DE102010034860A1 - Connection box for solar module, has vent holes that are formed in side wall and bottom portion of base such that inner space of connection box portion is filled with liquid and curable filler air is escaped into outside space - Google Patents

Abstract

The connection box (1) has cover (3) and base (4) which is provided on solar module (2). The base comprises a bottom portion (5) and side wall (6). An adhesive layer (11) is arranged on lower surface of bottom portion. Multiple vent holes are formed in side wall and bottom portion of base to connect the inner space of connection box portion (13) and outside space (14). The inner space of connection box portion is filled with liquid and curable filler air is escaped into outside space.

Description

The present invention relates to a junction box for a solar module and a solar module with a junction box.

Solar modules usually have a junction box, via which the generated electrical power can be tapped. The junction boxes are usually mounted on the back of the module on the backside encapsulation material system with the contact strips of the solar module passed through an opening in the backside encapsulation system and an opening in the bottom of the junction box into the junction box. Within the junction box, the contact strips are connected in the simplest version of a junction box directly to the connection lines, which are led out of the junction box. In a junction box and electrical components, in particular so-called bypass diodes and other elements may be arranged. As a rule, two contact strips of a solar module are assigned a common connection box, but it is also possible for each module to have two or more connection boxes, each with one connecting line.

The junction box must ensure permanent, safe electrical contact with the solar module as well as sealing the opening in the back enclosure system for the typical warranty period of at least 20 years. For permanent sealing of the box from environmental influences, the junction boxes are partially hermetically sealed, but this has the disadvantage that the condensation of the trapped air humidity in the junction box can not be avoided. The junction boxes can therefore be filled with an insulating filling material, whereby the electrical components are permanently protected mechanically and against climatic influences.

According to the prior art, such junction boxes are first fixed on the back of the solar module and then filled with a filling material.

When pouring the junction box, however, it may lead to the formation of air bubbles within the junction box, which are also referred to as caverns and which depending on the location in the junction box can reduce the protection of the electrical components and the liability of the junction box on the solar panel and are therefore undesirable ,

The object of the invention is to provide a junction box for electrical contacting of a solar module, which can be filled with a filler material largely free of air or gas inclusions and which ensures a permanently mechanically stable and tight connection with the back of the module, and the provision of a corresponding solar module.

The problem is solved by the main claim. Preferred embodiments are set forth in the subclaims.

The invention relates to a junction box for a solar module with a can body, which has at least one passage opening for the passage of a connecting line and a filling opening for filling a liquid filler, wherein the can body has a bottom for placement on the solar module, which at least one passage opening for the implementation at least one supply line, wherein optionally an adhesive layer is arranged on the solar module facing lower surface of the bottom, which covers at least a portion of the lower surface of the bottom and wherein through the can body, the at least one feedthrough opening, the adhesive layer, the filling opening and the solar module an interior and an exterior space are defined.

The junction box according to the invention is characterized in that one or more vent channels are arranged below the filling opening in the wall of the can body or in the adhesive layer, which connect the interior and the exterior space when the can body with top filling opening, so that when filling the interior With a liquid filler air can escape through a vent to the outside.

By inventively provided ventilation channels in the wall of the can body or in the adhesive layer can escape air, which is enclosed when filling the junction box with the filler between filler and the interior limiting surfaces and which z. B. due to a viscosity and a surface tension of the liquid filling material does not rise in the form of bubbles and escapes through the filling generally located at the top filling opening. Such trapped air areas usually arise in the peripheral areas of the interior, such as the corners but also the underlying edge regions of the can body, but especially in the enclosed between the bottom of the can body and the solar panel area. By the escape of the air from the peripheral areas almost the entire interior can be filled, whereby on the one hand by the maximum area utilization optimal mechanical adhesion of the Junction box on the Rückflächenverkapselungsmaterialsystem is achieved, as well as an optimal protection against the ingress of moisture. Caverns in which corrosion can occur due to trapped moisture are largely avoided or at least greatly reduced.

Venting channels in the adhesive layer may also be respectively disposed at the interfaces of the adhesive layer to the module surface and / or to the bottom surface of the bottom so that the walls of the ventilation channels are not formed solely by the adhesive layer. The vent channels in the adhesive layer must therefore not be arranged completely inside the adhesive layer.

Likewise, ventilation channels in the wall of the can body can also be arranged at the interface with the adhesive layer or, if no adhesive layer is present, on the underside of the base facing the solar module, so that the walls of the ventilation channels are not formed solely by the can body, but also through the adhesive layer or the solar module. The vent channels in the wall of the can body must therefore not be arranged completely inside the wall of the can body From the main claim arise depending on the presence of the optional adhesive layer two options: If the optional adhesive layer is present, then the at least one vent channel with alignment of the can body with Be located above the filling opening below the filling opening in the wall of the can body or in the adhesive layer. In particular, the one or all venting channels can be arranged exclusively in the adhesive layer. In the latter case, therefore, the can body does not have to have any further venting channels.

If, on the other hand, the optional adhesive layer is not present, then one or more venting channels are arranged below the filling opening in the wall of the can body when the can body is aligned with the filling opening at the top. Interior and exterior space according to the main claim are formed in this case according to the can body, the at least one passage opening, the filling opening and the solar module.

The solar module can be, for example, a thin-film solar module or a module based on monocrystalline or polycrystalline solar cells, whose back-end encapsulating material may comprise, for example, a glass pane or a foil composite material. In general, a solar module on the back side has a feedthrough opening in the back face encapsulating material system for one or both supply lines, but the supply lines may also be led out of the module laterally between the photovoltaic layer system and the back side encapsulating material system. It is preferably a thin-film solar module with a planar rear side.

The connection box according to the invention is placed on the solar module during assembly in the region of the passage opening in the Rückflächenverkapselungsmaterialsystem, wherein the supply line is threaded through the arranged in the bottom passage opening. It can be a single-pole or multi-pole junction box, wherein in the case of a single-pole junction box at least two junction boxes per solar module are provided. Frequently, however, the two output lines of a solar module are connected via a common junction box. In the junction box further not relevant to the invention components, in particular electrical components such as diodes, circuit boards, etc. may be arranged, which will not be discussed here. The electrical connections within the junction box can be carried out via various connection techniques such as plug-in, clamp and solder connections.

The can body includes a bottom, the bottom surface of the bottom generally having a shape adapted to the solar module. The lower surface of the bottom may preferably be designed flat in the case of the implementation of the supply line through the backside encapsulation of a planar solar module, but also the bottom may be formed for the connection of a solar module via a side edge.

The passage opening in the bottom of the junction box can be made very small, so that just the implementation of the supply line is possible, but it can also extend over the entire inner box area. The can body must by no means have vertical side walls arranged on the ground. It can have almost any floor plan and be arched to the exterior or interior. The can body is preferably made of a weather- and UV-resistant plastic or of a metal, preferably aluminum. Plastic cans are characterized by low production costs, in particular by a conventional injection molding process. Aluminum is characterized by even higher UV and climatic resistance, and therefore has an even longer life.

The supply line is usually a contact strip without sheath, z. B. a flat, tinned copper ribbon. The connection line has at least outside the junction box on a sheath. Within the Junction box, the sheath is at least partially removed for electrical contact.

The connection line is usually guided by means of sealing bushing elements through the passage opening of the can body. The passage opening is usually in a side wall of the can body.

The adhesive layer on the lower side of the bottom can be designed, for example, as double-sided adhesive tape. It generally serves for a first fixation of the can body on the solar module before filling with the filler and a seal that limits the interior to be filled. Alternatively, no adhesive layer is present and the can body is filled with other means such. B. a clamp or a strap on the solar module fixed.

Depending on the intended use, hardening materials such as, for example, silicones, epoxy resin, PUR (polyurethane), which have an adapted viscosity during processing, can be used as liquid fillers.

In a preferred embodiment, the cross-sectional area, cross-sectional shape and length of the venting channels are formed such that the liquid filler does not escape through a venting channel into the exterior space when filling the interior space. While air can also escape through very small openings, by forming the cross-sectional area, the cross-sectional shape and the length of the venting channels, it is possible to ensure that the filler, which is generally liquid during filling, does not exit through a venting channel into the exterior space. In particular, the viscosity of the filler is to be considered. A vent channel with a flat, slot-shaped cross-section can be designed, for example, with a slightly larger cross-sectional area than a round vent channel of the same cross-sectional area. But there are also other factors such as adhesion between the filler and the surface of the vent channel, and the hydrostatic pressure, as well as the length of the venting channels to be considered. Specifically, it can be empirically determined, for example by experiments, how large a venting channel can be designed. If a vent channel must be made very small to ensure that no filler leaks, for example when using a very low-viscosity filler, so that no adequate venting effect is achieved, several venting channels can be adjacent to each other.

In a further preferred embodiment, the venting channels have a cross-sectional area of 0.1 to 10 mm ² , preferably 0.5 to 1.0 mm ² . These cross-sectional areas are particularly suitable for preferred fillers such as silicone and epoxy resin and ensure that a good venting effect and a bubble-free interior of the junction box is achieved and no filler emerges from the can. The viscosity of the fillers silicone and epoxy resin can also be influenced by appropriate additives and also by a change in physical parameters such as temperature or air humidity. In a preferred embodiment, a ventilation channel is formed through an opening in the bottom or in the side wall of the can body. As an inexpensive manufacturing method for the can body exists in particular the injection molding process, in which the direct formation of very small material recesses, which act as venting channels, is readily feasible. These venting channels preferably run within the can body.

In a further preferred embodiment, a venting channel is formed by a recess in the adhesive layer. The adhesive layer can be produced in various ways and, depending on the manufacturing process, recesses can be provided directly in the adhesive layer, which act as a venting channel. For example, the adhesive layer can be printed by a screen printing process on the underside of the floor facing the solar module, wherein recesses can be provided directly in the adhesive layer. A venting channel in the adhesive layer introduced in this way is then typically limited both by the adhesive layer and by the bottom of the can body and the surface of the solar module. An advantage of this embodiment is the relatively simple adjustment of the size of the vent channels with unchanged can body, so that for example with little effort can be made to adapt to fillers of different viscosities.

In a preferred embodiment according to one of the preceding claims, the adhesive layer is arranged only in the outer edge region on the bottom surface of the base facing the solar module. As a result, a volume is formed between the solar module and the lower surface of the bottom within the adhesive layer, which volume can be filled with the filler. By the filler can be achieved in the long term more stable and stronger connection with greater tightness between junction box and solar module in general than only with the adhesive layer, so that preferably the largest possible surface portion of the lower surface of the bottom is bonded to the filler and not with the adhesive layer.

In a preferred embodiment, the adhesive layer comprises several at a small distance arranged and adjoining segments, which together have a the at least one passage opening enclosing structure, whereby between two segments a recess in the adhesive layer is formed, which acts as a vent channel.

In a further preferred embodiment, the segments are formed by strips of a double adhesive tape having a thickness of 0.1 mm to 3.0 mm and a width of up to 1.0 mm to 10.0 mm.

In a further preferred embodiment of the junction box, a plurality of spacer elements are arranged on the bottom surface of the bottom facing the solar module, which are formed so that when placing the junction box on the solar module, a uniform distance of the bottom of the surface of the solar module is achieved. In this preferred embodiment, the adhesive layer consists of a homogeneous adhesive layer of a curable adhesive. The use of a curable adhesive as well as the use of a double-sided adhesive tape for fixing the junction box on the solar module is possible. Since the curable adhesive, in contrast to the double-sided adhesive tape, does not define a distance between the base and the solar module and therefore does not provide a uniform layer thickness of the adhesive layer, a plurality of spacer elements are arranged in the outer region of the lower surface of the floor in this embodiment. For example, feet can be provided in the corner regions of the floor, with which the connection box is placed on the solar module. In a further preferred embodiment of the junction box, the bottom of the can body extends at least at one point of the circumference of the can body beyond a side wall of the can body out into the outer space and forms a base, but without unnecessarily increasing the volume of the junction box. Preferably, the base surrounds the entire can body. As a result, the floor area can be increased in such a way that a better adhesion of the junction box, as well as a higher impermeability to penetrating moisture is achieved.

In a further preferred embodiment, the adhesive layer is arranged only in the outer partial surface regions of the lower surface of the base and one or more ventilation channels are formed in the base in the inner surface regions not covered by the adhesive layer. If there is a base with an adhesive layer only in the outer area, the space between base, solar module and adhesive layer must be filled as completely as possible with the filler in order to achieve a maximum adhesive surface and a tight bond. As this space enclosed between the floor and the solar module is generally very flat, when filling this volume, air pockets may be present, especially in the corner areas. In this case, ventilation channels are therefore preferably formed in the base in the inner surface areas which are not covered by the adhesive layer.

In a preferred embodiment, the can body has a substantially quadrangular ground plan and a substantially quadrangular circumferential base, wherein in each of the four corner regions of the base a venting channel in the base or a venting channel in the adhesive layer is arranged.

In a preferred embodiment, the can body, when the can body is aligned with the top filling opening, has a vent opening at the level of the filling opening or above the filling opening. If the can body has a large-area lid opening, which also serves to fill the can body, then the air can escape upwards out of the internal volume and the lid opening simultaneously forms the filling opening and vent opening is, the can body preferably has a separate vent through which a majority of the displaced air can escape. This vent is located at the level or above the filling opening and thus above or at the filling level, to which the can body is usually filled with filler. Since the filler does not escape against gravity and must escape through the vent much of the displaced air, the vent preferably has a larger cross-sectional area than a single vent channel. Vent opening and venting channels therefore differ significantly in the location and in their function and preferably also in size.

In a preferred embodiment, the can body is formed in one piece, wherein at least one filling opening is present. In the case of a one-piece can body connecting lead and supply line are preferably connected to each other via a plug connection, which takes place by placing the can body using other components.

In a further preferred embodiment, the can body is formed in two parts and has a bottom part and a lid part, wherein the filling opening preferably corresponds to the lid opening of the bottom part. In this embodiment, the interior is still after placing the junction box on the solar module and performing connection and supply line accessible and it can be done, for example, a solder joint of the lines. The lid opening can simultaneously represent the filling opening when the can is filled in the open state. Likewise, however, the two-part junction box can be filled in the closed state, and the cover part and / or the bottom part in this case have the filling opening. The cover part can be designed plan and serve only to close the bottom part, but it can also have a side wall. The cover part may also consist of the same or a different material as the bottom part.

In a further preferred embodiment, the bottom part and the cover part are connected to one another via a hinge. Lid and bottom part can basically be present in two separate units. In a preferred embodiment, however, the bottom part and cover part are connected to each other via a hinge, whereby the assembly of the cover part and the closing of the junction box is simplified. The connection between the cover part and bottom part is preferably formed as a film hinge, a thin-walled compound, often in the form of a fold, which allows by their flexibility limited rotational movement of the connected parts, whereby on the hinge side of the junction box, a tight connection is achieved. The connection of the bottom part and the cover part may be formed, for example, as a screw connection or a latching bracket and hook connection. Particularly preferred is a snap connection, wherein a joining part elastically deformed when closing the box and then hooked releasably or permanently. Between the lid and bottom part may also be provided a seal, for. B. made of rubber.

The invention also relates to a solar module with a junction box, characterized in that the junction box is designed according to one of the preceding claims.

The inventions will be described below with reference to the 1 - 5 explained in more detail, in which schematically embodiments of the junction box according to the invention are shown.

Show it:

1 : Vertical cross section through a junction box without base

2 : Vertical cross section through a junction box with socket

3 : Horizontal cross section through the junction box in section plane AA 'according to 2 Embodiment 1

4 : Horizontal cross section through the junction box analogue to 3 Embodiment 2

The figures merely illustrate the principle of the invention and are not to scale. Furthermore, only features relevant to the invention are shown.

It shows 1 starting from a horizontal orientation of the solar module ( 2 ) a vertical cross section through an embodiment of a junction box according to the invention ( 1 ) without socket ( 18 ) with a solar module ( 2 ), or, the back encapsulation layer with a passage opening ( 15 ) for the supply line ( 8th ) of the junction box ( 1 ). The junction box ( 1 ) has a lid part ( 3 ) and a bottom part ( 4 ) with a floor ( 5 ) and a side wall ( 6 ) and is connected to the ground ( 5 ) on the solar module ( 2 ), wherein between solar module ( 2 ) and lower surface of the soil ( 12 ) an adhesive layer ( 11 ) with a recess ( 17 ) is provided. The bottom part ( 4 ) has a through hole ( 16 ) on. Along the dotted lines, the air when filling the can from the interior ( 13 ) in the outdoor area ( 14 ) escape.

Within the junction box, the supply line is, for example, by a solder connection to the connecting line ( 10 ), which through a passage opening ( 9 ) in the side wall ( 6 ) of the bottom part ( 4 ) is guided.

2 shows in a similar manner a vertical cross section through a further embodiment of a junction box according to the invention. This junction box is different from that in 1 by having a socket ( 18 ), in which a through-bore ( 16 ) is arranged, but no recess in the adhesive layer ( 17 ) is available. Furthermore, in 2 a sectional plane AA 'drawn. The corresponding section shows 3 ,

3 shows a horizontal section in the sectional plane AA 'from 2 at the level of the passage opening in the side wall in the case of a junction box ( 1 ) with a square floor plan. Within the hatched shown side wall is located from outside to inside an inner part of the soil ( 5 ) to which the passage opening in the floor ( 7 ) as well as the passage opening in the solar module ( 15 ), or whose Rückseitenverkapselungsmaterial is located, through which the supply line ( 8th ) in the junction box ( 1 ) and with the supply line 10 connected is. Outside the hatched side wall ( 6 ) is the base ( 18 ) on its underside an outer circumferential adhesive layer ( 11 ), which is shown by dashed lines. Between side wall ( 6 ) and adhesive layer ( 11 ) are within the of the adhesive layer ( 11 ) covered area ( 11 ) in the corners venting channels ( 19 ) in the socket.

4 shows in a similar manner a horizontal section through a junction box according to the invention with a base in a further preferred embodiment, which differs from the embodiment in FIG 3 differs in that no venting channels ( 19 ) are arranged in the base, but ventilation channels through recesses in the adhesive layer ( 17 ) consisting of several spaced segments ( 20 ) is formed.

The junction box according to the invention can be mounted faster and more reliably on a solar module compared to a junction box according to the prior art. It is achieved a better mechanical connection with the solar module, as well as a higher density, so that a longer life can be achieved.

LIST OF REFERENCE NUMBERS

1

junction box

2

solar module

3

cover part

4

the bottom part

5

ground

6

sidewall

7

Feedthrough opening for supply line

8th

supply line

9

Passage opening for connecting cable

10

connecting cable

11

adhesive layer

12

bottom surface of the soil

13

inner space

14

outer space

15

Passage opening in the solar module

16

Venting channel in the bottom part

17

Recess in the adhesive layer

18

base

19

Venting channel in the base

20

Segment of the adhesive layer

Claims (17)

Junction box ( 1 ) for a solar module ( 2 ) with a can body, which at least one passage opening ( 9 ) for the implementation of a connecting line ( 10 ) and a filling opening for filling a liquid filler, wherein the can body a bottom ( 5 ) for mounting on the solar module ( 2 ), which at least one passage opening ( 15 ) for the implementation of at least one supply line ( 8th ), optionally with an adhesive layer ( 11 ) on the solar module facing lower surface of the soil ( 12 ) is arranged, which covers at least a portion of the surface of the bottom, wherein through the can body, the passage opening ( 10 ), the adhesive layer ( 11 ), the filling opening and the solar module an interior ( 13 ) and an outdoor space ( 14 ) are defined, characterized in that when aligning the can body with overhead filling opening one or more venting channels below the filling opening in the wall of the can body ( 3 ) or in the adhesive layer ( 11 ) are arranged, which the interior ( 13 ) and the outdoor space ( 14 ), so that when filling the interior ( 13 ) with a liquid filler air through a ventilation channel in the outer space ( 14 ) can escape. Junction box according to the preceding claim, wherein the cross-sectional area, cross-sectional shape and length of a ventilation channel are formed so that the liquid filler when filling the interior ( 13 ) not through the vent channel into the outer space ( 14 ) exit. Junction box according to one of the preceding claims, wherein the venting channels have a cross-sectional area of 0.1 to 10 mm ² , preferably 0.5 to 1.0 mm ² . Junction box according to one of the preceding claims, wherein a venting channel through an opening in the bottom ( 16 ) or in a side wall ( 6 ) of the can body is formed. Junction box according to one of the preceding claims, wherein a ventilation channel ( 17 ) through a recess in the adhesive layer ( 11 ) is trained. Junction box according to one of the preceding claims, wherein the adhesive layer ( 11 ) only in the outer edge region on the solar module facing lower surface of the soil ( 12 ) is arranged. Junction box according to one of the preceding claims, wherein the adhesive layer ( 11 ) a plurality of closely spaced and adjoining segments ( 20 ), which together form one of the at least one bushing opening ( 7 ) have an enclosing structure, whereby between two segments ( 20 ) each have a recess in the adhesive layer ( 17 ) is formed, which acts as a venting channel. Junction box according to the preceding claim, wherein the segments ( 20 ) are formed by strips of a double adhesive tape having a thickness of 0.1 mm to 3.0 mm and a width of up to 1.0 mm to 10.0 mm. Junction box according to one of claims 1 to 6, wherein on the solar module facing lower surface of the floor ( 12 ) a plurality of spacer elements are arranged, which are formed so that when placing the junction box ( 1 ) on the solar module ( 2 ) a uniform distance of the lower surface of the soil ( 12 ) from the surface of the solar module ( 2 ) and wherein the adhesive layer ( 11 ) is formed by an adhesive layer of a curable adhesive. Junction box according to one of the preceding claims, wherein the floor ( 5 ) at least at one point of the circumference of the can body ( 1 ) via a side wall of the can body ( 1 ) out into the outdoor area ( 14 ) and a pedestal ( 18 ) trains. Junction box according to the preceding claim, wherein the adhesive layer ( 11 ) only in the outer partial surface areas of the lower surface of the base ( 18 ) is arranged and one or more ventilation channels in the base ( 19 ) in the non-adhesive layer ( 11 ) covered inside surface areas are formed. Junction box according to one of the preceding claims, wherein the can body has a substantially quadrangular plan view and a substantially quadrangular circumferential base ( 18 ), wherein in the four corner regions of the base in each case a ventilation channel in the base ( 19 ) or a venting channel in the adhesive layer ( 17 ) is arranged. Junction box according to one of the preceding claims, wherein the can body at the top of the filling opening has a vent opening in the height of the filling opening or above the filling opening. Junction box according to one of the preceding claims, wherein the can body is integrally formed. Junction box according to one of the preceding claims, wherein the can body is formed in two parts and a bottom part ( 4 ) and a lid part ( 3 ), wherein the filling opening preferably the lid opening of the bottom part ( 4 ) corresponds. Junction box according to the preceding claim, wherein bottom part ( 4 ) and lid part ( 3 ) of the junction box ( 1 ) are connected to each other via a hinge. Solar module with a junction box ( 1 ), characterized in that the junction box ( 1 ) is formed according to one of the preceding claims.

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