DE102016213024A1 - Method and device for fastening a connection device to a solar module - Google Patents

Abstract

The invention relates to a device (24) and a method for fastening a connection device (1) to a solar module (11), wherein the connection device (1) has a side (2) facing the module and a side (3) facing away from the module, wherein in one central region (5) of the module-facing side (2) at least one passage opening (12, 13) in the connection device (1) from the module-facing side (2) to the module side facing away (3), wherein an adhesive material (15) in an edge region (4) the module-facing side (2) and / or in a mounting region (16) of the solar module (11) is applied, wherein the connection device (1) with the module-facing side (2) on the mounting region (16) of the solar module (11) wherein adhesive material (15) is additionally applied in the central region (5) of the module-facing side (3).

Description

The invention relates to a method and a device for fastening a connection device to a solar module.

From the prior art it is known to attach a junction box to a solar module, wherein the junction box for receiving contact means for electrically contacting the solar module is used. These junction boxes are usually glued in a first step by means of silicone to a surface, such as a back of the solar module. It is also known that in a second step, at least part of the junction box is filled with a silicone in order to electrically isolate parts of the elements arranged in the junction box.

It is also known that when filling air bubbles and can be included in the filler. Such air bubbles undesirably degrade the insulating properties of the filler material.

The JP 2014027238 A discloses a solar cell module having a junction box and a filler material, wherein the filler material is filled by a filling device into the junction box. Further, the document discloses that the solar module is then vibrated to remove air bubbles.

The JP 2014027239 A also discloses a solar cell module having a terminal box and a filling material which is filled by a filling device into the terminal box. Further, the document discloses that a solar cell module is rotated with the terminal box for a certain period of time to remove air bubbles.

The JP 2014022469 A discloses that a housing of a junction box in the region of the top is opened, wherein the junction box is filled by filling devices from one side of the surface.

The JP 2014007199 A discloses a junction box of a solar cell module which is filled with a filling material by a filling device. Further, the solar cell module is transported to a rotating device and rotated for a predetermined period of time to remove air bubbles.

The US 2014196945 A discloses a junction box having a body and a terminal plate to which a cable inserted into the body is coupled. Furthermore, the box comprises a stationary part, which at least attaches the connection plate to the main part. The connection box comprises a filling material which seals a peripheral area of the connection plate. Further, the terminal plate has an opening serving as an inlet for filling material and as an air passage opening.

The JP 2013016653 A discloses a method of manufacturing a solar cell module. Herein, a junction box is sealed in a sealing process. Furthermore, in a decompression process, an interior of the connection box is decompressed and in a filling process the decompressed connection box is filled with potting material.

Solar modules with junction boxes, in whose filler air bubbles are arranged, may represent rejects of the production process, as in such junction boxes reliability of the solar module can not be guaranteed to a desired extent.

The technical problem arises of providing a method and a device for fastening a connection device to a solar module, which reduce rejects in the production of solar modules or the risk of undesired reduction of the operational safety of the finished solar module.

The solution of the technical problem results from the objects with the features of claims 1 and 10. Further advantageous embodiments of the invention will become apparent from the dependent claims.

A method is proposed for fastening a connection device or a part thereof to a solar module. The method is used in particular for mounting a connection device to the solar module. The connection device can in particular be a junction box or a part thereof.

In this case, the method for fastening may be part of a method for producing a solar module with a connection device fastened to the solar module. In this method of manufacture, the at least one connection device is fixed by the proposed method for attachment to the solar module.

The connection device has a module-facing side and a module-facing side. In the fastened state of the connection device, at least part of the side facing the module can rest on or lie against a fixing region of the solar module. The side facing away from the module can be a side of the connection device opposite the side facing the module. For example, the connection device may have a rectangular or substantially rectangular cross-section.

The connection device can in this case have a receiving region for contact means for producing an electrical contact with active regions of the solar module. Also, in the receiving area, further electrical or electronic components, for example a diode, in particular a so-called bypass diode, may be arranged.

Furthermore, at least one cable can extend from the outside into the receiving area of the connection device. A free end of the cable can allow contacting of a so-called contact band of the solar module, wherein an electrical contact to the active region (active layer) can be produced by the contact band.

The module-facing side and the module-remote side of the connection device can each comprise or have an edge region. In this case, the edge region may in each case comprise or enclose a central region of the module-facing or module-side facing side. A width of the edge region may be e.g. up to 10% or 20% of the width or length of the entire module-facing side or the entire module side facing away. Thus, a width or length of the central region may be in a range of 60% to 90% of the entire width or the entire length.

It is possible that a surface of the module-facing side is flat. In particular, the surface in the edge region and the surface in the central region can be arranged in one plane. However, it is also possible that the module-facing side has at least one recess or recess. The module-remote side may also preferably have at least one depression or recess, e.g. to form the Verfüllbereich explained in more detail below.

At least one passage opening is arranged in the central region of the module-facing side. This extends from the module-facing side to the module side facing away. In the region of the passage opening, in particular on the side facing away from the module, one or more of the aforementioned electrical or electronic components can be arranged. This can also mean that at least one such component is arranged below or above or at least partially in the passage opening. However, it is not mandatory that an electrical or electronic component is arranged in the region of the passage opening.

Furthermore, an adhesive material is applied in the edge region of the module-facing side and / or in a fastening region of the solar module. The border area has been explained previously. A mounting region of the solar module here denotes a region in which the connection device is arranged in the fastened state. This means that the connection device is fastened to the solar module in the fastening region. The attachment region can in this case be arranged in particular on a rear side of the solar module.

The at least one passage opening can in this case be subsequently introduced, in particular at a fixed location, into the connection device.

The adhesive material may in particular be an adhesive silicone, more particularly a so-called one-component adhesive silicone.

It is possible to apply the adhesive material in a strip or caterpillar shape, wherein a strip or a bead can have a circular cross section. Of course, a strip may also have a different cross-section.

Furthermore, the connection device with the side facing the module is arranged on the fastening region of the solar module, in particular pressed or pressed against this fastening region. During and after the arrangement, the adhesive material can be arranged in the edge area and / or in the fastening area between the connection device and the solar module. Thus, areas of the solar module and / or the connection device provided with adhesive material come into contact.

According to the invention, adhesive material is additionally applied in at least part of the central region of the module-facing side of the connection device. In particular, adhesive material is additionally applied in the central region in such a way that adhesive material, in particular when pressed against the module-facing side on the fastening region, in particular when pressing or pressing against the solar module, enters or passes through the through-opening.

It is of course additionally or alternatively possible to additionally apply adhesive material in a partial region of the mounting region of the solar module which, during or after arranging the connection device on the fastening region in the desired fastening position, faces the central region of the connection device and / or bears against this central region. Also, the application of adhesive material in at least a part of the central region of the module-facing side of the connection device correspond to such an application in the partial region of the mounting region of the solar module.

Thus, the passage opening or at least a part thereof is filled with adhesive material when the connection device is arranged with the module side facing the mounting region of the solar module.

It is also possible for regions of the side facing away from the module also to be at least partially filled with adhesive material which passes through the passage opening.

It is possible for regions of the side facing away from the module, in particular partial regions of the central region, to have an irregular, in particular uneven, surface. The surface may in particular be a bottom surface of the side facing away from the module. For example, a surface of the central portion of the module-facing side may have projections, e.g. in the form of webs, or depressions, for example in the form of blind holes or the at least one passage opening. By passing adhesive material through the through-opening into this region of the side facing away from the module, these unevennesses can be filled in such a way that the region filled with adhesive material has less unevenness after the filling, preferably a flat surface.

By filling the passage opening and optionally further regions of the module-facing side, a reduction of unevenness on the side facing away from the module is achieved in an advantageous manner compared to the unfilled state. If subsequently, as explained in more detail below, filling material is filled from the side facing away from the module into a filling area of the side facing away from the module, the risk of bubble formation is also reduced by reducing the unevenness. In this case, it can be assumed that the irregular areas, in particular uneven areas created by uneven surfaces or through openings, increase the risk of air bubble formation when filling with filling material.

This results in an advantageous manner that reduces the risk of air bubbles in the attachment of the connection device to the solar module and thus also producing the solar module with the connection device and thus reliability is increased. Thus, a reject in the production of such solar modules is advantageously reduced.

The adhesive material arranged in the central area can also serve for strengthening the connection device to the solar module in addition to the explained filling of the passage opening and possibly further uneven areas on the module side.

In a further embodiment, the adhesive material is applied in the region of the at least one passage opening. This may mean that the adhesive material is applied above or below the passage opening in the region of the module-facing side. It is also possible for the adhesive material to pass into or through at least part of the passage opening during or after application.

This can be ensured in an advantageous manner that the adhesive material occurs in the temporally subsequent arrangement of the connection device with the module side facing the mounting region of the solar module in or through the through hole and this at least partially or preferably completely fills. This in turn advantageously results in a reliable reduction of unevenness in the region of the module-facing side, in particular in the region of the passage opening. This in turn reliably reduces the risk of creating air bubbles when filling backfill material and thus the rejects or the risk of reduced operational safety.

In a further embodiment, the adhesive material is applied in strips. In this case, a strip or several strips can be applied in the edge region of the module-facing side of the connection device. Further, one or more strips may be applied in the central region of the module-facing side. The strip-like application advantageously makes it possible to apply the adhesive material to the module-facing side in a process-technically simple manner.

In a further embodiment, at least one strip of the adhesive material extends from an edge region of the module-facing side into or through the central region. In particular, the at least one strip can extend from a first edge region through the central region to a further edge region, which lies opposite the first edge region. For example, The strip may extend from a longitudinal or transverse edge to an opposite longitudinal or transverse edge of the connection device.

The application of a strip which extends from an edge region into or through the central region advantageously results in a procedurally simple process Application of adhesive material in the desired areas.

In a further embodiment, the adhesive material is applied in a partial region of the central region of the module-facing side, which is opposite to a filling region of the module-facing side. In this case, the passage opening can be arranged in the partial area.

In this case, the filling area may denote a partial area of the module-remote side, in particular a partial area of a central area of the module-remote side, into which filling material is filled in order to insulate electrical or electronic components or elements. Thus, these electrical or electronic components or elements or at least a part thereof can be arranged in the filling area. The filling area can thus be a subarea of the above-mentioned receiving area or can correspond to or include this receiving area. The fill area may be defined by delimiting elements, e.g. Webs or walls are included, wherein the boundary elements are arranged on the module side facing away.

In this way it is advantageously ensured that a reduction or compensation of unevenness in the filling area is made possible by the adhesive material which passes through the passage opening or at least a part thereof, and preferably a flat or smooth surface can be provided. Thus, the risk of air bubble formation is reduced, especially in the filling area, whereby the desired insulation properties may be given after filling.

In a further embodiment, at least one adhesive pad is arranged on the side facing the module before the application of adhesive material in the central region of the module-facing side. An adhesive pad may be in the form of a sticker coated on both sides with an adhesive layer.

If the adhesive material for fastening the connection device to the solar module, as explained above, is a silicone, in particular a one-component silicone, then the process for fastening the connection device to the solar module may require curing of the silicone. Due to the additional adhesive pad, a stationary attachment of the connection device to the solar module can be ensured in an advantageous manner before and during this curing. Thus, the adhesive pad can serve for fixing the connection device to the solar module, at least until the adhesive material for fastening the connection device to the solar module has hardened.

Furthermore, the arrangement of the adhesive pad in the central region of the module-facing side results in a reduction of the spatial volume present on the module-facing side, into which the adhesive material, in particular the adhesive material applied in the central region, can enter the attachment region when arranging the attachment device. Due to the reduced volume of space is achieved in an advantageous manner that in comparison to a design without adhesive pad more adhesive material can enter or through the passage opening. Preferably, the adhesive pad is arranged in the central region. In the central region, however, the adhesive pad or a part of the adhesive pad is not arranged in the region of a passage opening, in particular not above or below a passage opening. As a result, the passage of adhesive material through the passage opening is not prevented by the adhesive pad in an advantageous manner. In this way, an improved reduction of unevenness in the region of the module-remote side can be achieved.

In a further embodiment, the adhesive material is cured after arranging the connection device with the side facing the module at the attachment region of the solar module. Curing can mean that a desired degree of hardness of the adhesive material is adjusted. The curing can take place in this case by adjusting at least one surrounding condition such that moisture, for example in the form of water molecules, is removed from the adhesive material. Ambient conditions may be, for example, an ambient temperature and an ambient humidity. For example, a predetermined temperature, particularly in a range of 35 ° C to 100 ° C, may be set in the space area including the adhesive material. Alternatively or cumulatively, the curing may be accomplished by placing the adhesive material for a predetermined period of time in an environment of suitable environmental conditions, for example in air at room temperature. For example, the adhesive material may be in a range of more than 6 hours, preferably more than 10 hours, more preferably more than 12 hours at normal room temperature, for example at a temperature of 15 ° C to 25 ° C, in air at a humidity be cured from 20% to 70%, preferably 40% to 50% relative humidity.

This results in an advantageous manner a reliable attachment of the connection device on the solar module, which additionally seals the previously described receiving area of the module side facing.

In a further embodiment, the adhesive material after arranging the Connection device irradiated with the module side facing the mounting portion of the solar module. Preferably, the adhesive material is irradiated with infrared radiation. Infrared radiation may in this case have a wavelength from a range of 780 nm to 1 mm. Further, the adhesive material may be irradiated with infrared radiation for a predetermined irradiation time period and at a predetermined irradiation power. The irradiation period may be, for example, 30 seconds. The irradiation power may be 150 W, for example.

In this way, the time required for hardening, in particular until reaching a desired degree of hardness, in comparison to curing without irradiation can be reduced in an advantageous manner.

In a further embodiment, after arranging the connection device with the side facing the module, a filling material is arranged in the filling region of the side facing away from the module. The backfill material may in particular be another silicone, preferably a two-component silicone.

The components of the two-component silicone may be mixed a predetermined (short) amount of time prior to placement in the backfill area and thereafter placed in the backfill area, for example with a suitable mixing head. As a result of the chemical composition of the two components, the filling material generally hardens in terms of time.

The filling area has been explained previously. The filling area may in this case be a partial area of the central area of the module-facing side. Of course, it is also conceivable that the filling area comprises at least a part of the edge area.

By arranging the adhesive material in the central region of the module-facing side and passing through the through-opening, a reduction of unevenness of a surface, in particular a bottom surface, can take place, in particular in the filling region before the filling material is arranged. Ideally, a flat or smooth surface can be produced. This reduces the risk of air bubbles when filling the filling material.

The filling material can be arranged in the filling area before, during and / or after the curing of the adhesive material. Preferably, the backfill material is placed in the backfill area during the complete cure of the adhesive material.

This results in an advantageous manner an electrical insulation of the electrical or electronic components with desired (good) insulation properties.

Further proposed is a device for fastening or mounting a connection device to a solar module. The device serves to carry out a method according to one of the embodiments described in this disclosure. Thus, the device is designed such that a corresponding method by means of the device is feasible.

The device comprises at least one device for applying an adhesive material. The device may be designed, for example, as an adhesive material dispensing device or comprise such. In this case, the device can be movable relative to the connection device and / or relative to a fastening region of the solar module, in particular be able to be moved in an actuator-supported manner.

Further, by means of the device, an adhesive material in the edge region of the module-facing side and / or in the mounting region of the solar module can be applied.

Furthermore, the connection device with the side facing the module can be arranged on the attachment region of the solar module. This can be done, for example, by means of at least one positioning device, wherein the positioning device can be part of the proposed device. In particular, the connection device can be movable relative to the solar module by means of the at least one positioning device. The positioning device may e.g. adjust the position of the connection device or the solar module. A further positioning device can set a position of the remaining element, that is to say of the solar module or the connection device.

According to the invention, the adhesive material can additionally be applied by means of the device for applying the adhesive material in the central region of the module-facing side.

The device thus advantageously makes it possible to carry out a method explained above.

Furthermore, the device may comprise a further device for applying a filling material. This device can be designed, for example, as a filling material dispensing device or comprise such. For example, a filler dispenser may include a mixing head for the components of a two-part silicone. By means of this device can backfill material in one Verfüllbereich the module facing away side can be arranged. For this purpose, the device may be movable relative to the solar module, in particular actuator-supported.

Furthermore, the device may comprise a device for setting a temperature in the region of the adhesive material. This device may for example be a heater or a cooling device.

Furthermore, the device may comprise at least one irradiation device, in particular an infrared irradiation device.

Further described is a connection device with a side facing the module and a side facing away from the module. Both the module-facing side and the module-facing side can each have an edge region and a central region. Furthermore, the connection device can have at least one passage opening which extends from the central region on the side facing the module to the side facing away from the module, in particular to a filling region on the side facing away from the module.

Of course, the connection device can also have a plurality of passage openings. In exactly one of these passage openings or in the region of this passage opening, electrical or electronic components of the connection device can be arranged.

Furthermore, the connection device can have or form so-called spacer elements in an edge region on the side facing the module, in particular in an edge region. These may be formed, for example, as pins or webs. The spacer elements can thus be formed by the edge region or by the central region of the module-facing side protruding elements. When arranging the connection device with the module-facing side on the attachment region, the spacer elements come into mechanical contact with a surface of the solar module. In this way, it is advantageously ensured that a predetermined spatial distance is present between the surface of the solar module in the attachment area and the remaining surface area or edge area of the module-facing side, in which the adhesive material is arranged. Without spacer elements, there is a risk that the adhesive material, in particular completely, is pressed out of the region between the module-facing side and the fastening region during pressing, whereby on the one hand a stability of the fastening and on the other hand a desired insulation can be impaired.

In particular, in the case of a connection device formed in this way, in addition to the adhesive material, at least one adhesive pad can be arranged in the central region of the module-facing side in order to reduce the space volume available for adhesive material on the side facing the module when arranging it at the attachment region.

The invention will be explained in more detail with reference to embodiments. The figures show:

1 a schematic plan view of a module-facing side of a connection device,

2 a schematic plan view of a module facing away from the in 1 illustrated connection device,

3 a schematic side view of a solar module with a connection device attached thereto,

4 a schematic block diagram of a device according to the invention and

5 a schematic flow diagram of a method according to the invention.

Hereinafter, like reference numerals designate elements having the same or similar technical features.

1 shows a schematic plan view of a module side facing 2 a connection device 1 , which may be designed in particular as a junction box or part thereof. The module-facing side 2 refers to the one module side facing away 3 the connection device 1 (see eg 2 ) opposite side of the connection device 1 ,

The module-facing side 2 has a border area 4 and a central area 5 on, with the edge area 4 the central area 5 includes. A dashed line is a border between the border area 4 and the central area 5 shown.

A width of the border area 4 For example, 10% of the width of the connection device 1 be. The width of the connection device 1 may be a distance between the edges of the longitudinal sides or transverse sides of the connection device 1 be.

Further shown is that in the edge area 4 the module-facing side 2 Spacer elements 6 arranged or formed, which may be formed as so-called pins. These are as elevations over a surface of the edge area 4 educated. Next points the border area 4 four through holes 7 to the module side facing away 3 on.

Further illustrated are cables 8th from an outer volume into a receiving area on or above the module side 3 the connection device 1 are guided. At free ends of the cables 8th is a cable lug 9 arranged for contacting a contact strip 10 serves, with the contact strip 10 with an active area of a solar module 11 (please refer 3 ) connected is.

The contact shoes 9 are here in a range of through holes 12 arranged, extending from the central area 5 the module-facing side 2 to the module side facing away 3 , in particular to a filling area 14 the module side facing away 3 , extend. Further shown is that in the central area 5 the module-facing side 2 slit-shaped further passage openings 13 are arranged, which are also from the central area 5 the module-facing side 2 to a backfill area 14 (please refer 2 ) of the module side facing away 3 extend. Also shown is an adhesive material 15 which is in the edge area 4 the module-facing side 2 the connection device 1 is applied. Here is the adhesive material 15 represented by hatched areas. The adhesive material 15 can be applied in particular in the form of stripes or caterpillar. Further shown is that adhesive material 15 also in the central area 5 the module-facing side 2 is arranged. In particular, a strip of adhesive material extends 15 from a subsection of the edge area 4 on a first longitudinal side to a section of the edge region 4 on an opposite longitudinal side of the connection device 1 and over the other passage openings 13 ,

Thus, the adhesive material extends 15 through the central area 5 , in particular in the region of the further passage openings 13 ,

Will now be the connection device 1 with the module-facing side 2 at a mounting area 16 of the solar module 11 (see eg 3 ), so on the one hand, the adhesive material 15 between a surface of the attachment area 16 and a surface of the module-facing side 2 the connection device 1 arranged. Next is the adhesive material 15 , in particular in the region of the further passage openings 13 arranged adhesive material 15 , through the further passage openings 13 and optionally also through the passage openings 12 in the backfill area 14 (please refer 2 ) of the module side facing away 3 pressed. As a result, in particular the further passage openings 13 with adhesive material 15 at least partially, but preferably completely filled. It is also possible that the adhesive material 15 also at least part of the bottom surface of the filling area 14 on the side facing away from the module 3 covered. As a result, unevennesses, in particular those through the passage openings, are advantageously formed 12 . 13 conditional unevenness, in the bottom area of the filling area 14 reduced, especially smoothed.

This in turn reduces the risk of air bubble formation when filling the Verfüllbereichs 14 with a filling material 22 (please refer 2 ). Experiments have shown that air bubbles can be generated in particular by uneven areas during filling.

The passage openings 12 . 13 are here arranged such that they are in a partial area of the central area 5 are arranged, the the Verfüllbereich 14 opposite.

In 2 is a schematic plan view of a module side facing away 3 the in 1 illustrated connection device shown.

The module side facing away 3 can be a raised edge area 18 exhibit. In a central area, the module side facing away 3 Stege 19 have a height of the webs less than the height of the raised edge region 18 can be. The bridges 19 limit a backfilling area 14 ,

In 2 is shown in the backfill area 14 electrical and electronic components are arranged. In particular, in the backfill area 14 terminals 9 , the contact bands 10 and exposed wires of the cables 8th arranged. Next is in the backfill area 14 a so-called bypass diode 20 as well as electrical connection elements 21 arranged, with the cables 8th via the bypass diode 20 and the electrical connection elements 21 in the backfill area 14 be electrically connected.

By hatched lines is a backfill material 22 shown, which in the backfill area 14 is arranged. The backfill material 22 may in particular be a two-component silicone. The adhesive material 15 may in particular be a one-component silicone.

When filling, the electrical and electronic components that are in the backfill area 14 are arranged in the backfill material 22 enclosed, whereby these components are electrically isolated.

Because of the passage openings 12 and the in 2 further through openings 13 (please refer 1 ) before filling already with adhesive material 15 may be filled, the bottom area of the Verfüllbereichs 14 in which then backfill material 22 is arranged, advantageously less uneven areas, which can lead to the formation of air bubbles.

Thus, therefore, the risk of air bubble formation is reduced, which in turn isolating properties of the connection device 1 be improved. This increases operational safety and thus reduces rejects in the production of solar modules.

In 1 is still an adhesive pad 23 represented, which is the central area 5 the module-facing side 2 is arranged. The adhesive pad 23 serves to glue the connection device 1 to the solar module 11 ,

In 3 is a solar module 11 with a connection device mounted thereon 1 shown. In particular, a mounting area is shown 16 , eg on a rear side, of the solar module 11 , Obvious here are spacer elements 6 on the side facing the module 2 the connection device 1 are arranged. Schematically represented are the passage openings 12 . 13 , Also shown is the adhesive material 15 which is both in the edge area 4 as well as in the area of the further passage openings 13 on the module side 2 is arranged.

In 4 is a schematic block diagram of a device according to the invention 24 for fastening a connection device 1 on a solar module 11 shown. The device 24 comprises a control device 25 , for example, include a microcontroller or may be designed as a microcontroller. Furthermore, the device comprises 24 a positioning device 26 for the connection device 11 , wherein by the positioning 26 a position and orientation of the connection device 1 can be adjusted. Furthermore, the device comprises 24 An institution 27 for applying an adhesive material 15 (please refer 1 ) and a device 28 for applying a filling material 22 (please refer 2 ). By means of the device 24 can that in 5 described method are performed.

In 5 is shown a schematic flow diagram of a method according to the invention. In a first step S1 becomes adhesive material 15 in a border area 4 a module facing page 2 a connection device 1 as well as in a central area 5 this module facing page 2 , in particular in the region of at least one passage opening 12 . 13 applied. This can be a device 27 and the connection device 1 be moved with a relative movement relative to each other.

In a second step S2, the connection device 1 with the module-facing side 2 at a mounting area 16 a solar module 11 arranged, in particular on a surface of the attachment area 16 pressed. Here, the adhesive material 15 through the passage openings 13 to step.

In a third step S3, the adhesive material 15 hardened. Here, the adhesive material 15 be irradiated with radiation, in particular infrared radiation. Alternatively or cumulatively, the adhesive material may be dried for a predetermined period of time in an environment having predetermined environmental conditions, such as a predetermined temperature and a predetermined humidity.

In a fourth step S4 then backfill material 22 in a backfill area 14 a module side facing away 3 the connection device arranged to isolate electrical components and elements. Also the filling material 22 can be cured.

Next, an unillustrated lid on the module side facing away 3 the connection device 1 be put on.

LIST OF REFERENCE NUMBERS

1

connecting device

2

module-facing side

3

Module side facing away

4

border area

5

central area

6

Spacer elements

7

Through openings

8th

electric wire

9

lug

10

Contact band

11

solar module

12

Through opening

13

further passage opening

14

filling area

15

adhesive material

16

fastening area

18

raised edge area

19

Stege

20

Bypass diode

21

electrical connection elements

22

backfill

23

adhesive pad

24

contraption

25

control device

26

positioning

27

Device for applying adhesive material

28

Device for applying filling material

S1

first step

S2

second step

S3

Third step

S4

fourth step

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• JP 2014027238 A [0004]
• JP 2014027239 A [0005]
• JP 2014022469 A [0006]
• JP 2014007199 A [0007]
• US 2014196945 A [0008]
• JP 2013016653 A [0009]

Claims (10)

Method for fixing a connection device ( 1 ) on a solar module ( 11 ), the connection device ( 1 ) a module-facing side ( 2 ) and a module-facing side ( 3 ), wherein in a central area ( 5 ) of the module-facing side ( 2 ) at least one passage opening ( 12 . 13 ) in the connection device ( 1 ) from the module-facing side ( 2 ) to the side facing away from the module ( 3 ), wherein an adhesive material ( 15 ) in a peripheral area ( 4 ) of the module-facing side ( 2 ) and / or in a mounting area ( 16 ) of the solar module ( 11 ) is applied, wherein the connection device ( 1 ) with the module-facing side ( 2 ) at the attachment area ( 16 ) of the solar module ( 1 ), characterized in that adhesive material ( 15 ) additionally in the central area ( 5 ) of the module-facing side ( 2 ) is applied. Method according to claim 1, characterized in that the adhesive material ( 15 ) in the region of the at least one passage opening ( 12 . 13 ) is applied. Method according to one of the preceding claims, characterized in that the adhesive material ( 15 ) is applied in strips. A method according to claim 3, characterized in that at least one strip from a border area ( 4 ) in or through the central area ( 5 ). Method according to one of the preceding claims, characterized in that the adhesive material ( 15 ) in a partial area of the central area ( 5 ) of the module-facing side ( 2 ), which corresponds to a filling area ( 14 ) of the module-facing side ( 3 ) is opposite. Method according to one of the preceding claims, characterized in that prior to the application of adhesive material ( 15 ) in the central area ( 5 ) at least one adhesive pad ( 23 ) on the module-facing side ( 2 ) is arranged. Method according to one of the preceding claims, characterized in that the adhesive material ( 15 ) after arranging the connection device ( 1 ) with the module-facing side ( 2 ) at the attachment area ( 16 ) of the solar module ( 11 ) is cured. Method according to one of the preceding claims, characterized in that the adhesive material ( 15 ) after arranging the connection device ( 1 ) with the module-facing side ( 2 ) at the attachment area ( 16 ) of the solar module ( 11 ) is irradiated. Method according to one of the preceding claims, characterized in that after arranging the connection device ( 1 ) with the module-facing side ( 2 ) at the attachment area ( 16 ) a filling material ( 22 ) in a backfilling area ( 14 ) of the module-facing side ( 3 ) is arranged. Device for fastening a connection device ( 1 ) on a solar module ( 11 ), the connection device ( 1 ) a module-facing side ( 2 ) and a module-facing side ( 3 ), wherein in a central area ( 5 ) of the module-facing side ( 2 ) at least one passage opening ( 12 . 13 ) in the connection device ( 1 ) from the module-facing side ( 2 ) to the side facing away from the module ( 3 ), the device ( 24 ) at least one institution ( 27 ) for applying an adhesive material ( 15 ), wherein by means of the device ( 1 ) an adhesive material ( 15 ) in a peripheral area ( 4 ) of the module-facing side ( 2 ) and / or in a mounting area ( 16 ) of the solar module ( 11 ), the terminal device ( 1 ) with the module-facing side ( 2 ) the attachment area ( 16 ) of the solar module ( 11 ), characterized in that adhesive material ( 15 ) additionally in the central area ( 5 ) of the module-facing side ( 2 ) is orderable.

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