EP3111551A1

EP3111551A1 - Photovoltaic module

Info

Publication number: EP3111551A1
Application number: EP15707913.8A
Authority: EP
Inventors: Josef Joachim Gmeiner
Original assignee: Individual
Current assignee: Individual
Priority date: 2014-02-28
Filing date: 2015-02-26
Publication date: 2017-01-04
Also published as: US20160365831A1; WO2015128433A1; CA2940782A1; DE102014102729A1; CN106031026A

Abstract

The invention relates to a photovoltaic module (1) having a frame (2) made of profiled struts (3a, 3b, 4a, 4b) and a composite (10) which is fastened to the frame (2) and comprises a plurality of photovoltaic cells and at least one transparent layer, preferably an EVA layer, applied to the photovoltaic cells and/or a transparent glass panel. The photovoltaic module (1) according to the invention is characterised in that a spacer device (20) fastened to the frame (2) is spaced apart from the upper face (11) of the composite (10) and also spaced apart from the end face (15) of the composite (10), such that between the spacer device (10) on the one hand and the upper face (11) and the end face (15) of the composite (10) on the other hand a continuous path (28) is provided, by means of which water, in particular rainwater, can run off. The invention further relates to a method for processing a known photovoltaic module.

Description

Photovoltaic module

Photovoltaic modules typically include photovoltaic cells on which an EVA (ethylene vinyl acetate) layer and a final glass sheet are applied. On the underside, a so-called Tedlar film with at least one polyvinyl fluoride layer (PVF) is usually provided (so-called backsheet), which is intended to protect the film on the underside from environmental influences. In addition to high UV resistance, the Tedlar film serves as a moisture barrier.

On the edge side, this composite comprising cells, EVA layer, glass pane and Tedlar foil, is accommodated by a surrounding aluminum frame, consisting mostly of four aluminum profile struts, wherein a cross-sectionally U-forming seal between the composite cells / EVS / glass pane / Tedlar and the frame is provided.

In the known photovoltaic modules, unwanted delamination occurs relatively frequently, with the above-mentioned composite of cells, EVA, glass and Tedlar foil dissolving. The causes can be of various kinds. For example, the seal can be or become defective, so that water, in particular rainwater, can penetrate into the space between the composite and the frame. This can result in a so-called ground fault, in which the generated solar power of the photovoltaic module no longer flows off via the connection lines, but a conductive connection between one of the two tracks of the cells, either the plus or the minus conductor, and the frame of Module is created. This constellation is life-threatening, as this current flows when the frame is touched by hand through the body of the person concerned.

When so much water enters the module through the defective seal that both the plus and minus conductors are connected together by the water, a short circuit is created, such as a Fire, including destruction of the diodes in the junction boxes of the modules.

It is an object of the present invention to minimize the risks described above.

This object is solved by the features of the independent claims.

The advantages of the invention can be seen, in particular, in that the spacer device creates a continuous path, which makes it possible for water running along the composite surface to drain through the intermediate spaces created according to the invention. For this purpose, the spacer device is designed such that a part of it spaced to the at least one edge top side of the composite and another part spaced from the opposite end face of the composite is mounted. This results in a continuous path between the spacer device and the upper edge side and the adjoining end side of the composite, so that no water, in particular in the form of rainwater, can collect more due to a faulty seal between the frame and the composite, which causes a or short circuit. The water can now rather run down to the outermost edge of the composite and over its front side. Preferably, the said path is provided at least on that end face of the composite, which is present in the installed state of the module, for example on a pitched roof, on the horizontally extending lower edge of the module.

With particular preference, an adhesive is introduced from the front side, which is not framed by the frame, between at least two layers of the composite. The term "layers" here means the layer of the photovoltaic cells, one or more of the films and / or the glass pane. stood. The adhesive penetrates between the glass sheet, the EVA layer (if present) and / or the cells and prevents diffusion of, in particular, water vapor, so that the composite remains intact over time. It also holds the layers together so that they do not "fray out" over time, thus preventing delamination.

According to a particularly advantageous embodiment, the spacer device comprises an elongated profile element which extends along said end face with said distance. It is of course possible that a plurality of adjoining and / or overlapping profile elements are used.

It has proven to be particularly advantageous if the spacer device comprises at least one bent and / or angled profile element, preferably L-shaped, which is preferably made of aluminum or VA steel.

In an L-shaped configuration of the first leg of this elbow is preferably attached to the frame and preferably extends at substantially constant distance along said end face of the composite, while this perpendicular extending second leg with preferably also constant distance over the top of the Edge of the network protrudes. The resulting through path leaves room for the passage of water between the second leg and the top of the composite and then subsequently between the first leg and the end face. Down the path is open, allowing water to drain along the outside of the frame.

The aforementioned embodiment also has the advantage that the said first and second legs of the L-shaped angle piece simultaneously form a UV protection for the above-mentioned, introduced from the front side adhesive, which otherwise in direct UV irradiation on the part of the Sun would become brittle over time so that moisture could penetrate the composite. Even with another curved and / or angled design, such a UV protection can be realized.

The spacer device is preferably fastened to at least one outer edge of a profile element of the frame, which is arranged below the plane in which the composite underside extends. Preferably here screws or rivets are used. The frame is well suited for such attachment of the spacer since it is stable and rigid.

Preferably, the relative position and in this case in particular the distance between the spacer device and the opposite frame, in the vicinity of which said end face of the composite is defined defined, for which in particular one or more spacers are used. For example, nuts, sleeves, washers or similar. used, which are pushed over a rivet, this rivet is used to attach the spacer means on the frame. As a result, the space between the spacer device and the opposite end side of the composite is then determined. When using an L-shaped elbow then the second leg does not need to be extra attached; Rather, it is sufficient if the first leg is attached to the profile element.

Particularly preferably, the composite is at its edge on the underside of the frame, so does not protrude beyond the frame. As a result, a secure storage of the composite is guaranteed. At the same time the front is relatively protected against frontal damage.

In particular, the invention also relates to a method with which known photovoltaic elements are machined in such a way, wherein the parts of a profile strut enclosing one end side and top side of the composite are removed. be milled and then the existing there seal is removed. Subsequently, a spacer device is attached to said profile strut at a distance from the exposed top of the composite and at a distance from the exposed end face of the composite. In this way, a continuous path is created between the spacer device and the upper side and the front side of the composite, can run through the water, especially rainwater.

The invention will be explained in more detail with reference to figures. Show it:

Fig. 1 is a plan view of a known photovoltaic module;

FIG. 2 is a side view of the photovoltaic module of FIG. 1; FIG.

Fig. 3 is a section along A-A in Fig. 1;

4 shows the enlarged detail B from FIG. 1;

5 is a plan view of a photovoltaic module according to the invention;

Fig. 6 is a side view of the photovoltaic module of Fig. 5;

Fig. 7 is a section along A-A in Fig. 5;

Fig. 8 shows the enlarged detail B of FIG. 6, and

9 shows the enlarged detail C from FIG. 5.

1-4, a known from the prior art photovoltaic module 101 (hereinafter also referred to as module 101) shown, the surrounding a frame 2 and a composite frame 2 10 includes. The composite 10 is known to have arranged in a plane photovoltaic cells on which an EVA film and on this a glass sheet is arranged. On the underside of the cells, a Tedlar film may be attached. In the present case, only the composite 10 as a whole is reproduced in the figures, ie its elements (cells, foils, glass pane) are not shown in detail.

On the edge side, the composite 10 rests on four interconnected profile struts, the transverse profile struts 3a, 3b and the longitudinally extending profile struts 4a, 4b, of the frame 2 (see Fig. 1). The transverse profile strut 3a is defined herein as the one that o.ä. When installing the module 101 on a pitched roof. whose horizontal lower edge forms. Water, which hits the module 101, thus runs on the glass in the direction of this profile strut 3a.

In the present case, the frame 2 has a circumferential double-walled construction as seen in cross-section, the elongated side walls 5a, 5b extending perpendicular to the photovoltaic cells and the walls 6a, 6b extending perpendicularly to the side walls 5a, 5b one

- Again seen in cross section - form cavity 7. Angle connectors 13 for connecting in each case two profiled struts 3 a, 3 b and 4 a, 4 b arranged perpendicular to one another are inserted into this cavity 7 into the four corner regions (see FIG. 4). The walls 6a, 6b protrude beyond the cavity 7 inwardly toward the center of the frame, the upper wall 6b supporting the composite 10 from below (Figure 3).

At the top of the frame 2, a peripheral frame leg 8 is provided parallel to and spaced from the wall 6b, which is connected to the wall 6b via an extension 5c of the side wall 5b. The frame leg 8, the extension 5c and the wall 6b form a circumferential recess 9, in which the composite 10 is inserted. In perfect condition of the module 1, there is no direct contact of the composite 10 with the Instead, a seal 14 is introduced into the trough 9, which has a substantially U-shaped cross-section (see Fig. 3).

If said seal 14 is faulty or leaking over time, water will penetrate into the well 9, resulting in end-on delamination of the composite 10 and unwanted electrical short circuits or the like. can lead.

Accordingly, the invention proposes a photovoltaic module 1 (or just called module 1) according to FIGS. 5-9, which compared to the known photovoltaic module 101 according to FIG. 1 -4 has some modifications, which will be based on the following the - be carried out starting from a module 101 - process steps to be performed. For this purpose, a known photovoltaic module 101 (the modified photovoltaic module according to the invention 1 is given the reference numeral 1, which is used in the following), whose o.g. potential or already occurring vulnerabilities should be eliminated.

First, the photovoltaic module 1 is cleaned so that dirt does not adversely affect the final result.

Thereafter, the frame 2 is milled, the extension 5c and the frame leg 8 of the profile brace 3a are removed. In addition, the defective seal 14 is peeled off at the end face 15 and the edge-side exposed upper side 1 1 of the composite 10 and the exposed end face 15 of the composite 10 is cleaned. This serves u.a. also to the fact that in a previously defective seal 14 incurred verdigris is eliminated.

Between the glass pane, the EVA layer, the photovoltaic cell layer and / or the Tedlar film of the composite 10, an adhesive 16 is then inserted from the exposed front side 15 of the composite 10. presses that these layers stick together and possibly the front side is closed. The layers thus remain firmly together and do not split. Also, no water vapor can penetrate.

After the adhesive 16 has hardened, drilled holes 18 are bored in the side walls 5a and 5b of the profile brace 3a of the frame 2, which are used to receive rivets, screws or the like. (s.u.) are suitable. In this case, in each case two boreholes 18 are each provided with each other, wherein at least two such pairs of boreholes 18 are drilled at the two outer ends of the profile brace 3a. In the intermediate section also such pairs of holes can be provided.

Subsequently, a spacing device 20 is attached to the profile strut 3 a at a distance d 2 (see FIG. 7), for example 8 mm, to the end face 15 of the composite 10. The spacer device 20 according to the embodiment of FIGS. 5-9, an L-shaped elbow 21 having a first leg 22 which - when the elbow 21 is attached to the frame 2 - parallel to the end face 15 and the side walls 5a, b extends and a second leg 23, which is aligned at right angles to the first leg 22 and protrudes beyond the cavity 7 and the composite 10, wherein a distance d1 (see Fig. 7) to the top 1 1 of the composite 10 is maintained. The distance is for example 1 or 2 mm. The first leg 22 of the elbow 21 is fixed by means of double rivets 25 on the profile strut 3a, wherein the mutual distance d2 is determined by a respective spacer 26 placed between them, here in the form of a hexagon nut.

The second leg 23 also provides an effective UV protection for the adhesive 16, since the solar radiation can not reach the adhesive 16 directly.

By the two distances d1 and d2 is a continuous path 28 between the spacer 20 and the exposed top 1 1 of the composite 10 and the end face 15 created, through which the module 1 downstream water can pass. This water, which accumulates in the module 101 according to the prior art on the seal 14 between the frame leg 8 and glass and penetrates in defective recess 14 in the trough 9, can now proceed unhindered along the end face 15 of the composite 10. In other words, the trough 9 is removed by the removal of frame leg 8 and extension 5c, instead providing a continuous path 28 for passage of the otherwise jamming water. The water can drain down through the path 28 along the profile strut 3a.

In FIG. 8, which shows a side view of a section of a photovoltaic module 1 according to the invention, the path of the water through the path 28 is indicated by means of an arrow f1. The hidden in the side view shown path 28 is shown in phantom here.

The invention relates both to the method for processing existing photovoltaic modules and to the resulting modules themselves.

The invention has been explained in more detail with reference to an embodiment. Modifications within the claims are readily possible. Thus, it is possible, for example, that more than one end face according to the invention is provided with a spacer device. It is also conceivable that only one end side section or a plurality of spaced-apart end side sections of the photovoltaic module are protected by one or more spacer devices. Instead of an L-shaped angle piece, differently shaped profile elements can also be used in cross-section, for example those with a partially circular cross-section. LIST OF REFERENCES

Photovoltaic module

01 known photovoltaic module

frame

a, b profile strut

a, b sidewalls

c extension

a, b walls

cavity

frame legs

trough

0 composite

1 top of the composite

3 angle connector

4 seal

5 front side

6 glue

8 holes

0 spacer device

1 L-shaped angle piece

2 first leg

3 second leg

5 double rivets

6 spacer

8 path

Claims

Patent claims

1 . Photovoltaic module (1) with a frame (2) constructed from profiled struts (3a, 3b, 4a, 4b) and a composite fastened to the frame (2)

(10), which comprises a multiplicity of photovoltaic cells and at least one transparent layer applied to the photovoltaic cells, preferably an EVA layer, and / or a transparent glass pane, characterized in that a spacer device fastened to the frame (2) (20) spaced from the top

(1 1) of the composite (10) and spaced from the end face (15) of the composite (10) is mounted so that between the spacer means (10) on the one hand and the top (1 1) and the end face (15) of the composite ( 10) on the other hand, a continuous path (28) is present, can drain over the water, especially rainwater.

2. Photovoltaic module according to claim 1, characterized in that an adhesive (16) of the not framed by the frame (2) end face (15) forth between at least two layers of the composite (10), in particular between the layer of photovoltaic cells , one or more of the films and / or the glass sheet is introduced.

3. Photovoltaic module according to at least one of the preceding claims, characterized in that the spacer means (20) comprises an elongate profile element, preferably of metal, which extends along said end face (15) with said distance (d2).

4. Photovoltaic module according to at least one of the preceding claims, characterized in that the spacer device

(20) at least one bent and / or angled profile element

(21), preferably L-shaped, preferably of aluminum.

5. Photovoltaic module according to at least one of the preceding claims, characterized in that a leg (23) of an L-shaped angle piece (21) of the spacer device (20) with a substantially constant distance (d1) to the top (1 1) of the Composite (10) runs.

6. Photovoltaic module according to at least one of the preceding claims, characterized in that the spacer device (20) on at least one profile strut (3a) of the frame (2) is fixed, preferably by means of fastening means in the form of screws or rivets (25).

7. photovoltaic module according to at least one of the preceding claims, characterized in that one or more spacers (26) define a substantially constant distance (d2) of the spacer means (20) to said end face (15).

8. Photovoltaic module according to at least one of the preceding claims, characterized in that the composite (10) is supported on the underside of the frame (2), which preferably projects beyond the at least one end face (15) of the composite (10).

9. A method for processing a photovoltaic module (1), the one of profile struts (3a, 3b, 4a, 4b) constructed frame (2) and in the frame (2) enclosed composite (10), which photovoltaic cells and at least a transparent layer, preferably an EVA layer, and / or glass pane applied to the photovoltaic cells, the method comprising the following steps:

- It is the frame (2) at least along a profile strut (3a) milled in the region of said enclosure and at least the framed there end face (15) and the bordered edge top side (1 1) of the composite (10) exposed;

- A spacer means (20) is at the said at least one profile strut (3a) spaced from the exposed edge top (1 1) of the composite (10) and at a distance to the exposed end face (15) of the composite (10) attached, so that between the spacer means (20) on the one hand and the top (1 1) and the end face (15) of the composite (10) on the other hand, a continuous path (28) is provided, can drain over the water, especially rainwater.

10. The method according to the preceding claim, characterized in that an adhesive (16) from the not framed by the frame (2) front side (15) forth between at least two layers of the composite (10), in particular between the layer of photovoltaic cells, one or more of the films and / or the glass pane is introduced.

1 1. Method according to at least one of the preceding method claims, characterized in that the spacer device (20) is selected such that it comprises at least one elongate metal profile.

12. The method according to at least one of the preceding method claims, characterized in that the spacer device (20) is selected such that it comprises a bent and / or angled profile element (21), preferably L-shaped, preferably made of aluminum.

13. The method according to the preceding method claim, characterized in that the L-shaped angle piece (21) comprising spacer means (20) is fixed to the frame (2) such that a leg (23) of the angle piece (21) with a Wesentli - Chen constant distance (d1) to the edge top side of the composite (10) extends.

14. Method according to at least one of the preceding method claims, characterized in that the spacer means (20) is fixed to a circumferential outer profile strut (3a) of the frame (2), preferably by means of screws or rivets (25).

Method according to at least one of the preceding method claims, characterized in that one or more spacers (26) for fixing the relative position of the spacer means (20) to the frame (2) are used at a substantially constant distance (d2) from the spacer means (20) to define said opposite end face (15).