DE102015106454A1 - Wavy element for receiving a plurality of solar cells and photovoltaic module - Google Patents

Abstract

A wavy element (1) and photovoltaic module for accommodating a plurality of solar cells (20), comprising a wave-shaped frame (4), the frame having four outer edges (15); an accommodating portion (5) formed integrally with the wavy frame for receiving a plurality of solar cells, the receiving portion defining a planar support surface; wherein the minimum distance of the receiving area to at least two outer edges (15) of the frame corresponds to at least half a period of the waveform and / or at least a distance of 3.5 cm; wherein the wave-shaped element is made of sheet metal and has a maximum thickness of 0.6 mm.

Description

Field of the invention

Embodiments of the present invention relate to a wave-shaped element for accommodating a plurality of solar cells, a photovoltaic module and a method for producing a wave-shaped element for accommodating a plurality of solar cells and a photovoltaic module. Embodiments are particularly directed to a wavy element for receiving a plurality of solar cells and a photovoltaic module, which can be installed inexpensively and without special tools on or as part of a corrugated metal roof.

Background of the invention

A building is constructed from a plurality of building components. The building components include in particular roof elements. Building components form the basic structure of a building and offer protection against environmental influences, such as rain, wind or solar radiation.

Photovoltaic systems with solar cells serve the direct conversion of solar energy into electrical energy. In countries with a high population density, photovoltaic systems are often connected to the public grid, so that the generated electrical energy can be fed directly into the grid. However, in countries with low population density and remote locations, this often does not make sense, as it would be too costly and expensive to build a public grid. In any case, in some countries, especially in provincial areas, there is no public electricity grid.

Examples of this problem are emerging markets. There are in many areas no power supply via the public electricity grid. However, there is also energy demand in such areas, for example, mobile phones are also widely used there. To charge the mobile phones, however, a power supply is necessary. Often there are diesel / gasoline generators for power generation in such areas.

The use of photovoltaic systems in such areas is due to the high solar radiation while appropriate, but not entirely unproblematic. The roofs are often made in lightweight construction, especially with the help of corrugated sheets. The high weight of conventional glass-aluminum modules on the usual lightweight roofs requires complex aluminum substructure. However, not only the solar cells of the photovoltaic plants themselves, but also the aluminum used for the substructure can represent a corresponding high value, which often falls victim to a theft.

It is therefore an object of the present invention to at least partially overcome the problems in the prior art. It is a particular object of the present invention to provide a cost-effective and technically easily attachable possibility to transform the energy provided by the sun into electrical energy, and at the same time substantially complicating a theft.

Brief description of the invention

• – einen wellenförmigen Rahmen, wobei der Rahmen vier Außenränder aufweist;
• – einen einstückig mit dem wellenförmigen Rahmen ausgebildeten Aufnahmebereich zur Aufnahme einer Vielzahl von Solarzellen, wobei der Aufnahmebereich eine ebene Auflagefläche definiert;
• – wobei der Mindestabstand des Aufnahmebereichs zu wenigstens zwei Außenrändern des Rahmens wenigstens einer halben Periode der Wellenform und/oder wenigstens einem Abstand von 3,5 cm entspricht;
• – wobei das wellenförmige Element ein Wellblech ist und eine maximale Dicke von 0,6mm aufweist.

These objects are achieved by the subject matter of the independent claims. According to one aspect, there is provided a wavy element for receiving a plurality of solar cells, comprising the following components:

• A wavy frame, the frame having four outer edges;
• - An integrally formed with the wavy frame receiving area for receiving a plurality of solar cells, wherein the receiving area defines a flat support surface;
• - wherein the minimum distance of the receiving area corresponds to at least two outer edges of the frame at least half a period of the waveform and / or at least a distance of 3.5 cm;
• - The wavy element is a corrugated sheet and has a maximum thickness of 0.6mm.

According to a further aspect, there is provided a photovoltaic module comprising a wave-shaped element as described herein and a plurality of solar cells disposed in the receiving area of the wave-shaped element.

As a receiving area, the flat support surface is understood, which is designed to receive the solar cells, for example. In the form of one or more solar units. A possibly provided projection around the receiving area surrounds the receiving area and is therefore no longer understood as belonging to the receiving area. In the case of a photovoltaic module, the receiving area can be understood in particular as the area that is actually covered by the one or more solar units. The distance from the receiving area to the outer edge of the frame is therefore understood in the case of the photovoltaic module regularly as the distance between the edge of the photovoltaic module to the outer edge of the frame.

As will be explained in more detail later, this feature combination allows the user and owner of a house with corrugated iron roof easily and without further structural help such. B. a drill or the like can fix the photovoltaic module on its roof by simply nailing in existing corrugated roof elements. The minimum distance between the edge of the wave-shaped element or photovoltaic module to the receiving area of the solar cells also guarantees that when driving nails into the sheet, the solar cells are not damaged.

In particular, the corrugated sheet can have a thickness of less than or equal to 0.5 mm, and in particular a thickness of 0.2 mm. This makes the nailing even easier. On the other hand, in many embodiments, for stability and transport reasons, the thickness of the corrugated sheet should be at least 0.1 mm.

In embodiments, the wave-shaped element or the photovoltaic module comprises a projection at least partially, preferably completely surrounding projection. This serves in particular to protect the glass edge of the solar unit introduced in the photovoltaic module.

• – einen ersten Teil und einen zweiten Teil, die entlang einer Fügenut zusammengefügt sind, und einen wellenförmigen Rahmen bilden, wobei der Rahmen vier Außenränder aufweist;
• – einen einstückig mit dem ersten Teil ausgebildeten ersten Aufnahmebereichsteil sowie einen einstückig mit dem zweiten Teil ausgebildeten zweiten Aufnahmebereichsteils, wobei der erste und zweite Aufnahmebereichsteil den Aufnahmebereich bilden, wobei einen Aufnahmebereich zur Aufnahme einer Vielzahl von Solarzellen ausgelegt ist und dazu eine ebene Auflagefläche definiert;
• – wobei der Mindestabstand des Aufnahmebereichs zu wenigstens zwei Außenrändern des Rahmens wenigstens einer halben Periode der Wellenform und/oder wenigstens einem Abstand von 3,5 cm entspricht;
• – wobei das wellenförmige Element aus Kunststoff gebildet ist.

In another aspect, there is provided a wavy element for receiving a plurality of solar cells, comprising:

• A first part and a second part, which are joined along a joining groove, and form a wave-shaped frame, wherein the frame has four outer edges;
• A first receiving area part formed integrally with the first part and a second receiving area part integrally formed with the second part, the first and second receiving area part forming the receiving area, a receiving area being designed to receive a plurality of solar cells and defining a planar supporting surface;
• - wherein the minimum distance of the receiving area corresponds to at least two outer edges of the frame at least half a period of the waveform and / or at least a distance of 3.5 cm;
• - Wherein the wave-shaped element is formed of plastic.

Also in this embodiment, the wave-shaped element or the photovoltaic module can be easily mounted on a roof. Since the significantly different thermal expansion coefficients of glass, which is regularly used as the upper protective layer over the solar cells, and plastic, however, can normally lead to problems in heating in the sun, the two-part design allows a positive attachment of the solar cells in the receiving area, wherein gluing or the like can be omitted regularly. Moreover, the manufacturing process for producing the two parts of the wave-shaped element may be identical.

In embodiments, the wave-shaped element or the photovoltaic module can have a receiving region partially, preferably completely, circumferential groove.

In embodiments of the wave-shaped element or photovoltaic module described here, the receiving region furthermore has at least one, preferably two recesses. These can serve the rear ventilation and thus regularly increase the energy yield of the photovoltaic module.

• – Zur Verfügung Stellen eines Bleches; und
• – gleichzeitiges Tiefziehen der Wellenform und des ebenen Aufnahmebereichs in einem Arbeitsschritt.

In another aspect, there is provided a method of making a corrugated corrugated sheet as described herein, comprising:

• - Providing a sheet; and
• - Simultaneous deep drawing of the waveform and the flat recording area in one step.

This has the advantage that the wave-shaped element can be produced in a single step from a conventional flat sheet.

In addition, a recess can be formed within the receiving area, for example by milling or punching. This can be done in the same or a further step.

According to a further aspect, there is provided a method of manufacturing a photovoltaic module, in which a plurality of solar cells are adhered to the receiving area of the wavy element produced as described herein. This is done in particular and in a simple and cost-effective manner with the aid of a double-sided adhesive tape. Alternatively, silicone can be used for bonding.

Generally, as described herein, the solar cells are commonly incorporated into the receiving area as solar units. A solar unit is understood as meaning the laminate of one or more solar cells embedded between a lower and an upper protective layer.

According to another aspect, there is provided a method of manufacturing a plastic wavy element as described herein Provided in which a first part of the wave-shaped element is injection-molded; and a second part of the wave-shaped element is injection-molded.

The division of the wave-shaped element into two parts and the simple production by means of an injection molding process allow the cost-effective production of a photovoltaic module as described herein. For this purpose, a multiplicity of solar cells, typically in the form of one or more solar units, are introduced into a receiving groove portion of the first and second part of the wave-shaped element, respectively at least partially, preferably completely encircling receiving groove. Then, the first part of the wave-shaped element is connected to the second part of the wave-shaped element at a joining groove. Possible types of connection are a snap lock, hot calking or gluing. This type of production enables a simple form-fitting attachment of the solar cells within the wave-shaped element, which thus absorbs the solar unit and prevents removal, such as in the case of theft. At the same time, this type of attachment does not lead to excessive stresses and shear forces when heated in the sun.

Other aspects, details, embodiments and advantages will become apparent from the dependent claims, the description and the attached drawings.

Brief description of the figures

Embodiments of the present invention are illustrated by way of example in the accompanying drawings.

1 shows a schematic three-dimensional view of a wave-shaped element according to an embodiment of the present invention;

2 shows a schematic three-dimensional view of a photovoltaic module according to an embodiment of the present invention;

3 shows a schematic cross section through the embodiment of the photovoltaic module according to 2 along the line AA according to an embodiment of the present invention;

4 shows a schematic three-dimensional view of a wave-shaped element according to another embodiment of the present invention;

5 shows a schematic three-dimensional view of a photovoltaic module according to another embodiment of the present invention;

6 shows a schematic cross section through the embodiment of the wave-shaped element according to 5 along the line AA according to an embodiment of the present invention; and

7 shows a schematic cross-section through an embodiment of a roof-mounted photovoltaic module according to an embodiment of the present invention.

Detailed description of the invention

According to one aspect of the invention, the wave-shaped element can be permanently installed on a building by simple means. In particular, the wave-shaped element can be nailed onto an existing roof element, for example, from corrugated iron.

The wave-shaped element as understood herein has a regular longitudinal wave structure with a constant period (distance between two maxima). Mathematically, the period corresponds to 2pi. In other words, the period represents the distance in the wave-shaped element in which the same structure repeats.

According to one aspect, the wave-shaped element has a receiving region, which is formed integrally with the frame of the wave-shaped element. According to one aspect of the invention, the minimum distance of the receiving area to at least two outer edges of the wave-shaped element is at least a half period and in particular at least a 3/4 period. Alternatively or additionally, the minimum distance of the receiving area to at least two outer edges of the wave-shaped element is at least 3.5 cm and in particular at least 5 cm. The recording area serves to accommodate a plurality of solar cells. The solar cells are typically mounted in the form of a solar unit. The solar unit is sometimes referred to as "laminate", and should be understood as the entirety of the solar cells and their encapsulation.

The inventor of the present disclosure has found that, particularly in emerging markets, a simple and inexpensive mounting of photovoltaic modules is needed, while being sufficiently secure against theft. According to the invention, therefore, the photovoltaic module is formed from a one-piece wave-shaped element made of sheet metal or of a two-piece wave-shaped element made of plastic. The inventor proposes the attachment of the Photovoltaic module a hitherto completely unusual way before, namely the simple fastening example. On a roof with the help of nails. However, it has been found that the hammering of a nail through the frame formed in the wave-shaped element can regularly lead to breakage in the receiving area attached high-sensitivity solar cells or the solar unit (such as the sun-side tempered glass), as by the Hammering caused shocks to be passed.

The inventor of the present invention has therefore found, in numerous experiments, that the minimum distance of at least half a period or at least 3.5 cm mentioned herein prevents damage to the solar unit since the shocks at that distance are sufficiently attenuated. In addition, the minimum distance also serves to ensure that a simple slipping off the nail head with the hammer does not lead to a direct impact on the solar cells.

In addition, in the case of a wavy element made of sheet metal, the thickness of the sheet used therefor should be less than 0.6 mm, in particular less than or equal to 0.5 mm, and preferably less than or equal to 0.2 mm. This has the advantage that conventional nails without the use of drills or the like can be driven through the plate at all by means of a hammer. It is this. It is important to understand that in the typical field of application of the present invention, technical aids, such as a drill, or even a 220V or 110V AC connection to operate the drill, are not available on a regular basis. It may therefore be of fundamental importance to the consumer that the attachment of the photovoltaic module on the corrugated roof by the simple penetration of nails is possible. Not only is this possible with the stated maximum thicknesses of the sheet, but also numerous experiments have shown that, together with the minimum distance of half a period of the waveform or of at least 3.5 cm, the vibrations on the way towards the solar cell are sufficiently mitigated so that the solar cells themselves are not harmed.

As an alternative to placing the wave-shaped element on an existing roof element, it can also itself act as part of the building and in particular of the roof. Typical roofs, especially in emerging countries, consist of several interconnected corrugated sheets. According to one aspect of the invention, the wave-shaped element can be integrated into the roof structure of a building like a conventional roof element. The integration into the structure of the building has the consequence that a simple theft of the photovoltaic module is prevented because the photovoltaic module is firmly connected to the building. In addition, the integration of the solar cells into the building structure has the consequence that the solar cells are well protected against mechanical influences and environmental influences such as, for example, solar cells. Wind are protected.

According to embodiments, the photovoltaic module has a wave-shaped element described herein, on which a plurality of solar cells in the form of one or more solar units are arranged.

The solar unit typically has at least one electrical connection element, a lower protective layer and an upper protective layer. The lower protective layer is firmly connected to the solar cells and arranged below the solar cells. It consists for example of special plastic film The lower protective layer comes in the formation of the photovoltaic module with the receiving area of the wave-shaped element, for example. By gluing the solar unit in permanent contact. The lower protective layer can then be firmly connected to the receiving area. The upper protective layer may consist of glass, in particular of surface-treated glass such as, for example, mirror-poor and / or specially hardened glass.

The arrangement of the plurality of solar cells typically has a planar shape. Flat in this case means that the extent in two coordinate axes of a Cartesian coordinate system is greater by at least an order of magnitude than in the third coordinate axis. In particular, the solar cells are flat solar cells, typically less than 6 inches (15.6 cm) in size, and / or have a thickness in the range of less than one millimeter.

According to embodiments of the present invention, so-called 1/3 or 1/4 solar cells are used. These are, for example, 5 or 6 inch solar cells, which, however, were separated into 3 or 4 equal parts (the separation being parallel to the finger alignment and thus perpendicular to the busbar alignment of the solar cells). In a typical arrangement of 2 rows of 18 solar cells each (in particular 1/3 solar cells), this has the particular advantage that the output voltage of the photovoltaic module is 18 V_mpp (since each cell in the unheated state delivers 1/2 V_mpp), the voltage of the Photovoltaic module then actually drops in operation regularly to about 12-14 volts. This corresponds to the voltage required to charge a car battery. In typical embodiments, such an arrangement provides a nominal power of 50 Wp.

By adapting the photovoltaic module to a building structure and in particular a Roof structure at least outside the receiving area of the photovoltaic module is made possible that the photovoltaic module can be integrated into the building. As already mentioned, the photovoltaic module can either be mounted on an existing roof element, or it can be used as an alternative to a conventional roof element.

In addition, a positive connection between the wave-shaped element and the building structure, such as the roof, on which the wave-shaped element is mounted, allows. In this way, the photovoltaic module can withstand high mechanical stresses when used as intended. Also environmental influences can possibly be better absorbed by the.

If, for example, the roof of a building is formed from a plurality of corrugated metal roof elements, then the wave-shaped element described here is adapted to this structure in that it also has a corrugated sheet structure in the edge regions. In particular, it can replace such a conventional corrugated roof tile element; Alternatively, the wave-shaped element can also be placed on an already existing corrugated roof element and fixed there.

It is generally desired in the manufacture of photovoltaic modules, edge regions of the attachment, which do not serve to generate electricity from solar energy but only the mechanical attachment, as narrow as possible. In this way, the largest possible areas of the photovoltaic modules are available for the arrangement of solar cells.

The present invention deliberately deviates from this. According to one aspect of the present invention, the edge of the wave-shaped element or the solar module is deliberately chosen at least as half a period of the waveform or at least 3.5 cm. As already explained, it is found that this distance regularly suffices that nails can be hammered by the wave-shaped element in the outer region of the edge region without this causing a rupture of the solar cells located in the receiving region.

However, in typical embodiments, the size of the edge region is also no greater than twice the period of the waveform and / or no larger than 15 cm. Although this ensures the possibility of simple attachment with the aid of a hammer, at the same time it does not take up too much space which can not be used to generate electricity.

The shape of the wave-shaped element may be rectangular. A typical dimension has a width (i.e., an extension in the direction of the undulations) of between 40 cm and 90 cm, in particular between 45 cm and 55 cm. Just an upper limit such as 55 cm has been found to be practicable in order to be able to comfortably transport the wave-shaped element or the photovoltaic module under the arm. On the other hand, too narrow arrangements are too inefficient.

A typical length of the wave-shaped element or photovoltaic module (i.e., the extent parallel to the waveform) is between 100 cm and 220 cm, typically between 120 cm and 140 cm.

The photovoltaic module comprises several solar cells. By the electrical connection elements, of which the building component has at least one, both the solar cells connected to each other and a connection can be made out of the photovoltaic module out. Preferably, at least one electrical connection element such as a cable (i.e., a power connection for the two poles) projects out of the solar unit between the lower protection layer and the upper protection layer. This allows, for example, a simple connection of the solar cells to the mains of a building.

For example, semicrystalline, crystalline flexible or printed solar cells can be used as solar cells. Although flexible solar cells are more expensive to purchase, they are also less susceptible to mechanical influences. A mixed arrangement is conceivable. Crystalline solar cells are currently the most common solar cells.

Corrugated iron elements are often used and installed especially in emerging markets. Typical corrugated sheet members have a corrugation of 76/18, that is, a waveform having a period of 78 cm and a height (i.e., wave minimum to maximum shaft) of 18 cm.

The photovoltaic module can be used in particular as a stand-alone system. This means that the photovoltaic module will not be connected to a public power grid. Rather, the generated electrical energy is consumed directly on site. The electrical connection element of the photovoltaic module of the present description is typically formed from two wires which are provided without a plug or socket.

The invention will now be described in detail by way of example with reference to the embodiments shown in the figures. This designates in the figures the same reference number the same element.

In the embodiments schematically illustrated by the figures, the wave-shaped element 1 through the waveform in the frame 4 adapted to a typical corrugated roof structure. The frame includes four outer edges 15 , Without limitation to the embodiments shown, the receiving area 5 into which the multitude of solar cells 20 can be recorded, just. The recording area 5 typically has a fastening bar 10 which is designed to receive the solar cells. The solar cells can typically be taken in the form of one or more solar units. As will be described in more detail later, the solar cells are typically adhered, in particular in the embodiments in which the wave-shaped element consists of sheet metal.

As in 1 is indicated, it is basically and without limitation to the embodiment of 1 possible that the receiving area has one or more recesses. This can serve the better ventilation of the solar cells, which in turn can be beneficial for the energy yield. The one or more recesses are thus behind the solar cells and in particular allow cooling of the solar cells by the ambient air. This is sometimes important for the efficiency of solar cells, which decreases with increasing temperatures. The recesses are in 1 with the reference number 11 designated. Between several recesses, a gutter, the playful in 1 is shown and with the reference numeral 12 is provided, be provided.

The pick-up area is typically made in the same step, in which the waveform is also placed in a previously flat sheet, typically by deep-drawing or stamping. In addition, then the one or more recesses can be introduced into the wave-shaped element, for example by punching, milling, or cutting.

2 now shows an embodiment of a photovoltaic module 2 , In the wavy element 1 is a variety of solar cells 20 brought in. Typically, the solar cells 20 in one or more solar units 21 introduced into the wave-shaped element.

The solar cells are central in the wave-shaped element according to the exemplary embodiments of the figures 1 arranged. The frame 4 of the photovoltaic module remains free of solar cells.

In addition, an electrical connection element 3 be present in the form of a connection cable, which of the solar cells 20 from the wave-shaped element 1 protrudes. The electrical connection element is typically soldered directly on the back of the solar unit to the executed busbars of the solar cells. In embodiments, the electrical connection element, such as a cable, is led out through a sealed hole on the back side of the wave-shaped element. For sealing silicone can be used. The connection element is guided, for example, along a metal bead for mechanical protection to the outer edge of the photovoltaic module. This makes it possible to easily guide the cable during installation in the interior of the roof.

It is quite generally and without reference to terminal guide a preferred embodiment of the present disclosure that the photovoltaic module is provided without a junction box. The connection element consists in numerous embodiments exclusively of a power cable, which consists exclusively of the two mutually insulated lines for the two different poles.

The understanding underlying the present invention will be apparent from the schematic cross-sectional representation of 3 clarifies that along the dashed line AA 2 is shown. Basically, the wave-shaped element has a waveform as shown in the figures. This is typically to be understood as the framework 4 has a waveform. Without limiting to the figures shown, the receiving area according to embodiments of the invention is flat and thus in particular without waveform.

Without limitation to the figures shown, the receiving area 5 be increased relative to the rest of the wave-shaped element. This should be understood that the height of the fastening web 10 is larger compared to the maximum height of the waveform. This allows the problem-free attachment to existing corrugated metal roof panels. In particular, the receiving area can be raised at least 1 mm in relation to the maximum height of the shaft. It is typical, however, that the receiving area protrudes no more than 10 mm above the maximum height of the shaft.

The waveform allows the photovoltaic module 1 overlapping with other building components, both those with solar cells, as well as with conventional corrugated iron elements to arrange. In this way, a positive connection between the wave-shaped element 1 and adjacent components. This considerably increases the stability of the overall composite. Thereby become the solar cells 20 or the solar unit 21 less mechanically stressed, since acting forces can be absorbed by the overall composite.

As shown in the schematic cross-sectional illustrations of the accompanying figures, according to embodiments, the waveform is at a low position 15 within the wave-shaped element into a projection which forms the receiving area. The low position 15 at which the waveform transitions into the projection is typically close to a minimum of the waveform, especially at a distance in the range of +/- 1 cm of the minimum, preferably at the minimum itself.

The receiving area is typically formed within the projection. The receiving area usually has a height of at least 3/4 of the wave height, preferably approximately the wave height itself. The attachability to existing roof elements made of corrugated iron is thus guaranteed.

In addition, the projection ensures increased rigidity of the wave-shaped element or of the photovoltaic module. This is even more true in synergy with the normal way rectangular shape of the receiving area. This leads to an easier transportability or to a reduced risk of damage of the photovoltaic module. In addition, a water drain is formed by this geometry next to the receiving area, which is groove-like around the low position 15 extends and in use is able to dissipate the water along this groove.

In embodiments of the present invention, the receiving area is 5 by a projection 12 at least partially, typically completely surrounded. This has several advantages. On the one hand, it serves the rigidity of the wave-shaped element or of the photovoltaic module, in particular in the region of the receiving region. In addition, the projection is typically dimensioned such that its height is above the height of the solar unit. Opposite the fastening bridge 10 the receiving unit is the projection 16 typically increased, in particular in the order of +/- 5 mm with respect to the top of the solar unit, in particular, the projection is at least at the same height as the solar unit. In further embodiments, the projection is increased by at least 1 mm with respect to the solar unit. During the transport of the photovoltaic module, the projection therefore serves to protect the solar unit, and in particular the typically hardened glass on top of the solar unit, which can otherwise be easily destroyed just in the edge region of the solar unit.

The photovoltaic modules according to the invention can in particular be island systems which provide an output voltage of approximately 12-14 V during operation. Their design is therefore regularly with 18 V_mpp. It may be provided to use them with the help of a charge controller for charging electrical equipment without an additional interconnection is necessary. In principle, however, it is also possible to interconnect the photovoltaic module differently, so that it can be connected to inverters and forms a power supply for a building or is suitable as a power supply for a grid feed.

In particular, in the embodiments described herein, in which the wave-shaped element is made of sheet metal, the solar cells are firmly connected in the receiving region, for example, by means of an adhesive. As in 3 is schematically illustrated, the solar unit 21 with the help of a double-sided adhesive tape 23 permanently with the wave-shaped element 1 connected, bringing the photovoltaic module 2 is formed. Due to the similar coefficients of thermal expansion of glass and sheet metal, the splice is not subjected to constant mechanical stress during the course of the day. The solar cells are thus permanently fixed in the wave-shaped element and typically only by use of force herauslösbar again. This makes a selective theft of solar cells almost impossible.

According to embodiments, the wave-shaped element is formed in two parts. This is particularly the case when the wave-shaped element is made of a plastic. The division of the wave-shaped element takes place regularly perpendicular to the wave direction and in particular through the receiving area for solar cells.

Such an embodiment is disclosed in 4 exemplified. For the assembly of the photovoltaic module in the case of a two-piece wave-shaped element, the first part 7 of the wave-shaped element and the second part 8th of the wave-shaped element on a joining groove 9 pushed together and, for example, permanently connected by gluing or with the help of a snap closure or Heissverstemmen. This is usually done after introducing one or more solar units in the receiving area. As a result, as exemplified in 5 is shown, the photovoltaic module 2 receive. Gluing the one or more solar units in the receiving area of the wave-shaped element is not necessary in this case.

In particular, in the embodiments of the wave-shaped element described herein, in which the wave-shaped element consists of plastic, a receiving groove for the solar cells, more typically the one or more solar units may be provided. This should be based on the in 6 shown schematic cross section along the dashed line 5 to be illustrated.

Without limitation to the embodiment according to 6 can in the assembled state of the photovoltaic module, the receiving groove 6 the receiving area partially, typically completely surrounded. The receiving groove thereby creates an opening which extends in the direction of the solar unit to be accommodated or the solar unit already introduced, as shown in FIG 6 is illustrated. The receiving groove typically serves the positive reception of one or more solar units. The depth of the groove (ie, the depth of the opening for receiving the one or more solar units) is typically 0.5 to 1.0 cm. The width of the groove is typically 0.5 cm. However, the width of the receiving groove is typically chosen to be slightly smaller than the thickness of the one or more solar units, so that the connection between the solar cells and the wave-shaped element can also be non-positive.

Due to the geometry, the receiving groove described herein typically projects the height of the solar unit. The receiving groove thus additionally has the functionality that is exemplary with respect to 3 for the lead 12 was discussed, namely, that in the case of transport, the sensitive surface of the one or more solar units is better protected.

The provision of a receiving groove is especially thought of in a two-piece wave-shaped element. Provision of a receiving groove, the sticking of the solar cells can be omitted in the receiving area.

An attachment of the solar cells by means of the receiving groove has the advantage that caused by different coefficients of thermal expansion different expansions of the wave-shaped element and the solar cell can be absorbed by both components, without damaging the solar cells. This may be particularly important in the case of a plastic wavy element.

7 FIG. 4 illustrates an exemplary cross-sectional illustration of an embodiment of the photovoltaic module described herein that is mounted on an existing roof element 31 with the help of nails 30 applied and thus permanently connected. As also illustrated in the left part of the figure, another covering element can be provided during the assembly of the photovoltaic module, so that the frame 4 of the photovoltaic module between the roof element and the cover element is embedded.

The present description uses examples to disclose the invention and also to enable those skilled in the art to practice the invention, particularly to make and use devices or systems, and to carry out any methods involved. Various specific embodiments have been disclosed; One skilled in the art will recognize that the spirit and scope of the claims encompasses further correspondingly effective modifications. In particular, mutually non-exclusive features of the embodiments described above may be combined with others. The patentable scope of the invention is defined by the claims, and may include other examples that occur to those skilled in the art. Such other examples are intended to be within the scope of the claims if they include structural elements that do not differ from the literal language in the claims, or if they include equivalent structural elements with insubstantial differences from the literal languages of the claims.

LIST OF REFERENCE NUMBERS

1

Wavy element

2

solar unit

3

Electrical connection element

4

frame

5

reception area

6

receiving groove

7

First part of the wavy element

8th

Second part of the wavy element

9

Fügenut

10

fastening web

11

recess

12

gutter

15

outer edges

16

head Start

20

solar cells

21

solar unit

23

Double-sided adhesive tape

30

nail

31

roof element

32

Second roof element

Claims (11)

Wavy element ( 1 ) for receiving a plurality of solar cells ( 20 ), comprising: - a wavy frame ( 4 ), the frame having four outer edges ( 15 ) having; A reception area formed integrally with the wave-shaped frame ( 5 ) for receiving a plurality of solar cells, wherein the receiving area defines a flat bearing surface; - wherein the minimum distance of the receiving area to at least two outer edges ( 15 ) of the frame corresponds to at least half a period of the waveform and / or at least a distance of 3.5 cm; - Wherein the wave-shaped element is made of sheet metal and has a maximum thickness of 0.6mm.  A corrugated member according to claim 1, wherein the corrugated sheet has a thickness of less than or equal to 0.5mm, and more preferably a thickness of 0.2mm. Wavy element according to one of the preceding claims, further comprising a projection at least partially, preferably completely surrounding the receiving area ( 16 ). Wavy element ( 1 ) for receiving a plurality of solar cells ( 20 ), comprising: - a first part ( 7 ) and a second part ( 8th ) along a joining groove ( 9 ) and a wavy frame ( 4 ), the frame having four outer edges ( 15 ) having; A first receiving area part formed integrally with the first part, and a second receiving area part integrally formed with the second part, the first and second receiving area parts having a receiving area (FIG. 5 form), wherein the receiving area is designed to receive a plurality of solar cells and defines a flat support surface; - wherein the minimum distance of the receiving area corresponds to at least two outer edges of the frame at least half a period of the waveform and / or at least a distance of 3.5 cm; - Wherein the wave-shaped element is formed of plastic. Wavy element according to claim 4, further comprising a receiving area partially, preferably completely encircling receiving groove ( 6 ) having. Wavy element according to one of the preceding claims, wherein the receiving area further comprises at least one, preferably two recesses ( 11 ) having. Photovoltaic module ( 2 ) comprising a wave-shaped element according to one of the preceding claims and a multiplicity of solar cells ( 20 ), which in the receiving area of the wave-shaped element ( 1 ) are arranged.  A method of producing a wavy element according to any one of claims 1-3, comprising: - Providing a sheet; - Simultaneous deep drawing of the waveform and the flat recording area in one step; and - Optional formation of a recess within the receiving area.  A method of manufacturing a photovoltaic module comprising: - Producing a wave-shaped element according to claim 8; - Sticking, in particular by means of a double-sided adhesive tape, a plurality of solar cells in the receiving area.  A method of producing a wavy element according to any one of claims 4-6, comprising: - Injection molding of the first part of the wave-shaped element; and - Injection molding of the second part of the wave-shaped element.  A method of manufacturing a photovoltaic module comprising: - Producing a wave-shaped element according to the method of claim 10; - Inserting a plurality of solar cells in a receiving area of the wavy element at least partially, preferably completely circumferential groove; and - Connecting the first part of the wave-shaped element with the second part of the wave-shaped element.

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