side,
• Applying a bonding layer for bonding the solar cell with a cell connector to at least one of the front side and the back side,
• Providing a cell connector having an upper side and a lower side opposite the upper side, wherein at least one of the upper side and the lower side is unbelot,
• Arranging the unbelotierten side of the cell connector on the connection layer of the solar cell,
• - By means of the bonding layer cohesively connecting the unbeloteten side of the cell connector with the solar cell.

In particular, the invention therefore encompasses the idea of using a cell connector which has at least one non-soldered side. In order to still connect this cell connector with a solar cell, the invention provides that the solar cell has a connecting layer for cohesive bonding. This means, in particular, that the cell connector no longer has to be completely encased or encapsulated with a solder material in order to connect the cell connector to the solar cell. Because the solar cell itself brings with it a necessary connection layer. In a known cell connector, which is completely covered with a solder material, there are areas that are not directly connected to the solar cell via the solder material. The solder material of these non-connected areas thus remains unused. By using a cell connector with at least one unloaded side, soldering material can thus advantageously be saved.

Even in the case of cell connectors which are only selectively soldered on an upper side or a lower side, that is to say not continuously soldered, there is generally the problem of an exact positioning of the solar cell on the selectively soldered regions of the cell connector. This is especially a problem in an industrial manufacturing plant for solar cell modules in which cell connectors can typically be several meters to kilometers long. In a production line of such a production plant, positioning errors of the solar cells can occur on such long cell connectors. This can usually lead to a committee or to a waste. Selective belotet here means in particular that a top and / or bottom of the cell connector are not continuous, so completely, are soldered, but only in some areas. The solar cells must be positioned by soldering to these soldered areas for connection. This is difficult and technical consuming. Usually this positioning errors can occur.

Such known positioning errors can not give it by means of the invention in an advantageous manner. For the cell connector does not have any selectively soldered areas on its unbottled side, on which the solar cells would have to be positioned exactly for the purpose of a material connection. The solar cells bring here their own connection layer for a cohesive connection, so that any positioning of the solar cell on the cell connector is possible.

The term "unbelottled" in the sense of the present invention means in particular that no solder is present. The term "unbelotet" is thus synonymous with the phrase "lot-free".

By the phrase "at least one or one of the front and back" is meant in particular only the front or only the back or both the front and the back.

By the phrase "at least one or one of the top and bottom" is meant in particular only the top or only the bottom or both the top and bottom.

The connection layer on the respective front side (the rear side is always to be read in the following) is applied or in particular comprises the case where the connection layer is applied directly or directly on the front side or the front side, ie without an intermediate layer, for example , In particular, the case is also included that the connection layer is applied indirectly or indirectly on the front side or the front side, respectively, so for example between the front side and the connection layer an antireflection layer and / or a front side contact structure can be provided. The above statements apply analogously to the back. For example, a back-side contact structure may be provided between the rear side and the connection layer.

A solar cell according to the present invention has in particular a wafer, in particular a silicon wafer. In such a wafer, two regions with different conductivities or dopings are preferably formed. Between these two regions, which can also be referred to as the base and emitter, there is usually a p-n junction. The front side of the solar cell in the sense of the present invention is in particular the side of the solar cell, which is located closest to the emitter relative to the base. The base is thus arranged in particular the rear side of the solar cell closest relative to the emitter. As a rule, light, in particular solar radiation, is incident through the emitter. The front side may be referred to in particular as a light entry side.

In one embodiment, a plurality of interconnect layers may be provided, each applied to the front or back, or both front and back, and applied to the front or back, or both front and back become. Depending on the number of connection layers, it is possible to provide a plurality of cell connectors.

According to one embodiment, the solar cell comprises a front-side contact structure, which may also be referred to as emitter contact structure, wherein the front-side contact structure preferably comprises a grid-like arrangement of linear metallic contact elements, which may also be referred to as contact fingers. Furthermore, metal busbars extending transversely to the contact fingers and having a greater width are preferably provided, which can be referred to as busbars, for example.

According to one embodiment, the solar cell comprises a rear-side contact structure, which may be referred to in particular as a base contact structure, wherein the rear-side contact structure preferably has a flat metallic layer, on which, for example, metal rear contact elements are arranged. Cell connectors are preferably connected to the front-side busbars and the rear-side contact elements.

In one embodiment, three or more or less than three busbars may be provided.

In one embodiment it can be provided that connection layers are provided or arranged perpendicular to the cell connectors on the front side and / or on the back side of the solar cell.

According to one embodiment it can be provided that a connecting layer is applied in each case on the front side and on the rear side of the solar cell and that the cell connector is unbolted on both sides.

By providing a two-sided unbalanced cell connector can be even more material be saved. For in this embodiment, both sides (front and back) of the solar cell are provided with their own connection layer in order to connect one cell connector to the solar cell in a materially bonded manner. The cell connector can thus be cohesively connected to the front or the back respectively. Preferably, a plurality of cell connectors are provided, which are respectively applied to the front side and the rear side and connected in a material-locking manner to the solar cell by means of the corresponding connection layer.

According to a further embodiment it can be provided that at least one unloaded side of the cell connector has a light reflection layer. This light reflection layer may, for example, reflect between 50 to 95% in the wavelength range of 300 to 1200 nm and consists for example of silver, aluminum or tin or may comprise, for example, one or more of the aforementioned materials. The light reflection layer can also be generally referred to simply as a reflection layer.

Such a light reflection layer advantageously reflects incident light away from the solar cell. As a rule, this reflected light is reflected back toward the solar cell by a solar cell encapsulation which covers or at least partly encapsulates the solar cell, so that at least part of the originally irradiated light can enter the solar cell and generate corresponding charge carriers there. As a rule, the solar cell encapsulation has a boundary layer with an environment of the solar cell. At this boundary layer, the light reflected by the light reflection layer is reflected back toward the solar cell. In particular, a total reflection can be provided at the boundary layer.

According to one embodiment, the solar cell module comprises such a solar cell encapsulation detailed above. This is applied in particular on the light entry side, in particular the front side. The solar cell encapsulation may also be referred to simply as encapsulation.

In a further embodiment it can be provided that the light reflection layer has a plurality of mutually inclined reflection surfaces. These inclined reflection surfaces form a structure and can be designated as such.

By providing such reflection surfaces which are inclined to one another, the incident light can advantageously be reflected in the direction of an encapsulation such that the reflected light impinges there on a boundary layer of the encapsulation with an environment of the solar cell, whereby a total reflection occurs at this boundary layer can or can occur. As a result, a particularly large proportion of the originally incident light is reflected back in the direction of the solar cell in an advantageous manner. As a result, therefore, a light output can be increased in an advantageous manner, which can cause an increase in performance of the solar cell module in an advantageous manner. In combination with the encapsulation, the structure causes light to be captured by the solar cell, which would otherwise not reach the solar cell. The structure may therefore generally be referred to in particular as a light-catching structure.

In one embodiment it can be provided that the top side and / or the underside of the cell connector are provided with a light catching structure.

In a further embodiment it can be provided that the connecting layer comprises a solder and / or an adhesive, in particular exclusively a solder and / or an adhesive.

This means, in particular, that the connection layer can be a solder layer, for example. In particular, the bonding layer may be an adhesive layer. This means, in particular, that the cohesive connection can be effected by means of soldering and / or by gluing.

According to a further embodiment it can be provided that, when the connection layer comprises a solder, the solder is an element selected from the following group of solders: Sn, SnPb, SnPbAg, SnCu, SnBi, SnBiAg, SnAg. SnCuAg, SnZn.

Sn-Pb alloys in particular have the advantage of a lower melting point. SnBi has the particular advantage that it is a low-melting solder. The starting point or reference point here is the melting point of SnPb (Ag) at about 180 ° C. Low-melting solders are below (usually down to about 139 ° C (SnBi).) Higher melting solders have melting points up to about 221 ° C (SnAg).

In particular, SnCu has the advantage that it is a lead-free compound and thus is generally less harmful to health than an SnPb alloy. Pure tin and SnCu thus have the advantage of lead-free and a sometimes lower price. According to one embodiment it can be provided that a thickness of the bonding layer, that is to say in particular a thickness of the solder layer and / or a thickness of the adhesive layer, is or amounts to from 1 to 50 μm.

According to a further embodiment it can be provided that the adhesive is an element selected from the following group of elements:

In one embodiment, the adhesive is an electrically conductive or electrically conductive adhesive. As a result, for example, power can be passed through the adhesive. Preferably, electrically conductive particles may be incorporated in the adhesive or may be provided or arranged. The adhesive thus preferably has electrically conductive particles.

According to one embodiment it can be provided that the connection layer is applied by means of plasma spraying and / or by means of thermal spraying and / or ultrasonically assisted braiding. The latter case only if the connection layer is a solder layer or this connection layer comprises a solder. Ultrasound-assisted soldering means in particular that the solar cell is subjected to ultrasound before or while the solder is being applied. By Uchaschalleinwirkung oxide layers can be broken open, for example, advantageously present on the solar cell to ensure a mechanically strong and good electrical connection between the solder and the solar cell.

In a further embodiment, it can be provided that, when the connection layer is applied on the front side of the solar cell, the front side of the solar cell is busbarfrei.

That means, in particular, that in this embodiment the cell connector assumes the function of the busbar, that is to say the busbar. It is here advantageously saved material, insofar as no additional busbar is needed more. The cell connector thus has a dual function: a busbar function and a connection function. The cell connector is thus used particularly efficiently and effectively in an advantageous manner. Nevertheless, contact fingers can also be provided in this embodiment.

In a further embodiment, it can be provided that when the bonding layer is applied to the back of the solar cell, the back of the solar cell is solder pad free. The solder pads are or preferably comprise silver. This Lötpads are then solderable, but themselves are not made of a lot or do not even solder, so are lot-free.

Again, material in the form of solder pads is saved in an advantageous manner. Usually, it is known in solar cells so that solder pads are mounted on their back to solder by means of this cell connector. According to the invention, such solder pads, which usually contain silver and are correspondingly expensive, are no longer necessary because their function is taken over by the bonding layer.

In a further embodiment it can be provided that the cell connector is applied with one of its sides to a busbar or is applied to a busbar.

In a further embodiment it can be provided that a plurality of cell connectors are provided, which may be formed in particular the same or preferably different.

In a further embodiment it can be provided that a plurality of solar cells are provided, wherein two directly adjacent solar cells are electrically connected by means of a cell connector, wherein the underside of the cell connector with the top of one of the two solar cells and wherein the top of the cell connector with the bottom the other of the two solar cells are connected.

In a further embodiment, it can be provided that a connecting layer is applied in each case to the front side and to the rear side of the solar cell and wherein the cell connector is unbolted on both sides.

In a further embodiment it can be provided that, when the connection layer is applied to the front side of the solar cell, the front side of the solar cell is busbarfrei.

According to a further embodiment, it can be provided that, when the connection layer is applied to the rear side of the solar cell, the back side of the solar cell is free of soldering pads.

In yet another embodiment, it may be provided that a plurality of solar cells are provided, wherein two directly adjacent solar cells are electrically connected by means of a cell connector, wherein the underside of the cell connector with the top of the one of the two solar cells and wherein the top of the cell connector with the bottom the other of the two solar cells are connected.

According to one embodiment, the cell connector comprises an electrically conductive band, which for example comprises copper or may be formed from copper. The band may preferably be referred to as a copper band. In particular, the band has an upper side and an underside opposite the upper side.

For example, in one embodiment, the tape is disposed between a tie layer and a reflective layer. This means, in particular, that the reflection layer is applied on an upper side of the strip. On a top side opposite the underside of the band, the connecting layer is applied. This means, in particular, that the upper side of the cell connector is formed by the reflection layer. This means in particular that the underside of the cell connector is formed by the connection layer. Here, the reflection layer is preferably unbelotet. This means, in particular, that the top side of the cell connector is not soldered, that is, it is solder-free. The connection layer of the cell connector is a connection layer for materially connecting the cell connector to a solar cell.

In a further embodiment, the cell connector comprises the electrically conductive band as well as the reflection layer and is furthermore formed free of a connecting layer, that is, the cell connector is in particular unbelotet. This means, in particular, that the cell connector has no connecting layer. This means, in particular, that the cell connector has an upper side, which is formed by the reflection layer, and a lower side, which is formed by the electrically conductive band. Thus, the cell connector has on both sides no connecting layer, so the cell connector is free on both sides of a Verbindungsschlicht, so it is preferably unbottled on both sides.

In another embodiment, the cell connector comprises the electrically conductive tape as well as two reflective layers deposited or disposed on top and bottom of the tape, respectively. The top side and the bottom side of the cell connector are therefore each formed in particular by the two reflection layers. The cell connector is free in particular on both sides of a connecting layer, that is in particular free of solder on both sides.

In a further embodiment it can be provided that the light reflection layer, that is to say the reflection layer, has a plurality of mutually inclined reflection surfaces.

In another embodiment it can be provided that the cell connector has several, in particular two, reflection layers. The reflection layers can be formed in particular the same or preferably different.

The connecting layer of the cell connector may be formed, for example, as an adhesive layer and / or as a solder layer. This means in particular that the cell connector 103 can be glued and / or soldered to a solar cell.

Embodiments relating to the method are analogous to embodiments with regard to the solar cell module and vice versa. Corresponding statements apply to the other case and vice versa.

The invention is explained in more detail below with reference to preferred examples. Show here

1 a solar cell module at two different times of its manufacture,

2 a front and a back of a solar cell of the solar cell module according to 1 .

3 another solar cell module at two different times of its production,

4 a front and a back of a solar cell of the solar cell module according to 3 .

5 a sectional view of a solar cell module, similar to the solar cell module according to 1 is formed,

6 a sectional view of another solar cell module, similar to the solar cell module according to 3 is formed,

7 a sectional view of a solar cell module, similar to the solar cell module according to 1 is formed, and

8th a flowchart of a method for manufacturing a solar cell module.

Hereinafter, like reference numerals may be used for like features. Furthermore, for the sake of clarity, not all drawings are marked with all reference numbers.

1 shows a solar cell module at two different times of its production.

The reference number 101 indicates an unfinished solar cell module. The reference number 101 shows so far on the individual components of the solar cell module. The reference number 101b points to the finished solar cell module.

The 1 further shows a cell connector according to the lowest figure 103 as he used cell connectors of the solar cell module 101b is used.

There are two immediately adjacent arranged solar cells 105 and 107 provided. The reference number 109 points to a respective front of the two solar cells 105 . 107 , The reference number 111 points to a respective back of the two solar cells 105 . 107 , The front 109 lies the back 111 across from. Versions in connection with one of the two solar cells 105 . 107 also apply to the other of the two solar cells 105 . 107 ,

The structure of a solar cell as such is known to the person skilled in the art. In particular, the solar cell comprises 105 a wafer, in particular a silicon wafer, with a base and an emitter. The front 109 may be, for example, a light entrance side. The front 109 Thus, for example, it may be a first surface of the wafer. The backside 111 For example, it may be a second surface of the wafer opposite the first surface.

On the front side 109 is a contact structure 113 applied, which comprises a grid-like arrangement of line-shaped metallic contact elements, which may also be referred to as contact fingers comprises. Transverse to these contact fingers run metallic busbars, which have a greater width relative to the contact fingers. For a further view of this contact structure 113 will be on the 2 directed.

On the back side 111 is a back contact structure 115 applied. This has a flat formed metallic layer, for example, an aluminum layer. Again, for a further view on the 2 directed.

The reference number 117 shows on a connecting layer for cohesively connecting the solar cell 105 with a cell connector, in particular with the cell connector 103 , The connection layer 117 is on the back 111 the solar cell 105 applied, more precisely on the back contact structure 115 ie indirectly or indirectly on the back 111 , In the side view according to 1 is just a tie layer 117 visible, noticeable. As the 2 but will show are three tie layers 117 intended. So if in the following only the singular for the connection layer 117 is used, so should always be three tie layers 117 be read along.

Furthermore, the back is 111 , more precisely the back contact structure 115 , the solar cell 105 formed Lotpadfrei, so has no solder pads on.

The reference number 119 points to an upper side of the cell connector 103 , The reference number 121 points to a bottom of the cell connector 103 , The top 119 lies the bottom 121 across from.

The cell connector 103 includes an electrically conductive tape 123 for example, comprising copper or may be formed from copper. The band may preferably be referred to as a copper band. The ribbon 123 is between a connection layer 125 and a reflective layer 127 arranged. So that means in particular that on top of the band 123 the reflection layer 127 is applied. On one of the top opposite bottom of the band 123 is the connection layer 125 applied. So that means in particular that the top 119 of the cell connector 103 through the reflection layer 127 is formed. So that means in particular that the bottom 121 of the cell connector 103 through the tie layer 125 is formed. Here is the reflection layer 127 unbelotet. So that means in particular that the top 119 of the cell connector 103 Unbelotet, that is lot-free, is. At the connection layer 125 it is a connection layer for material-locking connection of the cell connector 103 with a solar cell.

The connecting layers 117 and 125 For example, they may be formed as an adhesive layer and / or as a solder layer. This means in particular that the cell connector 103 with the two solar cells 105 and 107 glued and / or can be soldered.

In the 1 are three cell connectors 103 A cell connector (also referred to as the middle cell connector hereinafter) between the two solar cells 105 . 107 and one (left cell connector) to the left of the solar cell 105 and a (right cell connector) to the right of the solar cell 107 ,

For the production of the solar cell module 101b becomes the bottom 121 of the middle cell connector 103 on the busbar of the top 109 the left solar cell 105 applied or arranged. The unbottled top 119 of the cell connector 103 is on the connection layer 117 the bottom 111 the right solar cell 107 applied or arranged. If the connecting layers 117 and 125 are a solder layer, the individual elements are now soldered together. If the connecting layers 117 . 125 are an adhesive layer, the individual elements are glued together. This connection process, ie the soldering process and / or the bonding process, is symbolic with an arrow with the reference numeral 129 characterized. In this respect, the reference symbol 101b on the solar cell module, in which the middle cell connector 103 with the two solar cells 105 and 107 is connected cohesively.

The bottom 121 of the left cell connector 103 may preferably be on top 109 another not shown solar cell analogous to the middle cell connector 103 be arranged and connected cohesively with this. The top 119 of the right cell connector 103 can preferably on the bottom 111 another not shown solar cell analogous to the middle cell connector 103 be arranged and connected cohesively with this.

In the side view according to 1 is just a cell connector 103 visible, which connects two directly adjacent arranged solar cells. As the top view 2 show there are a total of three middle cell connectors 103 intended. It may be provided in embodiments not shown that more or less than three, for example, 1, 2, 4 or 5, cell connectors are provided, each connecting two immediately adjacent arranged solar cells.

2 shows a plan view of the front 109 the solar cell 105 (left drawing in the 2 ). 2 further shows a bottom view of the back 111 the solar cell 105 (right hand drawing in the 2 ).

The front contact structure 113 comprises, as already stated above, a plurality of contact fingers 203 and across to 3 busbars 201 , where the busbars 201 based on the contact fingers 203 are wider. On these busbars 201 become cell connectors 103 as related to 1 shown, applied and soldered and / or glued there. There are three busbars 201 are provided, thus only three middle cell connectors 103 needed. In general, in particular, a number of busbars 201 a number of middle cell connectors 103 correspond. In an embodiment not shown, more or less than 3 busbars may be used 201 be provided. The concrete example comprising 3 busbars 201 is not limiting. In an embodiment, not shown, it may be provided that perpendicular to the cell connectors 103 Connecting layers on the front 109 and / or on the back 111 the solar cell 105 are provided or arranged.

The back view of the solar cell 105 according to the right drawing in 2 shows that three tie layers 117 like three stripes on the back contact structure 115 , in particular on the aluminum layer, are applied. On these three strips or tie layers 117 becomes a respective top 119 a middle cell connector 103 applied and, depending on the configuration of the connecting layers 117 , soldered together and / or glued together. The number of busbars preferably corresponds to the number of connection layers applied on the back side 117 , Thus, in particular more or less than 3 tie layers 117 be provided.

3 shows analogously to 1 a solar cell module at two different times of its manufacture.

Because the 3 essentially the same elements as the 1 shows, like reference numerals have been used. In particular, the comments related to the 1 directed. As a difference to the 1 is in the solar cell module 101 , b according to 3 provided that the cell connectors 103 each an electrically conductive tape 123 , For example, a copper strip, and a reflection layer 127 comprising, wherein the reflective layer 127 on the electrically conductive band 123 is applied. This means in particular that the cell connector 103 according to 3 a top 119 having, through the reflective layer 127 is formed, as well as a base 121 characterized by the electrically conductive band 123 is formed. The cell connectors 103 according to 3 do not have a tie layer. The cell connectors 103 are therefore free on both sides of a connecting layer, so in particular unbeatable on both sides.

Another difference is in the solar cell module 101 , b according to 3 provided that the solar cells 105 and 107 no bus bars 201 analogous to 2 exhibit. The solar cells 105 and 107 are therefore busbarfrei. They only have contact fingers 203 analogous to 2 on. For another view of the front 109 the solar cells 105 . 107 according to 3 will be on the 4 directed.

Instead, it is on the respective front 109 a tie layer 117 applied, more precisely, three strips of such a compound layer analogous to the three back strips (see. 4 ). These tie layers 117 on the front side 109 So in addition to the connection function, you also take on a busbar function. In this respect, the cell connector 103 be formed unbalanced on both sides. So that means in particular that both the top 119 as well as the bottom 121 lot free, so free of solder, so unbelotet, are. Which side of which element is connected to which side of which element has already been associated with 1 and 2 explained. The statements made there apply word for word and analogously.

4 shows analogous to the 2 in the left drawing the front 109 in a plan view of the solar cell 105 , The right drawing in 4 shows a bottom view of the back 111 the solar cell 105 , Here is the back 111 the solar cell 105 according to 3 analogous to the solar cell 105 according to 1 educated.

As a difference, but the front side 109 according to 4 no bus bars 201 on. Instead of the busbars 201 are three stripes as three tie layers 117 provided, so are three tie layers 117 on the front side 109 applied.

The respective underside 121 the middle cell connector 103 will be on such a strip 117 applied. There are three such stripes 117 are provided so far, three correspondingly formed middle cell connectors 123 provided with its underside 121 which is unbeloted on these three connecting layers 117 be applied.

The respective top 119 the three middle cell connectors 103 is on the back-mounted strip 117 applied.

The corresponding connection process 129 can be analogous to the statements in connection with the 1 and the 2 include a soldering and / or a gluing process.

5 shows a sectional view of a solar cell module 101b , which is similar to the solar cell module 101b according to 1 is formed. As a variant is in the cell connectors 103 according to 5 provided that the reflection layer 127 several surfaces 501 includes, which are inclined to each other. Such mutually inclined surfaces 501 can preferably also in the reflection layers 127 according to 1 be provided.

6 shows a sectional view of another solar cell module 101b , which is similar to the solar cell module 101b according to 3 is formed, here as a training analogous to 5 the cell connectors 103 a reflection layer 127 have, the mutually inclined surfaces 501 includes. Such mutually inclined surfaces 501 can preferably also in the reflection layers 127 according to 3 be provided.

In 6 are such inclined surfaces 501 on both sides of the cell connectors 103 provided, whereas in 5 only one side of the cell connectors 103 such inclined surfaces 501 having. Thus, therefore, the cell connectors 103 according to 5 only one reflection layer with such surfaces 501 on. The cell connectors according to 6 each have a reflective layer with such surfaces on both sides 501 on.

7 shows a sectional view of a solar cell module 101b , which is similar to the solar cell module 101b according to 1 is formed at a relative to the time of manufacture according to 1 later in time of production. As a difference here is just a middle cell connector 103 provided the two solar cells 105 and 107 connects with each other. It can also not shown embodiments, several, preferably 3, cell connectors 103 be provided.

Here is the solar cell 105 with their connected cell connectors 103 encapsulated between two covers, for example plastic covers. Such a plastic cover may for example be formed from ethylene vinyl acetate (EVA). Here, the reference symbol 701 on the cover, the front 109 the solar cell 105 covers. The reference number 703 points to the cover that covers the back 111 the solar cell 105 covers. On the front cover 701 is still a glass cover 705 applied by which, for example, sunlight on the solar cell 105 can radiate. This irradiation of sunlight is symbolic with several arrows with the reference numeral 709 characterized.

On the back cover 703 is yet another back cover 707 applied, which can cause, for example, a mechanical stabilization and a carrier function.

As the 7 shows, the incident light 709 from the inclined surfaces 501 towards the glass cover 705 reflected. This reflected light is indicated by an arrow 711 shown. At an interface 713 the glass cover 705 with an environment of the glass cover 705 , For example, atmosphere or vacuum, takes place at least a partial reflection, preferably a total reflection, so that light from the interface 713 back to the solar cell 105 is reflected. This reflected light is symbolic with an arrow with the reference numeral 715 characterized. As a result, therefore, a light output can be increased in an advantageous manner, which advantageously an increase in performance of the solar cell module 101b can cause.

8th shows a flowchart of a method for manufacturing a solar cell module.

In one step 801 At least one solar cell is provided with a front side and a front side opposite the rear side. In one step 803 For example, a bonding layer for integrally bonding the solar cell to a cell connector is applied to at least one of the front side and the back side. In one step 805 For example, a cell connector is provided having a top surface and a bottom surface opposite the top surface, wherein at least one of the top surface and the bottom surface is unpadded. In a step 807 The unbelotete side of the cell connector is placed on the connection layer of the solar cell. In one step 809 the unbelted side of the cell connector is connected to the solar cell by means of the connecting layer.

QUOTES INCLUDE IN THE DESCRIPTION

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Cited patent literature

• DE 102010016814 B3 [0002]
• DE 112006003262 T5 [0003]

Claims (14)

Solar cell module ( 101b ), comprising: - at least one solar cell ( 105 . 107 ) with a front side ( 109 ) and one of the front ( 109 ) opposite back ( 111 ), - where a connection layer ( 117 . 125 ) for cohesive bonding of the solar cell ( 105 . 107 ) with a cell connector ( 103 ) on at least one of the front sides ( 109 ) and the back ( 111 ), - a cell connector ( 103 ) with a top side ( 119 ) and one of the top ( 119 ) opposite underside ( 121 ), - wherein at least one of the two sides of the cell connector ( 103 ), unbelotet is, - whereby the unbelotete side of the cell connector ( 103 ) on the bonding layer of the solar cell ( 105 . 107 ) is arranged so that the unbelotete side of the cell connector ( 103 ) by means of the bonding layer ( 117 . 125 ) cohesively with the solar cell ( 105 . 107 ) connected is. Solar cell module ( 101b ) according to claim 1, wherein a connecting layer ( 117 . 125 ) each on the front ( 109 ) and on the back ( 111 ) of the solar cell ( 105 . 107 ) and wherein the cell connector ( 103 ) is unbummed on both sides. Solar cell module ( 101b ) according to claim 1 or 2, wherein at least one unbelotete side of the cell connector ( 103 ) a light reflection layer ( 127 ) having. Solar cell module ( 101b ) according to claim 3, wherein the light reflection layer ( 127 ) a plurality of mutually inclined reflecting surfaces ( 501 ) having. Solar cell module ( 101b ) according to one of the preceding claims, wherein the connection layer ( 117 . 125 ) comprises a solder and / or an adhesive. Solar cell module ( 101b ) according to claim 5, wherein if the connection layer ( 117 . 125 ) comprises a solder, the solder is an element selected from the following group of solders: Sn, SnPb, SnPbAg, SnCu, SnBi, SnBiAg, SnAg. SnCuAg, SnZn. Solar cell module ( 101b ) according to one of claims 1 to 6, wherein the connecting layer ( 117 . 125 ) on the front side ( 109 ) of the solar cell ( 105 . 107 ) is applied and the front of the solar cell ( 105 . 107 ) is busbarfrei. Solar cell module ( 101b ) according to one of claims 1 to 7, wherein the connecting layer ( 117 . 125 ) on the back side ( 111 ) of the solar cell ( 105 . 107 ) is applied and the back ( 111 ) of the solar cell is solder pad free. Solar cell module ( 101b ) according to one of the preceding claims, wherein a plurality of solar cells are provided, wherein two directly adjacent to each other arranged solar cells by means of a cell connector ( 103 ) are electrically connected, wherein the underside of the cell connector ( 103 ) with the top ( 119 ) of one of the two solar cells ( 105 . 107 ) and where the top side ( 119 ) of the cell connector ( 103 ) with the underside ( 121 ) of the other of the two solar cells ( 105 . 107 ) are connected. Method for producing a solar cell module ( 101b ), comprising the following steps: - providing ( 801 ) at least one solar cell ( 105 . 107 ) with a front side ( 109 ) and one of the front ( 109 ) opposite back ( 111 ), - application ( 803 ) a connection layer ( 117 . 125 ) for cohesive bonding of the solar cell ( 105 . 107 ) with a cell connector ( 103 ) on at least one of the front side ( 109 ) and the back ( 111 ), - Provide ( 805 ) of a cell connector ( 103 ) with a top side ( 119 ) and one of the top ( 119 ) opposite underside ( 121 ), wherein at least one of the top ( 119 ) and the underside ( 121 ) is undeleted, - arranging ( 807 ) of the unbelotierten side of the cell connector ( 103 ) on the connection layer ( 117 . 125 ) of the solar cell ( 105 . 107 ), - by means of the connection layer ( 117 . 125 ) cohesive bonding ( 809 ) of the unbelotierten side of the cell connector ( 103 ) with the solar cell ( 105 . 107 ). Method according to claim 10, wherein a connecting layer ( 117 . 125 ) each on the front ( 109 ) and on the back ( 111 ) of the solar cell ( 105 . 107 ) and wherein the cell connector ( 103 ) is unbummed on both sides. Method according to claim 10 or 11, wherein if the connection layer ( 117 . 125 ) on the front side ( 109 ) of the solar cell ( 105 . 107 ), the front side ( 109 ) of the solar cell ( 105 . 107 ) is busbarfrei. Method according to one of claims 10 to 12, wherein if the connection layer ( 117 . 125 ) on the back side ( 111 ) of the solar cell ( 105 . 107 ) is applied, the back ( 111 ) of the solar cell ( 105 . 107 ) is solder pad free. Method according to one of claims 10 to 13, wherein a plurality of solar cells are provided, wherein two immediately adjacent to each other arranged solar cells by means of a cell connector ( 103 ) are electrically connected, wherein the underside ( 121 ) of the cell connector ( 103 ) with the top ( 119 ) of one of the two solar cells and the top side ( 119 ) of the cell connector ( 103 ) with the Underside ( 121 ) of the other of the two solar cells.

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