DE102020201465A1 - Solar module, hybrid components, molding tool and method for manufacturing a hybrid component - Google Patents

Abstract

Solar modules, hybrid components, a shaping tool, methods for producing a hybrid component and the use of a shaping tool are proposed.

Description

The present invention relates to a solar module.

The present invention is based on the object of providing a solar module which can be produced simply and inexpensively and which, in particular, can be easily connected to a base body of a hybrid component.

This object is achieved by a solar module according to the independent device claim.

• - ein oder mehrere Solarzellenelemente, welche zwischen zwei Schutzlagen aus einem Schutzmaterial angeordnet sind;
• - eine Trägerlage aus einem Trägermaterial;
• - eine Decklage aus einem Deckmaterial;

wobei das eine oder die mehreren zwischen den zwei Schutzlagen angeordneten Solarzellenelemente gemeinsam mit den zwei Schutzlagen zwischen der Trägerlage und der Decklage angeordnet sind.The solar module preferably comprises the following:

• - One or more solar cell elements which are arranged between two protective layers made of a protective material;
• - A carrier layer made of a carrier material;
• - a cover layer made of a cover material;

wherein the one or more solar cell elements arranged between the two protective layers are arranged together with the two protective layers between the carrier layer and the cover layer.

Solar cell elements are in particular electrical components, in particular electrical semiconductor components, by means of which radiant energy, for example solar radiation, can be converted into electrical energy.

Individual or several, in particular all, solar cell elements of a solar module are preferably electrically connected to one another, for example soldered.

It can be favorable if the one or more solar cell elements are completely surrounded by the protective material of the two protective layers. All solar cell elements of a solar module are preferably arranged in one plane.

In particular, solar cell elements of a respective solar module do not overlap.

It can be favorable if the solar cell elements of a respective solar module are arranged in a regular pattern.

The cover material is in particular a light-permeable material, for example a transparent or translucent material.

In the context of this description and the appended claims, a translucent material is understood to mean, in particular, a material which is permeable to light in a wavelength range from approximately 300 nm to approximately 2400 nm, for example in a wavelength range from approximately 300 nm to approximately 1200 nm, in particular in a wavelength range from about 380 nm to about 780 nm.

The cover material is preferably a material that is permeable to photons.

The penetration of moisture can preferably be prevented by means of the protective layers and / or by means of the protective material. In particular, the one or more solar cell elements can be protected against moisture.

The carrier layer and / or the carrier material of the carrier layer are preferably used for thermal insulation of the solar cell elements of the solar module and / or for thermal insulation of the protective layers of the solar module.

Thermal insulation of the solar cell elements of the solar module can preferably prevent damage to the solar cell elements and / or damage to electrical contacting of the solar cell elements, for example damage to soldered connections.

Thermal insulation of the solar cell elements of the solar module can preferably also prevent thermal damage to the protective layers, for example melting of the protective layers.

In one embodiment of the solar module, it is provided that the protective material of the two protective layers comprises or consists of a polymer material, for example ethylene vinyl acetate (EVA), polyvinyl butyral (PVB), polyamide (PA), polymethyl methacrylate (PMMA) and / or polyurethane (PUR ), and / or that the protective layers are foils.

In particular, the protective layers each consist of a polymer material, for example ethylene vinyl acetate (EVA), polyvinyl butyral (PVB), polyamide (PA), polymethyl methacrylate (PMMA) or polyurethane (PUR).

The protective material is preferably a light-permeable material, for example a transparent or translucent polymer material.

The protective material is preferably a material that is permeable to photons.

It can be particularly favorable if the protective layers are ethylene vinyl acetate (EVA) films.

The protective layers are, in particular, flexible foils.

In one embodiment of the solar module, it is provided that the cover material of the cover layer and / or the carrier material of the carrier layer comprise or consist of a polymer material, for example polymethyl methacrylate (PMMA), polypropylene (PP), polycarbonate (PC) and / or ethylene tetrafluoroethylene ( ETFE), and / or that the top layer and / or the carrier layer are foils.

The cover layer and / or the carrier layer preferably each consist of a polymer material, for example of polymethyl methacrylate (PMMA), polypropylene (PP), polycarbonate (PC) or ethylene-tetrafluoroethylene (ETFE).

For example, it is conceivable that the cover layer and / or the carrier layer are each polymethyl methacrylate (PMMA) films, polypropylene (PP) films, polycarbonate (PC) films and / or ethylene-tetrafluoroethylene (ETFE) films.

The cover layer and / or the carrier layer are in particular flexible films.

It can be favorable if the carrier material of the carrier layer and the cover material of the cover layer are identical.

Alternatively, it is conceivable that the carrier material of the carrier layer and the cover material of the cover layer are different from one another.

For example, it is conceivable that the carrier material of the carrier layer and / or the cover material of the cover layer are translucent, in particular transparent or translucent, polymer materials.

It can be particularly favorable if the cover material of the cover layer is a light-permeable, in particular transparent or translucent, polymer material.

It is also conceivable that the carrier material of the carrier layer is a non-transparent polymer material.

It can be particularly advantageous if a color of the solar module can be determined by selecting a color of the carrier material of the carrier layer.

• - Polypropylen (PP)-Folie; Ethylen-Vinylacetat (EVA)-Folie; Solarzellenelement; Ethylen-Vinylacetat (EVA)-Folie; Polypropylen (PP)-Folie; oder
• - Polycarbonat (PC)-Folie; Ethylen-Vinylacetat (EVA)-Folie; Solarzellenelement; Ethylen-Vinylacetat (EVA)-Folie; Polycarbonat (PC)-Folie; oder
• - Ethylen-Tetrafluorethylen (ETFE)-Folie; Ethylen-Vinylacetat (EVA)-Folie; Solarzellenelement; Ethylen-Vinylacetat (EVA)-Folie; Ethylen- Tetrafluorethylen (ETFE)-Folie.

For example, it is conceivable that the solar module has the following layer structure in a thickness direction of the same:

• - polypropylene (PP) film; Ethylene vinyl acetate (EVA) film; Solar cell element; Ethylene vinyl acetate (EVA) film; Polypropylene (PP) film; or
• - polycarbonate (PC) film; Ethylene vinyl acetate (EVA) film; Solar cell element; Ethylene vinyl acetate (EVA) film; Polycarbonate (PC) film; or
• - ethylene tetrafluoroethylene (ETFE) film; Ethylene vinyl acetate (EVA) film; Solar cell element; Ethylene vinyl acetate (EVA) film; Ethylene-tetrafluoroethylene (ETFE) film.

In one embodiment of the solar module, it is provided that the one or more solar cell elements are welded into the protective material of the two protective layers.

The one or more solar cell elements of a respective solar module are preferably welded into the protective material of the two protective layers without gas inclusions, in particular without bubbles.

It can be advantageous, for example, if the one or more solar cell elements of a respective solar module are welded between two protective layers designed as ethylene-vinyl acetate (EVA) films.

In one embodiment of the solar module, it is provided that the two protective layers into which the one or more solar cell elements are welded are welded between the carrier material of the carrier layer and the cover material of the cover layer.

The two protective layers into which the one or more solar cell elements are welded are preferably completely surrounded by the carrier material of the carrier layer and the cover material of the cover layer.

It can be advantageous if the two protective layers into which the one or more solar cell elements are welded are welded without gas inclusions between the carrier material of the carrier layer and the cover material of the cover layer, in particular without bubbles.

In one embodiment of the solar module, it is provided that the solar module is a sandwich component.

It can be favorable if the solar module is produced by lamination, for example by lamination in a film material.

The protective layers, the cover layer and / or the carrier layer are preferably heated during lamination.

For example, it is conceivable that the protective layers, the cover layer and / or the carrier layer are fused to one another at least in some areas.

The solar module is preferably produced by vacuum lamination.

It can be favorable if the protective layers, the cover layer and / or the carrier layer are heated to a lamination temperature in the range from approximately 40.degree. C. to approximately 140.degree.

A lamination time during which a solar module is produced by lamination is preferably between approximately 10 minutes and approximately 100 minutes. It can be beneficial if the solar module is kept at the lamination temperature during the lamination time.

It can be advantageous, for example, if the solar cell elements of the solar module are first laminated into the protective layers made of the protective material. The solar cell elements laminated into the protective material are then preferably laminated between the carrier layer and the cover layer.

Alternatively, it is conceivable that the solar cell elements of the solar module are laminated into the protective layers made of the protective material and between the carrier layer and the cover layer at the same time.

Preferably, solar cell elements of the solar module are electrically connected to one another before lamination, in particular soldered to one another.

The solar module is preferably deformable, in particular three-dimensionally deformable.

In particular, a solar module with a three-dimensionally curved surface can preferably be produced.

It can be favorable if the solar module can be deformed non-destructively, in particular without destroying the one or more solar cell elements of the solar module.

The two protective layers, the carrier layer and / or the cover layer of the solar module can preferably ensure a non-destructive reshaping of the solar module.

By means of the two protective layers, the carrier layer and / or the cover layer, it is preferably possible to make the introduction of force into the solar module more uniform.

It can be favorable if a maximum degree of deformation, up to which the solar module can be deformed non-destructively, can be influenced by a choice of the protective material, a choice of the carrier material and / or a choice of the cover material.

It can also be favorable if a maximum degree of deformation, up to which the solar module can be deformed non-destructively, can be influenced by choosing a material thickness of the two protective layers, by choosing a material thickness of the carrier layer and / or by choosing a material thickness of the cover layer.

Preferably, a maximum temperature up to which the solar module can be further processed non-destructively can be influenced by choosing a material thickness of the two protective layers, by choosing a material thickness of the carrier layer and / or by choosing a material thickness of the cover layer.

In one embodiment of the solar module, it is provided that the solar module further comprises one or more connection elements, in particular one or more mechanical connection elements and / or one or more electrical connection elements.

Solar cell elements of the solar module can preferably be electrically contacted by means of one or more connection cables and / or one or more connection plugs of the solar module.

It can be favorable if the one or more electrical connection elements each comprise one or more connection cables and / or one or more connection plugs.

The one or more electrical connection elements each include, for example, a sleeve element in which connection cables and / or connection plugs are preferably received.

It is conceivable, for example, that one or more connection cables and / or one or more connection plugs for making electrical contact with the solar cell elements of the solar module are passed through a sleeve element.

One or more mechanical connection elements are preferred Fastening elements, for example fastening projections and / or fastening recesses.

It can be advantageous, for example, if the solar module comprises one or more fastening projections designed as retaining pins.

The solar module according to the invention is particularly suitable for use in a hybrid component.

The present invention therefore also relates to a hybrid component which comprises a base body made of a plastic material and a solar module according to the invention.

The base body is preferably materially connected to the solar module, in particular glued.

It can therefore be favorable if the solar module is connected, in particular glued, to the base body in a materially bonded manner by means of an adhesive material.

The carrier material of the carrier layer of the solar module acts in particular as an adhesion promoter, which facilitates a material connection of the solar module with the adhesive material.

In particular, the base body forms a reinforcing element of the hybrid component.

The base body preferably comprises a recess for receiving the solar module.

It can be favorable if the solar module is at least partially, preferably essentially completely, received in the recess of the base body.

The recess in the base body preferably has an inner contour which essentially corresponds to an outer contour of the solar module.

It can be favorable if the depression in the base body has a depth which is equal to or greater than a thickness of the solar module.

A thickness of the solar module is preferably understood to mean a thickness measured perpendicular to a main extension plane of the solar module.

The depression in the base body preferably has a depth which corresponds to the sum of a thickness of the solar module and a material thickness of the adhesive material.

It can be particularly favorable if a surface of the solar module on a visible side of the hybrid component is arranged flush with a surface of the base body on the visible side of the hybrid component.

In particular, the surface of the solar module and the surface of the base body on the visible side of the hybrid component are arranged in one plane.

The hybrid component is in particular a motor vehicle component.

For example, it is conceivable that the hybrid component is a body component for a motor vehicle.

The base body of the hybrid component is preferably an injection molded component.

The plastic material of the base body is in particular an injection-moldable plastic material.

The base body of the hybrid component is in particular a base body produced in an injection molding process or in an injection compression molding process.

The plastic material of the base body is preferably a thermoplastic plastic material, for example polycarbonate (PC), polymethyl methacrylate (PMMA) or polypropylene (PP).

In one embodiment of the hybrid component, it is provided that the hybrid component comprises a coating of a coating material on a side of the solar module facing away from the base body, which is applied to the solar module and / or to a front side of the base body.

The base body preferably comprises a mounting side and a front side.

It can be favorable if the base body comprises one or more mounting elements on the mounting side, by means of which the hybrid component can be mounted on a supporting structure, for example on a supporting structure of a motor vehicle.

The one or more assembly elements are preferably molded onto the base body in an injection molding process when it is manufactured.

The front side of the base body is in particular a side of the base body facing away from the assembly side.

The solar module of the hybrid component is arranged in particular in a recess arranged on the front side of the base body.

The depression is, in particular, a material recess extending from a surface of the base body on the front side of the same.

Alternatively, it is conceivable that the solar module of the hybrid component is arranged in a recess arranged on the assembly side of the base body. A recess arranged on the mounting side of the base body is in particular a material recess extending from a surface of the base body on the mounting side.

For example, it is conceivable that the base body is produced in a two-component injection molding process, the base body comprising a translucent base body part made of a translucent plastic material and a non-transparent base body part made of a non-transparent plastic material, the translucent base body part being arranged on a front side of the base body.

The translucent main body part is in particular a transparent or translucent main body part.

The translucent plastic material of the translucent base body part is in particular a transparent or translucent plastic material.

The non-transparent main body part forms, in particular, a frame element for the translucent main body part.

The recess in the base body for receiving the solar module is preferably a material cutout in the non-transparent base body part.

The translucent base body part preferably completely covers the solar module on a visible side of the hybrid component.

It can be favorable, for example, if the translucent plastic material of the translucent base body part comprises or consists of polycarbonate (PC), polypropylene (PP) or polymethyl methacrylate (PMMA).

It can also be favorable if the non-transparent plastic material of the non-transparent base body part comprises or consists of a blend of polycarbonate (PC) and acrylonitrile-butadiene-styrene (ABS).

As an alternative or in addition to this, it is conceivable that the opaque plastic material of the opaque base body part is made of polypropylene (PP), polymethyl methacrylate (PMMA), a blend of polypropylene (PP) and acrylonitrile-butadiene-styrene (ABS) or a blend of polymethyl methacrylate (PMMA) and Includes acrylonitrile butadiene styrene (ABS) or consists of this.

The coating material is preferably a light-permeable, in particular transparent or translucent, plastic material, in particular a lacquer material.

The coating material preferably comprises or consists of a polyurethane (PU) lacquer, a polyurea (PUA) lacquer, a silicone resin material and / or an epoxy resin.

The coating preferably completely covers the solar module of the hybrid component.

It can also be favorable if the coating covers the base body of the hybrid component at least partially, preferably essentially completely, on the visible side thereof.

The hybrid component preferably has a class A surface on one visible side thereof.

The coating is preferably applied to the solar module and / or to the front side of the base body in the same shaping tool in which the base body of the hybrid component is produced.

It can also be favorable if the base body of the hybrid component is injection-molded onto the solar module.

The base body is connected to the solar module by molding the base body onto the solar module, preferably in a materially bonded manner.

The base body is molded onto the solar module, in particular by back injection molding.

The carrier material of the carrier layer of the solar module acts in particular as an adhesion promoter, which facilitates an integral connection of the solar module with the plastic material of the base body.

In particular, the base body forms a reinforcing element of the hybrid component.

It is conceivable, for example, that the plastic material of the base body is a non-transparent plastic material.

It can be favorable if the plastic material of the base body is polycarbonate (PC), polymethyl methacrylate (PMMA) or polypropylene (PP) or a blend of polycarbonate (PC) and acrylonitrile Includes or consists of butadiene styrene (ABS).

In one embodiment of the hybrid component, it is provided that the hybrid component comprises a coating of a coating material on a side of the solar module facing away from the base body, which is applied to the solar module and / or to a front side of the base body.

The coating material preferably comprises or consists of a polyurethane (PU) lacquer, a polyurea (PUA) lacquer, a silicone resin material and / or an epoxy resin.

The coating preferably completely covers the solar module of the hybrid component.

It can also be favorable if the coating covers the base body of the hybrid component at least partially, preferably essentially completely, on its front side.

The hybrid component preferably has a class A surface on one visible side thereof.

The coating is preferably applied to the solar module and / or to the front side of the base body in the same shaping tool in which the base body of the hybrid component is injection molded onto the solar module.

The present invention is also based on the further object of providing a method for producing a hybrid component, by means of which a functional element can be connected simply and inexpensively to a base body of the hybrid component.

This object is achieved by a method for producing a hybrid component with the features of the independent method claim.

The method is used in particular to produce a hybrid component according to the invention.

The hybrid component preferably comprises a base body and a functional element, in particular a solar module according to the invention.

• - Herstellen eines Grundkörpers aus einem Kunststoffmaterial in einem Spritzprozess in einem Formgebungswerkzeug;
• - Bereitstellen eines Funktionselements, insbesondere eines erfindungsgemäßen Solarmoduls;
• - stoffschlüssiges Verbinden des Funktionselements mit dem Grundkörper, insbesondere mittels eines Klebermaterials.

The method according to the invention for producing a hybrid component preferably comprises the following:

• - Production of a base body from a plastic material in an injection molding process in a molding tool;
• - Provision of a functional element, in particular a solar module according to the invention;
• - Material connection of the functional element to the base body, in particular by means of an adhesive material.

It can be favorable if the base body is produced in a shaping tool, in particular in an injection molding tool.

The base body is preferably produced by introducing an injectable plastic material, in particular by introducing a melt-processable plastic material, into an injection cavity of the molding tool.

The base body is produced in particular by introducing an injectable plastic material into an injection cavity of the molding tool which is delimited by a first mold half and a second mold half of the molding tool.

The injection molding process is preferably an injection molding process or an injection compression molding process.

It can be advantageous if, in an injection compression molding process, an injection cavity of the shaping tool is reduced or enlarged after the injection of the injectable plastic material has been introduced.

The forming tool is preferably a plunge edge tool.

An injection compression molding process can preferably be carried out with a plunge edge tool.

In the context of this description and the appended claims, a plunge edge tool is understood to mean, in particular, a shaping tool which comprises a plurality of sealing surfaces which are arranged parallel to the main demolding direction and / or parallel to an opening direction of the shaping tool.

Preferably, the mold halves of the molding tool are cylindrical in the area of the sealing surface.

It can be favorable here if the mold halves of the shaping tool comprise sealing surfaces which correspond to one another, which preferably overlap each other in an at least partially closed shaping tool in such a way that plastic material does not come between the sealing surfaces of the mold halves can escape from the forming tool.

A forming tool designed as a plunge edge tool is therefore preferably suitable for processes in which the mold halves are moved during and / or after the injection of a plastic material into a cavity of the forming tool, in particular for enlarging and / or reducing the cavity.

The base body is preferably made from a thermoplastic plastic material, for example from an amorphous or partially crystalline plastic material.

It can be favorable, for example, if the plastic material of the base body comprises or consists of polycarbonate (PC), polymethyl methacrylate (PMMA) or polypropylene (PP) or a blend of polycarbonate (PC) and acrylonitrile-butadiene-styrene (ABS).

The carrier material of the carrier layer of the solar module and / or the plastic material of the base body are preferably matched to one another, in particular in such a way that molecules of the carrier material and molecules of the plastic material of the base body preferably interact with one another.

The carrier material and the plastic material of the base body preferably have surface properties that are compatible with one another.

By choosing a color of the plastic material of the base body, a color of the hybrid component can preferably be determined.

The two protective layers, the cover layer and / or the carrier layer of the solar module are preferably made from a light-permeable, in particular transparent or translucent, polymer material.

As an alternative or in addition to the choice of a color for the plastic material of the base body, it is conceivable that the base body is produced by back injection molding. In particular, an optical appearance of the base body can be influenced by back-molding the film, in particular by selecting a film, which is then back-molded with the plastic material of the base body.

It can be favorable if, during the production of the base body, a recess for receiving the functional element, in particular for receiving the solar module according to the invention, is produced.

In one embodiment of the method, it is provided that the functional element and the base body are pressed against one another for a material connection, in particular by moving two mold halves of the shaping tool together or by pressing the functional element against the base body by means of a handling device.

When the functional element is pressed against the base body by means of a handling device, the base body is preferably supported on a tool wall of a mold half of the molding tool.

The functional element and the base body are, in particular, pressed together for a materially bonded connection of the same.

If the functional element and the base body are pressed against one another by moving two mold halves of the shaping tool together, it can be provided that the functional element is fed to the shaping tool by means of a handling device.

The functional element and the base body are pressed against one another in particular by moving a first and a second mold half of the shaping tool together.

It can be favorable if the functional element is at least partially reshaped, if the functional element and the base body are pressed against one another for a materially bonded connection of the same.

In one embodiment of the method, it is provided that an adhesive material is applied to the base body and / or to the functional element before the functional element is firmly connected to the base body.

It can be favorable if the adhesive material is a temperature-curing and / or UV-curing adhesive material.

A temperature-curing adhesive material is preferably cured by means of the shaping tool, which is, for example, a variothermal shaping tool. A temperature-curing adhesive material can preferably be cured by heating a variothermal shaping tool.

A UV-curing adhesive material is preferably cured by means of UV radiation. It can be advantageous if a UV radiation device is arranged, for example, on a handling device by means of which the Functional element is fed to the shaping tool.

Adhesive material applied to the base body is preferably introduced into a recess in the base body which is designed to receive the functional element.

It can be favorable if the adhesive material is applied to the functional element and / or to the base body as a film material.

As an alternative to this, it is conceivable that the adhesive material is applied in liquid or paste form to the functional element and / or to the base body.

As an alternative to applying the adhesive material to the base body, it is conceivable that the plastic material, in particular the thermoplastic plastic material, of the base body is partially melted on a surface of the base body before the functional element is firmly bonded to the base body.

If the base body is produced in a two-component injection molding process, the base body comprising a transparent base body part made of a transparent plastic material, which is arranged on a front side of the base body, and a non-transparent base body part made of a non-transparent plastic material, it can be provided that the adhesive material for example, includes or consists of silicone.

For example, it is conceivable that the plastic material, in particular the thermoplastic plastic material, of the base body is melted in a recess in the base body which is designed to accommodate the functional element.

In one embodiment of the method, it is provided that the base body remains form-bound during the cohesive connection of the same to the functional element in the shaping tool by means of which the base body is produced.

After it has been manufactured, the base body is not removed from the mold, in particular from a mold half of the molding tool, in an injection molding process for a materially bonded connection with the functional element.

The base body is preferably not removed from the second mold half after it has been produced in an injection molding process for a materially bonded connection with the functional element.

Preferably, after it has been produced in an injection molding process for a materially bonded connection with the functional element, the base body is only removed from the mold from a single mold half.

After it has been manufactured, the base body is preferably only removed from the first mold half in an injection molding process for a materially bonded connection.

In one embodiment of the method, it is provided that the functional element is heated before the material connection to the base body of the hybrid component.

For example, it is conceivable that the functional element is heated by means of a heating device, for example by means of an infrared heating device, before it is firmly connected to the base body.

It can be advantageous, for example, if the infrared heating device is arranged on a handling device by means of which the functional element is fed to the shaping tool.

In one embodiment of the method, it is provided that after the material connection of the functional element to the base body, a coating of a coating material is applied to the functional element and / or to the base body, the coating completely covering the functional element of the hybrid component and / or the coating covers the base body of the hybrid component at least partially, preferably essentially completely, on a front side thereof.

If the coating essentially completely covers the functional element and the base body of the hybrid component on a front side of the hybrid component, a uniform and, in particular, attractive visual appearance of the hybrid component can preferably be achieved.

To apply the coating, a translucent, in particular transparent or translucent, plastic material, in particular a lacquer material, is preferably introduced into a coating cavity which is delimited by a tool wall of the shaping tool on the one hand and by a surface of the base body and a surface of the functional element on the other.

The coating cavity is preferably in particular made up of a second mold half and a third mold half of the shaping tool and limited by a surface of the base body and a surface of the functional element.

It can be favorable if a first mold half of the shaping tool is replaced by a third mold half of the shaping tool before the coating is applied, for example by turning a turning plate.

The coating is applied to the functional element and / or to the base body in particular by introducing the coating material into the coating cavity.

It can be advantageous if the coating cavity is essentially completely filled when the coating material is introduced.

In particular, it is conceivable that the coating cavity is reduced or enlarged after the coating material has been introduced into it.

The coating material preferably comprises a polyurethane (PU) lacquer, a polyurea (PUA) lacquer, a silicone resin material and / or an epoxy resin or is formed by these.

The functional element, in particular the solar module according to the invention, can preferably be protected from external influences, for example from the weather, by applying the coating.

The functional element, in particular the solar module according to the invention, can in particular be protected from UV radiation by applying the coating.

It can be favorable if the coating material is a scratch-resistant coating material.

In one embodiment of the method, it is provided that the coating is applied to the functional element and / or to the base body in the same shaping tool by means of which the base body is produced.

The base body preferably remains form-bound during the application of the coating in the shaping tool, in particular in a second mold half of the shaping tool.

In order to apply the coating, the base body is in particular not demolded from a mold half, in particular not from a second mold half, of the molding tool.

In one embodiment of the method, it is provided that one or more passage openings are produced in the base body when the base body is produced.

Passage openings in the base body serve in particular to receive and / or pass through one or more connection elements of the functional element.

It can be favorable if the one or more passage openings are produced during production of the base body in an injection molding process by means of one or more displacement elements, in particular by means of one or more slide elements.

For example, it is conceivable that one or more slide elements of the first mold half are placed against a tool wall of the second mold half in order to produce the passage openings during production of the base body and / or that one or more slide elements of the second mold half are applied to one or more slide elements of the second mold half in order to produce the passage openings during production of the base body Tool wall of the first mold half can be created.

It can be advantageous if the slide elements of the first and / or the second mold half can be displaced between an injection position and an insertion position.

The slide elements of the first mold half and / or the second mold half are preferably shifted from an injection position to an insertion position after the production of the base body.

It can be favorable if the slide elements of the first mold half rest against a tool wall of the second mold half in the injection position and / or if the slide elements of the second mold half rest against a tool wall of the first mold half in the injection position.

Preferably, the slide elements of the first and / or the second mold half are partially or essentially completely moved out of the one or more passage openings of the base body in an insertion position, so that when the functional element is connected to the base body with one another, one or more connecting elements of the functional element in one or the plurality of passage openings can be received or passed through them.

The above-mentioned object is also achieved by a method for producing a hybrid component having the features of the independent method claim.

The method is used in particular to produce a hybrid component according to the invention.

The hybrid component preferably comprises a base body and a functional element, in particular a solar module according to the invention.

• - Bereitstellen eines Formgebungswerkzeugs
• - Bereitstellen eines erfindungsgemäßen Solarmoduls;
• - Einbringen des Solarmoduls in das Formgebungswerkzeug;
• - Anspritzen eines Grundkörpers aus einem Kunststoffmaterial an das Solarmodul in einem Spritzprozess.

The method preferably comprises:

• - Providing a shaping tool
• - Provision of a solar module according to the invention;
• - Introducing the solar module into the forming tool;
• - Injection molding of a base body made of a plastic material onto the solar module in an injection molding process.

The base body is connected to the solar module by molding the base body onto the solar module, preferably in a materially bonded manner.

The injection molding process in which the base body is injected onto the solar module is, for example, an injection molding process or an injection compression molding process.

The shaping tool, in which the base body is molded onto the solar module, is preferably a dipping edge tool.

It can be favorable if the solar module is placed against a tool wall of the shaping tool before the base body is molded on.

The solar module is preferably placed against a tool wall of the shaping tool before the base body is molded on in such a way that a surface of the cover layer of the solar module is essentially completely in contact with the tool wall.

As an alternative to this, it is conceivable that the solar module is placed against a tool wall of the shaping tool before the base body is molded on in such a way that a surface of the carrier layer of the solar module is essentially completely in contact with the tool wall.

It can be favorable if the solar module is at least partially reshaped when it is placed against a tool wall of the shaping tool.

The base body is preferably injection-molded onto the solar module by introducing an injectable plastic material, in particular by introducing a melt-processable plastic material, into an injection cavity of the shaping tool.

It can be favorable if the injection cavity is delimited by a first mold half and a second mold half of the shaping tool as well as by the solar module.

In one embodiment of the method, it is provided that the base body is injected onto the solar module in a two-component injection molding process, the base body comprising a translucent body part made of a translucent plastic material and a non-transparent body part made of a non-transparent plastic material.

The translucent main body part is in particular a transparent or translucent main body part.

The translucent plastic material of the translucent plastic material is in particular a transparent or translucent plastic material.

The translucent base body part is preferably arranged on a front side of the base body and / or is preferably molded onto the solar module on a visible side thereof.

The non-transparent base body part is preferably arranged on a mounting side of the base body and / or is preferably molded onto the solar module on a side facing away from the visible side of the solar module.

For example, it is conceivable that the base body is produced in a two-component injection molding process, the base body comprising a transparent base body part made of a transparent plastic material and a non-transparent base body part made of a non-transparent plastic material on a front side thereof.

The non-transparent main body part forms, in particular, a frame element for the translucent main body part.

The non-transparent main body part comprises, for example, a rib structure.

The translucent base body part preferably completely covers the solar module on a visible side of the hybrid component.

It can be beneficial, for example, if the translucent plastic material of the translucent base body part comprises polycarbonate (PC), polypropylene (PP) or polymethyl methacrylate (PMMA) or consists of this.

It can also be beneficial if the non-transparent plastic material of the non-transparent base body part comprises or consists of polypropylene (PP), polymethyl methacrylate (PMMA) or a blend of polycarbonate (PC) and acrylonitrile-butadiene-styrene (ABS).

By choosing a color for the non-transparent plastic material of the non-transparent main body part, a color of the hybrid component can preferably be determined.

In one embodiment of the method, it is provided that after the base body has been molded onto the solar module, a coating of a coating material is applied to the solar module and / or to the base body, the coating completely covering the solar module of the hybrid component and / or the coating being the The base body of the hybrid component at least partially, preferably essentially completely, covers on a front side thereof.

If the coating essentially completely covers the solar module and the base body of the hybrid component on a visible side of the hybrid component, a uniform and, in particular, attractive visual appearance of the hybrid component can preferably be achieved.

To apply the coating, a translucent, in particular transparent or translucent, plastic material, in particular a lacquer material, is preferably introduced into a coating cavity, which is delimited by a tool wall of the shaping tool on the one hand and by a surface of the base body and a surface of the solar module on the other.

The coating cavity is preferably delimited in particular in front of a first mold half and a second mold half of the shaping tool and by a surface of the base body and a surface of the solar module.

For example, it is conceivable that a first mold half of the shaping tool is replaced by a third mold half of the shaping tool before the coating is applied, for example by turning a turning plate.

The coating is applied to the functional element and / or to the base body in particular by introducing the coating material into the coating cavity.

It can be advantageous if the coating cavity is essentially completely filled when the coating material is introduced.

In particular, it is conceivable that the coating cavity is reduced or enlarged after the coating material has been introduced into it.

The coating material preferably comprises a polyurethane (PU) lacquer, a polyurea (PUA) lacquer, a silicone resin material and / or an epoxy resin or is formed by these.

The solar module can preferably be protected from external influences, for example from the weather, by applying the coating.

The solar module can in particular be protected from UV radiation by applying the coating.

It can be favorable if the coating material is a scratch-resistant and / or UV-resistant coating material.

The coating material is in particular a so-called “hard coat” material.

In one embodiment of the method, it is provided that the coating is applied to the solar module and / or to the base body in the same shaping tool in which the base body is injected onto the solar module.

For example, it is conceivable that, in order to form a coating cavity, one mold half of the shaping tool is replaced by a further mold half of the shaping tool.

It can be particularly favorable if the base body, after it has been injection molded onto the solar module, remains form-bound in a mold half of the molding tool in order to apply the coating.

In one embodiment of the method, it is provided that the base body is connected to the solar module in a form-fitting manner by molding it onto the solar module.

It can be favorable, for example, if the base body encompasses the solar module.

The base body preferably engages around the solar module at an edge region of the solar module, at least in sections.

For example, it is conceivable that the base body encompasses the solar module in a closed ring shape at an edge region of the solar module.

In one embodiment of the method it is provided that the carrier material of the carrier layer and / or the cover material of the cover layer of the solar module comprise or consist of polypropylene (PP), wherein the plastic material of the base body comprises or consists of polypropylene (PP); or
that the carrier material of the carrier layer and / or the cover material of the cover layer of the solar module comprise or consist of polycarbonate (PC), the plastic material of the base body comprising or consisting of a blend of polycarbonate (PC) and acrylonitrile-butadiene-styrene (ABS); or that the carrier material of the carrier layer and / or the cover material of the cover layer of the solar module comprise or consist of ethylene tetrafluoroethylene (ETFE), the plastic material of the base body comprising or of a blend of polycarbonate (PC) and acrylonitrile butadiene styrene (ABS) consists; or
that the carrier material of the carrier layer and / or the cover material of the cover layer of the solar module comprise or consist of ethylene tetrafluoroethylene (ETFE), the base body being produced in a two-component injection molding process, a translucent base body part being produced from a translucent plastic material which Comprises or consists of polycarbonate (PC), and wherein a non-transparent base body part is produced from a non-transparent plastic material which comprises or consists of a blend of polycarbonate (PC) and acrylonitrile-butadiene-styrene (ABS); or
that the carrier material of the carrier layer and / or the cover material of the cover layer of the solar module comprise or consist of polycarbonate (PC), the base body being manufactured in a two-component injection molding process, with a translucent base body part being made from a translucent plastic material, which is polycarbonate ( PC) comprises or consists of it, and wherein a non-transparent base body part is produced from a non-transparent plastic material which comprises or consists of a blend of polycarbonate (PC) and acrylonitrile-butadiene-styrene (ABS).

The carrier material of the carrier layer of the solar module and / or the plastic material of the base body are preferably matched to one another, in particular in such a way that molecules of the carrier material and molecules of the plastic material of the base body preferably interact with one another.

It can be favorable if the carrier material of the carrier layer of the solar module and the plastic material of the base body have surface properties that are compatible with one another.

In particular, a shrinkage behavior of the plastic material of the base body can be adapted to the carrier material of the carrier layer of the solar module.

The present invention is also based on the further object of providing a method for producing a hybrid component, by means of which a functional element can be connected simply and inexpensively to a base body of the hybrid component.

This object is achieved by a method with the features of the independent method claim.

• - Bereitstellen eines Formgebungswerkzeugs;
• - Bereitstellen eines Funktionselements, welches ein oder mehrere Anschlusselemente umfasst;
• - Anlegen des Funktionselements an eine Werkzeugwandung einer ersten Formhälfte des Formgebungswerkzeugs und an ein oder mehrere Schieberelemente einer zweiten Formhälfte des Formgebungswerkzeugs;
• - Anspritzen eines Grundkörpers aus einem Kunststoffmaterial an das Funktionselement in einem Spritzprozess.

The method preferably comprises:

• - Providing a shaping tool;
• - Provision of a functional element which comprises one or more connection elements;
• Application of the functional element to a tool wall of a first mold half of the shaping tool and to one or more slide elements of a second mold half of the shaping tool;
• - Injection molding of a base body made of a plastic material onto the functional element in an injection molding process.

The functional element is in particular an insert element.

The functional element is, for example, a solar module according to the invention.

Alternatively, it is conceivable, for example, that the functional element comprises a heating element, for example a heating film, or is formed by this.

The one or more connection elements protrude in particular away from the functional element.

The one or more connection elements are preferably electrical connection elements and / or mechanical connection elements.

A connection element designed as an electrical connection element preferably comprises one or more cables and / or one or several connector elements or is formed by this. Solar cell elements of the solar module can preferably be electrically contacted by means of one or more connection cables and / or one or more connection plugs of the solar module.

It can also be favorable if a connection element designed as an electrical connection element also comprises a sleeve element, with one or more connection cables and / or one or more connection plugs for making electrical contact with the solar cell elements of the solar module being passed through the sleeve element.

A connection element designed as a mechanical connection element comprises, for example, a fastening projection. It can be advantageous, for example, if the solar module comprises one or more fastening projections designed as retaining pins.

The one or more slide elements are preferably placed against the functional element on a side of the functional element facing away from the tool wall of the first mold half of the shaping tool.

It can be favorable if an end face of the one or more slide elements is placed against the functional element, in particular an end face at a free end of the one or more slide elements.

The functional element is introduced into the shaping tool in particular before the base body is molded on.

Before the base body is molded onto the functional element, the molding tool is closed, in particular by moving the first mold half and the second mold half of the molding tool together.

It can be favorable if the base body is injection-molded onto the functional element on the side of the functional element on which the one or more connecting elements of the functional element are arranged.

All connection elements of the functional element are preferably arranged on the same side of the functional element.

The injection molding process in which the base body is molded onto the functional element is preferably an injection molding process and / or an injection compression molding process.

In one embodiment of the method, it is provided that the functional element is placed against the tool wall of the first mold half of the shaping tool by moving the one or more slide elements.

The one or more slide elements are preferably displaced in a displacement direction which is preferably parallel to a main demolding direction and / or parallel to an opening direction of the molding tool.

In one embodiment of the method, it is provided that the one or more slide elements are displaced by means of a displacement device.

The one or more slide elements are preferably displaced independently of one another by means of the displacement device.

As an alternative or in addition to this, it is conceivable that the one or more slide elements are displaced synchronously by means of the displacement device.

In one embodiment of the method, it is provided that the one or more slide elements are resiliently applied to the functional element, in particular by means of a spring device.

A thickness tolerance of the functional element is preferably compensated for by means of the spring device. In particular, a defined pressure is exerted on the functional element by means of the slide elements arranged on the spring device, so that the one or more slide elements are applied to the functional element without destroying it.

It can be favorable if the one or more slide elements are applied to the functional element under prestress by means of the spring device.

The spring device comprises, for example, a mechanical spring, in particular a helical spring or a plate spring, or is formed by this.

Alternatively, it is conceivable that the spring device comprises a hydraulic spring device or is formed by this.

In one embodiment of the method it is provided that a spring force of the spring device is set and / or regulated.

In one embodiment of the method, it is provided that one or more slide elements each comprise or form a cover element, wherein the one or more connection elements of the functional element are covered by means of a cover element.

Preferably, in each case one connection element of the functional element is covered by means of a cover element of a slide element.

As an alternative or in addition to this, it is conceivable that several connection elements of the functional element are covered by means of a cover element of a slide element in each case.

In one embodiment of the method, it is provided that the cover element for covering the one or more connection elements is placed against the functional element in an in particular circumferential sealing area, in particular in a sealing manner.

In particular, a sealing surface of the cover element, which is arranged on an end face of a slide element, is placed against the functional element in a sealing manner.

In order to cover the one or more connection elements, the cover element is preferably pressed against the functional element in an in particular circumferential sealing area.

In one embodiment of the method, it is provided that the functional element is fed to the shaping tool by means of a handling device.

The functional element is introduced into the shaping tool in particular by means of the handling device.

The functional element is preferably moved in between two mold halves of the shaping tool by means of the handling device.

The functional element is preferably positioned on several slide elements of the second mold half by means of the handling device, in particular placed on several slide elements of the second mold half.

The handling device is then preferably moved out of the shaping tool.

It can be favorable here if the functional element is positioned by means of the handling device in such a way that connection elements of the functional element are at least partially received in cover elements of the slide elements of the second mold half.

The handling device includes, for example, a gripper and / or an industrial robot.

The functional element is then fixed in the shaping tool, preferably by means of one or more slide elements of the second mold half.

For example, the one or more slide elements are displaced by means of a displacement device of the shaping tool along a displacement direction towards the first mold half.

Alternatively, it is conceivable that the first mold half is displaced towards the one or more slide elements and / or towards the functional element positioned on the slide elements.

In one embodiment of the method, it is provided that the functional element is aligned and / or positioned relative to the shaping tool by means of the one or more slide elements.

It can be favorable if the functional element is centered by means of the one or more slide elements.

The present invention also relates to a forming tool.

The present invention is based on the further object of providing a shaping tool by means of which a hybrid component can be produced simply and inexpensively.

This object is achieved by a shaping tool with the features of the independent device claim.

The shaping tool is used in particular to carry out the method according to the invention for producing a hybrid component.

• - eine erste Formhälfte;
• - eine zweite Formhälfte;

wobei die zweite Formhälfte ein oder mehrere Schieberelemente umfasst, mittels welcher ein Funktionselement an eine Werkzeugwandung der ersten Formhälfte anlegbar ist.The forming tool preferably comprises the following:

• - a first mold half;
• - a second mold half;

wherein the second mold half comprises one or more slide elements, by means of which a functional element can be placed against a tool wall of the first mold half.

It can be favorable if the one or more slide elements are arranged on the second mold half so as to be displaceable relative to the second mold half, preferably parallel to a main demolding direction and / or parallel to an opening direction of the molding tool.

A functional element can preferably be placed against the tool wall of the first mold half by moving one or more slide elements.

In a closed position of the molding tool, the first mold half and the second mold half preferably delimit an injection cavity, in particular together with a functional element introduced into the molding tool.

The first mold half of the shaping tool is, for example, a stamp element.

The second mold half of the forming tool is, for example, a die element.

The first and second mold halves are preferably movable relative to one another, in particular between an open position and a closed position of the molding tool.

The one or more slide elements are preferably so-called “leading slide elements”.

The one or more slide elements are preferably designed to be essentially cylindrical.

It can be favorable if the one or more slide elements are pin elements.

It can be favorable if the shaping tool is a plunge edge tool.

In one embodiment of the shaping tool, it is provided that the shaping tool further comprises a displacement device, by means of which one or more slide elements can be displaced relative to the second mold half.

It can be favorable if individual slide elements can be displaced independently of one another by means of the displacement device.

As an alternative or in addition to this, it is possible that all slide elements can be displaced synchronously by means of the displacement device.

For example, it is conceivable that all slide elements are coupled in terms of movement to a slide plate of the shaping tool. It can be advantageous if the slide plate is arranged on the second mold half of the shaping tool.

Alternatively, it is conceivable that a respective slide element can be displaced by means of a piston device of the displacement device.

A respective piston device of the displacement device is, for example, a hydraulic or pneumatic piston device.

A piston device preferably comprises a piston which can be displaced by applying pressure to a pressure chamber.

In one embodiment of the shaping tool, it is provided that the one or more slide elements that can be placed against the functional element are each resiliently arranged on the second mold half of the shaping tool by means of a spring device.

A compensation of a thickness tolerance of the functional element can preferably be realized by means of the slide elements arranged on the spring device. In particular, a defined pressure on the functional element can be achieved by means of the slide elements arranged on the spring device, so that the one or more slide elements can be applied to the functional element without destroying it.

The one or more slide elements are preferably resiliently arranged on the second mold half of the shaping tool parallel to a displacement direction of the slide elements by means of the spring device.

The one or more slide elements are preferably designed to be essentially rigid, in particular parallel to a direction of displacement thereof.

A spring effect is preferably provided essentially completely by the spring device.

For example, it is conceivable that the spring device is a mechanical spring device, a pneumatic spring device or a hydraulic spring device. A pneumatic spring device or a hydraulic spring device preferably each comprises a piston device or is formed by this.

It can be favorable if the displacement device comprises or forms the spring device, in particular if the displacement device comprises a piston device. The spring device is formed, for example, by the piston device of the displacement device.

If the spring device is a mechanical spring device, it preferably comprises one or more mechanical spring elements, for example helical spring elements and / or plate spring elements. Mechanical spring elements consist, for example, of spring steel.

In one embodiment of the shaping tool, provision is made for a spring force of the spring device to be adjustable and / or controllable.

By setting a spring force of the spring device, a pressing force can preferably be set and / or regulated, by means of which the one or more slide elements are applied to the functional element.

For example, it is conceivable that a spring force of a mechanical spring device can be adjusted.

It can also be favorable if a spring force of a pneumatic or hydraulic spring device can be set and / or regulated, for example by setting and / or regulating a pressure in a pressure chamber of a piston device.

In one embodiment of the shaping tool, it is provided that one or more slide elements comprise a cover element for covering the one or more connection elements of the functional element.

It can be favorable if each slide element comprises or forms a cover element.

Preferably, one connection element of the functional element can be covered by means of a cover element of a slide element.

As an alternative or in addition to this, it is conceivable that several connection elements of the functional element can be covered by means of a single cover element.

A cover element preferably comprises a receiving space in which one or more connection elements of the functional element can be received, in particular completely.

A receiving space of a cover element is formed, for example, by a recess in a slide element, for example by a cylindrical recess.

A recess in a slide element is, for example, a blind hole or a passage opening.

If the recess in a slide element is a passage opening, the slide element is preferably a slide sleeve.

One or more connection elements of the functional element can preferably be thermally and / or mechanically protected from damage by means of one or more cover elements.

In one embodiment of the shaping tool, it is provided that the cover element comprises a sealing surface which is arranged on an end face of a respective slide element.

The cover element preferably comprises a sealing surface that is closed, in particular, in an annular shape.

The sealing surface of the cover element can preferably be placed against the functional element in an annularly closed sealing area.

One or more connection elements of the functional element can preferably be covered in a sealing manner by means of a cover element, in particular in such a way that the connection elements of the functional element are not brought into contact with the plastic material when a plastic material is introduced into the cavity of the molding tool.

The present invention further relates to the use of a shaping tool according to the invention for producing a hybrid component which comprises a base body and a functional element, in particular for carrying out the method according to the invention for producing a hybrid component.

Further features and / or advantages of the invention are the subject matter of the following description and the graphic representation of exemplary embodiments.

• 1 eine Explosionsdarstellung eines schematischen Schnitts einer Ausführungsform eines Solarmoduls;
• 2 einen schematischen Schnitt der Ausführungsform des Solarmoduls aus 1;
• 3 eine schematische Draufsicht auf die Ausführungsform des Solarmoduls aus 2;
• 4 einen schematischen Schnitt durch die Ausführungsform des Solarmoduls aus 3 längs der Linie IV-IV in 3;
• 5 einen vergrößerten Ausschnitt eines schematischen Schnitts einer weiteren Ausführungsform eines Solarmoduls;
• 6 einen schematischen Schnitt einer weiteren Ausführungsform eines Solarmoduls;
• 7 einen ersten Verfahrensschritt einer Ausführungsform eines Verfahrens zur Herstellung eines Hybridbauteils;
• 8 einen auf den Verfahrensschritt aus 7 folgenden weiteren Verfahrensschritt der Ausführungsform des Verfahrens zur Herstellung eines Hybridbauteils;
• 9 einen auf den Verfahrensschritt aus 8 folgenden weiteren Verfahrensschritt der Ausführungsform des Verfahrens zur Herstellung eines Hybridbauteils;
• 10 eine Ausführungsform eines mit der Ausführungsform des Verfahrens zur Herstellung eines Hybridbauteils hergestellten Hybridbauteils;
• 11 eine weitere Ausführungsform eines Hybridbauteils;
• 12 einen schematischen Schnitt durch eine Ausführungsform eines Formgebungswerkzeugs zur Herstellung eines Hybridbauteils;
• 13 einen ersten Verfahrensschritt einer Ausführungsform eines Verfahrens zur Herstellung eines Hybridbauteils, wobei ein Grundkörper des Hybridbauteils in einem Spritzprozess hergestellt wird;
• 14 einen auf den Verfahrensschritt aus 13 folgenden weiteren Verfahrensschritt der Ausführungsform des Verfahrens zur Herstellung eines Hybridbauteils;
• 15 einen schematischen Schnitt eines in dem Verfahrensschritt aus 13 hergestellten Grundkörpers eines Hybridbauteils;
• 16 einen schematischen Schnitt eines Funktionselements eines Hybridbauteils;
• 17 einen auf den Verfahrensschritt aus 14 folgenden weiteren Verfahrensschritt der Ausführungsform des Verfahrens zur Herstellung eines Hybridbauteils, wobei das Funktionselement aus 16 in eine Vertiefung des Grundkörpers aus 15 eingebracht wird;
• 18 einen schematischen Schnitt des Grundkörpers aus 15 sowie des Funktionselements aus 16, wobei das Funktionselement teilweise in eine Vertiefung des Grundkörpers eingebracht ist;
• 19 einen auf den Verfahrensschritt aus 17 folgenden weiteren Verfahrensschritt der Ausführungsform des Verfahrens zur Herstellung eines Hybridbauteils, wobei das Funktionselement mit dem Grundkörper stoffschlüssig verbunden, insbesondere verklebt, wird;
• 20 einen schematischen Schnitt des mit dem Grundkörper aus 15 stoffschlüssig verbundenen, insbesondere verklebten Funktionselements aus 16;
• 21 einen auf den Verfahrensschritt aus 19 folgenden weiteren Verfahrensschritt der Ausführungsform des Verfahrens zur Herstellung eines Hybridbauteils;
• 22 einen auf den Verfahrensschritt aus 21 folgenden weiteren Verfahrensschritt der Ausführungsform des Verfahrens zur Herstellung eines Hybridbauteils;
• 23 einen auf den Verfahrensschritt aus 23 folgenden weiteren Verfahrensschritt der Ausführungsform des Verfahrens zur Herstellung eines Hybridbauteils, wobei eine zweite und eine dritte Formhälfte des Formgebungswerkzeugs sowie der Grundkörper und das Funktionselement eine Beschichtungskavität begrenzen;
• 24 einen auf den Verfahrensschritt aus 23 folgenden weiteren Verfahrensschritt der Ausführungsform des Verfahrens zur Herstellung eines Hybridbauteils, wobei eine Beschichtung aus einem Beschichtungsmaterial auf den Grundkörper und auf das Funktionselement aufgebracht wird;
• 25 einen auf den Verfahrensschritt aus 24 folgenden weiteren Verfahrensschritt der Ausführungsform des Verfahrens zur Herstellung eines Hybridbauteils;
• 26 einen schematischen Schnitt eines mittels der in den 13 bis 25 dargestellten Ausführungsform des Verfahrens zur Herstellung eines Hybridbauteils hergestellten Hybridbauteils;
• 27 einen ersten Verfahrensschritt einer weiteren Ausführungsform eines Verfahrens zur Herstellung eines Hybridbauteils, wobei ein Solarmodul in ein Formgebungswerkzeug eingebracht ist;
• 28 einen auf den Verfahrensschritt aus 28 folgenden weiteren Verfahrensschritt der Ausführungsform des Verfahrens zur Herstellung eines Hybridbauteils, wobei ein Grundkörper aus einem Kunststoffmaterial an das Solarmodul angespritzt ist;
• 29 einen schematischen Schnitt eines mittels der in den 27 und 28 dargestellten Ausführungsform des Verfahrens zur Herstellung eines Hybridbauteils hergestellten Hybridbauteils;
• 30 einen auf den Verfahrensschritt aus 29 folgenden weiteren Verfahrensschritt der Ausführungsform des Verfahrens zur Herstellung eines Hybridbauteils, wobei eine Beschichtungskavität in dem Formgebungswerkzeug gebildet wird;
• 31 einen auf den Verfahrensschritt aus 30 folgenden weiteren Verfahrensschritt der Ausführungsform des Verfahrens zur Herstellung eines Hybridbauteils, wobei eine Beschichtung aus einem Beschichtungsmaterial auf das Solarmodul und/oder auf den Grundkörper aufgebracht ist;
• 32 einen schematischen Schnitt eines mittels der in den 27, 28, 30 und 31 dargestellten Ausführungsform des Verfahrens zur Herstellung eines Hybridbauteils hergestellten Hybridbauteils;
• 33 einen schematischen Schnitt einer weiteren Ausführungsform eines Hybridbauteils;
• 34 einen schematischen Schnitt einer weiteren Ausführungsform eines Hybridbauteils;
• 35 einen schematischen Schnitt einer weiteren Ausführungsform eines Hybridbauteils;
• 36 einen schematischen Schnitt einer weiteren Ausführungsform eines Hybridbauteils;
• 37 eine schematische Draufsicht einer weiteren Ausführungsform eines Hybridbauteils;
• 38 einen schematischen Schnitt der Ausführungsform des Hybridbauteils aus 37 längs der Linie XXXVIII-XXXVIII in 37;
• 39 einen schematischen Schnitt einer Ausführungsform eines Formgebungswerkzeugs zur Herstellung eines Hybridbauteils;
• 40 einen ersten Verfahrensschritt einer weiteren Ausführungsform eines Verfahrens zur Herstellung eines Hybridbauteils, wobei das Formgebungswerkzeug aus 39 in einer geöffneten Stellung dargestellt ist;
• 41 einen auf den Verfahrensschritt aus 40 folgenden weiteren Verfahrensschritt des Verfahrens zur Herstellung eines Hybridbauteils, wobei ein Funktionselement dem Formgebungswerkzeug mittels einer Handhabungsvorrichtung zugeführt wird;
• 42 einen auf den Verfahrensschritt aus 41 folgenden weiteren Verfahrensschritt des Verfahrens zur Herstellung eines Hybridbauteils, wobei das Funktionselement an eine Werkzeugwandung einer ersten Formhälfte des Formgebungswerkzeugs sowie an Schieberelemente einer zweiten Formhälfte des Formgebungswerkzeugs angelegt wird;
• 43 einen auf den Verfahrensschritt aus 42 folgenden weiteren Verfahrensschritt des Verfahrens zur Herstellung eines Hybridbauteils, wobei die Handhabungsvorrichtung aus dem Formgebungswerkzeug heraus bewegt ist;
• 44 einen auf den Verfahrensschritt aus 43 folgenden weiteren Verfahrensschritt des Verfahrens zur Herstellung eines Hybridbauteils, wobei das Formgebungswerkzeug in einer geschlossenen Stellung dargestellt ist;
• 45 einen auf den Verfahrensschritt aus 44 folgenden weiteren Verfahrensschritt des Verfahrens zur Herstellung eines Hybridbauteils, wobei ein Grundkörper aus einem Kunststoffmaterial an das Funktionselement angespritzt ist;
• 46 einen auf den Verfahrensschritt aus 45 folgenden weiteren Verfahrensschritt des Verfahrens zur Herstellung eines Hybridbauteils, wobei das Hybridbauteil aus dem Formgebungswerkzeug entformt ist;
• 47 eine vergrößerte Darstellung des Bereichs XLVII in 45;
• 48 eine vergrößerte Darstellung des Bereichs XLVIII in 46; und
• 49 einen schematischen Schnitt einer weiteren Ausführungsform eines Formgebungswerkzeugs zur Herstellung eines Hybridbauteils.

In the drawings show:

• 1 an exploded view of a schematic section of an embodiment of a solar module;
• 2 a schematic section of the embodiment of the solar module 1 ;
• 3 a schematic plan view of the embodiment of the solar module 2 ;
• 4th a schematic section through the embodiment of the solar module 3 along the line IV-IV in 3 ;
• 5 an enlarged detail of a schematic section of a further embodiment of a solar module;
• 6th a schematic section of a further embodiment of a solar module;
• 7th a first method step of an embodiment of a method for producing a hybrid component;
• 8th one on the procedural step 7th following further method step of the embodiment of the method for producing a hybrid component;
• 9 one on the procedural step 8th following further method step of the embodiment of the method for producing a hybrid component;
• 10 an embodiment of a hybrid component produced with the embodiment of the method for producing a hybrid component;
• 11 a further embodiment of a hybrid component;
• 12th a schematic section through an embodiment of a molding tool for producing a hybrid component;
• 13th a first method step of an embodiment of a method for producing a hybrid component, a base body of the hybrid component being produced in an injection molding process;
• 14th one on the procedural step 13th following further method step of the embodiment of the method for producing a hybrid component;
• 15th a schematic section of one in the method step 13th manufactured base body of a hybrid component;
• 16 a schematic section of a functional element of a hybrid component;
• 17th one on the procedural step 14th following further method step of the embodiment of the method for producing a hybrid component, the functional element from 16 into a recess in the base body 15th is introduced;
• 18th a schematic section of the base body 15th as well as the functional element 16 wherein the functional element is partially introduced into a recess in the base body;
• 19th one on the procedural step 17th following further method step of the embodiment of the method for producing a hybrid component, wherein the functional element is materially connected, in particular glued, to the base body;
• 20th a schematic section of the with the base body 15th cohesively connected, in particular glued, functional element 16 ;
• 21 one on the procedural step 19th following further method step of the embodiment of the method for producing a hybrid component;
• 22nd one on the procedural step 21 following further method step of the embodiment of the method for producing a hybrid component;
• 23 one on the procedural step 23 following further method step of the embodiment of the method for producing a hybrid component, wherein a second and a third mold half of the molding tool as well as the base body and the functional element delimit a coating cavity;
• 24 one on the procedural step 23 following further method step of the embodiment of the method for producing a hybrid component, wherein a coating of a coating material is applied to the base body and to the functional element;
• 25th one on the procedural step 24 following further method step of the embodiment of the method for producing a hybrid component;
• 26th a schematic section of a means of the in the 13th until 25th illustrated embodiment of the method for producing a hybrid component produced hybrid component;
• 27 a first method step of a further embodiment of a method for producing a hybrid component, wherein a solar module is introduced into a molding tool;
• 28 one on the procedural step 28 following further method step of the embodiment of the method for producing a hybrid component, wherein a base body made of a plastic material is injection-molded onto the solar module;
• 29 a schematic section of a means of the in the 27 and 28 illustrated embodiment of the method for producing a hybrid component produced hybrid component;
• 30th one on the procedural step 29 following further method step of the embodiment of the method for producing a hybrid component, wherein a coating cavity is formed in the forming tool;
• 31 one on the procedural step 30th following further method step of the embodiment of the method for producing a hybrid component, wherein a coating of a coating material is applied to the solar module and / or to the base body;
• 32 a schematic section of a means of the in the 27 , 28 , 30th and 31 illustrated embodiment of the method for producing a hybrid component produced hybrid component;
• 33 a schematic section of a further embodiment of a hybrid component;
• 34 a schematic section of a further embodiment of a hybrid component;
• 35 a schematic section of a further embodiment of a hybrid component;
• 36 a schematic section of a further embodiment of a hybrid component;
• 37 a schematic top view of a further embodiment of a hybrid component;
• 38 a schematic section of the embodiment of the hybrid component 37 along the line XXXVIII-XXXVIII in 37 ;
• 39 a schematic section of an embodiment of a molding tool for producing a hybrid component;
• 40 a first method step of a further embodiment of a method for producing a hybrid component, wherein the shaping tool from 39 is shown in an open position;
• 41 one on the procedural step 40 following further method step of the method for producing a hybrid component, wherein a functional element is fed to the shaping tool by means of a handling device;
• 42 one on the procedural step 41 The following further method step of the method for producing a hybrid component, the functional element being applied to a tool wall of a first mold half of the molding tool and to slide elements of a second mold half of the molding tool;
• 43 one on the procedural step 42 following further method step of the method for producing a hybrid component, wherein the handling device is moved out of the forming tool;
• 44 one on the procedural step 43 following further method step of the method for producing a hybrid component, wherein the forming tool is shown in a closed position;
• 45 one on the procedural step 44 following further method step of the method for producing a hybrid component, wherein a base body made of a plastic material is injection-molded onto the functional element;
• 46 one on the procedural step 45 following further method step of the method for producing a hybrid component, wherein the hybrid component is demolded from the molding tool;
• 47 an enlarged view of the area XLVII in 45 ;
• 48 an enlarged view of the area XLVIII in 46 ; and
• 49 a schematic section of a further embodiment of a shaping tool for producing a hybrid component.

Identical or functionally equivalent elements are provided with the same reference symbols in all figures.

the 1 until 4th show an embodiment of a solar module designated as a whole by 100.

1 shows the solar module 100 in an exploded view.

The solar module 100 preferably comprises one or more solar cell elements 102 , which between two protective layers 104 made of a protective material 106 are arranged.

The solar cell elements are preferably in the protective material 106 of the two protective layers 104 welded in, in particular without gas inclusions and / or free of bubbles.

The protective layers 104 are preferably foils, in particular flexible foils.

Preferably the protective material is 106 a translucent, in particular transparent or translucent, polymer material.

The protective material 106 of the two protective layers 104 preferably comprises or consists of a polymer material, for example ethylene vinyl acetate (EVA), polyvinyl butyral (PVB), polyamide (PA), polymethyl methacrylate (PMMA) and / or polyurethane (PUR).

It can be particularly advantageous if the protective layers 104 Ethylene vinyl acetate (EVA) films are.

Preferably the solar cell elements are 102 of a respective solar module 100 between two protective layers designed as ethylene vinyl acetate (EVA) films 104 shrink wrapped.

The solar cell elements 102 are electrical components, in particular electrical semiconductor components, by means of which radiant energy, for example solar radiation, can be converted into electrical energy.

Preferably the solar cell elements are 102 by means of an electrical connection 103 connected to one another, for example soldered.

The one or more solar cell elements 102 are preferably completely made of the protective material 106 of the two protective layers 104 surround.

It can be favorable if all solar cell elements 102 a solar module 100 are arranged in one plane. In particular, solar cell elements overlap 102 of a respective solar module 100 Not.

It is conceivable, for example, that the solar cell elements 102 of a respective solar module 100 are arranged in a regular pattern (cf. 3 ).

The solar module 100 preferably further comprises a support layer 108 from a carrier material 110 as well as a top layer 112 from a cover material 114 .

The cover material 114 the top layer 112 and / or the carrier material 110 the carrier layer 108 preferably comprise or consist of a polymer material, for example polymethyl methacrylate (PMMA), polypropylene (PP), polycarbonate (PC) and / or ethylene-tetrafluoroethylene (ETFE).

The carrier layer 108 and / or the top layer 112 are preferably foils, in particular flexible foils.

For example, it is conceivable that the top layer 112 and / or the carrier layer 108 each are polymethyl methacrylate (PMMA) films, polypropylene (PP) films, polycarbonate (PC) films and / or ethylene-tetrafluoroethylene (ETFE) films.

It is conceivable, for example, that the carrier material 110 the carrier layer 108 and the cover material 114 the top layer 112 are identical. Alternatively, it is conceivable that the carrier material 110 the carrier layer 108 and the cover material 114 the top layer 112 are different from each other.

It is conceivable, for example, that the carrier material 110 the carrier layer 108 and / or the cover material 114 the top layer 112 translucent, in particular transparent or translucent, polymer materials.

It can be particularly favorable if the cover material 114 the top layer 112 is a translucent polymer material, in particular a transparent or translucent material.

It is also conceivable that the carrier material 110 the carrier layer 108 is an opaque polymer material. It is possible, for example, by selecting a color for the carrier material 110 the carrier layer 108 one color of the solar module 100 is determinable.

Preferably those are between the two protective layers 104 arranged solar cell elements 102 together with the two protective layers 104 between the carrier layer 108 and between the top layer 112 arranged.

The carrier layer 108 and / or the carrier material 110 the carrier layer 108 are preferably used for thermal insulation of the solar cell elements 102 of the solar module 100 and / or for thermal insulation of the protective layers 104 .

Preferably, the solar cell elements can be thermally insulated 102 of the solar module 100 damage to the solar cell elements 102 and / or damage to electrical contacting of the solar cell elements 102 , for example damage to the electrical connection 103 , be prevented.

It can also be beneficial if the solar cell elements are thermally insulated 102 of the solar module 100 furthermore, thermal damage, for example melting, of the protective layers 104 can be prevented.

• - Polypropylen (PP)-Folie; Ethylen-Vinylacetat (EVA)-Folie; Solarzellenelement 102; Ethylen-Vinylacetat (EVA)-Folie; Polypropylen (PP)-Folie; oder
• - Polycarbonat (PC)-Folie; Ethylen-Vinylacetat (EVA)-Folie; Solarzellenelement 102; Ethylen-Vinylacetat (EVA)-Folie; Polycarbonat (PC)-Folie; oder
• - Ethylen-Tetrafluorethylen (ETFE)-Folie; Ethylen-Vinylacetat (EVA)-Folie; Solarzellenelement 102; Ethylen-Vinylacetat (EVA)-Folie; Ethylen-Tetrafluorethylen (ETFE)-Folie.

For example, it is conceivable that the solar module 100 has the following layer structure in a thickness direction:

• - polypropylene (PP) film; Ethylene vinyl acetate (EVA) film; Solar cell element 102 ; Ethylene vinyl acetate (EVA) film; Polypropylene (PP) film; or
• - polycarbonate (PC) film; Ethylene vinyl acetate (EVA) film; Solar cell element 102 ; Ethylene vinyl acetate (EVA) film; Polycarbonate (PC) film; or
• - ethylene tetrafluoroethylene (ETFE) film; Ethylene vinyl acetate (EVA) film; Solar cell element 102 ; Ethylene vinyl acetate (EVA) film; Ethylene tetrafluoroethylene (ETFE) film.

The two protective layers 104 , in which in turn in particular the solar cell elements 102 are welded, are preferably between the carrier material 110 the carrier layer 108 and the cover material 114 the top layer 112 shrink wrapped.

The two protective layers 104 are in particular completely made of the carrier material 110 the carrier layer 108 and the cover material 114 the top layer 112 surround.

The two protective layers 104 , in which the solar cell elements 102 are welded, are preferably without gas inclusions and / or bubble-free between the carrier material 110 the carrier layer 108 and the cover material 114 the top layer 112 shrink wrapped.

The solar module 100 is produced, for example, by lamination, in particular by lamination of the solar cell elements 102 in a foil material.

The solar module 100 is preferably made by vacuum lamination.

The solar cell elements 102 of the solar module 100 are preferably electrically connected to one another before lamination, in particular soldered to one another.

Preferably the protective layers 104 , the top layer 108 and / or the carrier layer 112 heated during lamination.

The protective layers 104 , the carrier layer 108 and / or the top layer 112 are in particular fused to one another at least in some areas.

It can be beneficial if the protective layers 104 , the carrier layer 108 and / or the top layer 112 heated to a lamination temperature in the range of about 40 ° C to about 140 ° C.

A lamination time during which a solar module 100 is made by lamination is preferably between about 10 minutes and about 100 minutes. It can be beneficial if the solar module 100 is maintained at the lamination temperature during the lamination time.

It can be particularly favorable if the solar cell elements 102 of the solar module 100 first in the protective layers 104 from the protective material 106 be laminated in. Preferably then those in the protective material 106 laminated solar cell elements 102 between the carrier layer 108 and the top layer 112 laminated.

Alternatively, it is conceivable that the solar cell elements 102 of the solar module 100 at the same time in the protective layers 104 from the protective material 106 and between the carrier layer 108 and the top layer 112 be laminated in.

The solar module 100 is preferably a sandwich component 116 .

The solar module 100 is preferably deformable, in particular three-dimensionally deformable. By reshaping the solar module 100 In particular, a three-dimensionally curved surface can be produced.

The solar module 100 is preferably non-destructive deformable, in particular without destroying the solar cell elements 102 of the solar module 100 . A non-destructive reshaping of the solar module can preferably be used 100 through the two protective layers 104 , through the carrier layer 108 and / or through the top layer 112 of the solar module 100 guaranteed.

By means of the two protective layers 104 , the carrier layer 108 and / or the top layer 112 is in particular an equalization of the introduction of force into the solar module 100 realizable.

A maximum degree of deformation up to which the solar module 100 Is non-destructive deformable, is preferably through a choice of protective material 106 , by a choice of the carrier material 110 and / or through a choice of cover material 114 influenceable.

A maximum degree of deformation up to which the solar module 100 Is non-destructive deformable, is preferably also by choosing a material thickness of the two protective layers 104 by choosing a material thickness of the carrier layer 108 and/ or by choosing a material thickness for the top layer 112 influenceable.

It can also be favorable if a maximum temperature, up to which the solar module 100 Can be further processed non-destructively by choosing a material thickness of the two protective layers 104 , by choosing a material thickness of the carrier layer 108 and / or by choosing a material thickness for the top layer 112 can be influenced.

The solar module 100 preferably further comprises one or more connection elements 118 , in particular one or more mechanical connection elements 120 and / or one or more electrical connection elements 122 (cf. 4th ). The mechanical connection elements 120 are in 4th only indicated schematically by an arrow.

One or more mechanical connection elements 120 are in particular fastening elements, for example fastening projections and / or fastening recesses. The solar module 100 comprises, for example, one or more fastening projections designed as retaining pins.

An electrical connection element 122 each includes, for example, one or more connection cables 124 , by means of which solar cell elements 102 of the solar module 100 are electrically contactable.

One in 5 illustrated embodiment of a solar module 100 differs from that in the 1 until 4th illustrated embodiment of a solar module 100 essentially in that the electrical connection element 122 a sleeve element 126 includes.

Preferably the connection cables are 124 in the sleeve element 126 recorded, in particular passed through this.

Incidentally, the in 5 illustrated embodiment of a solar module 100 in terms of structure and function with the 1 until 4th illustrated embodiment of a solar module 100 so that reference is made to their description above.

One in 6th illustrated embodiment of a solar module 100 differs from that in the 1 until 4th illustrated embodiment of a solar module 100 essentially in that the electrical connection element 122 a ribbon cable 130 and a plug 132 includes.

Incidentally, the in 6th illustrated embodiment of a solar module 100 in terms of structure and function with the 1 until 4th illustrated embodiment of a solar module 100 so that reference is made to their description above.

the 7th until 9 show method steps of an embodiment of a method for producing an in 10 illustrated embodiment of a hybrid component 132 , which has a basic body 134 made of a plastic material and a functional element 136 includes.

The functional element 136 is, for example, an embodiment of the 4th until 6th solar module shown 100 .

At the in 10 illustrated embodiment of the hybrid component 132 is the basic body 134 preferably cohesively with the solar module 100 connected, in particular glued.

The solar module 100 is preferably by means of an adhesive material 138 cohesively with the main body 134 connected, in particular glued.

The basic body 134 of the hybrid component 132 is in particular an injection molded component. The plastic material is preferably the base body 134 an injectable plastic material.

The plastic material of the base body 134 is for example a thermoplastic plastic material, for example polycarbonate (PC), polymethyl methacrylate (PMMA) or polypropylene (PP).

The basic body 134 of the hybrid component 132 is preferably a base body produced in an injection molding process, in particular a base body produced in an injection molding process or in an injection compression molding process 134 .

It can therefore be advantageous if the base body is first 134 is produced in an injection process (cf. 7th ) and then by means of the adhesive material 138 cohesively with the solar module 100 connected, in particular glued, is (cf. 8th ).

The carrier material of the carrier layer 108 of the solar module 100 acts in particular as an adhesion promoter, which creates an integral connection of the solar module 100 with the adhesive material 138 relieved.

The basic body 134 in particular forms a reinforcing element 140 of the hybrid component 132 .

The basic body 134 preferably comprises a depression 142 to accommodate the solar module 100 .

It can also be favorable if the base body 134 a mounting side 144 and a front 146 having.

The basic body 136 preferably comprises one or more mounting elements 148 , which on the mounting side 144 of the main body 134 are arranged and are only indicated schematically by means of an arrow.

The basic body 134 is preferably by means of the mounting elements 148 can be mounted on a supporting structure, for example on a supporting structure of a motor vehicle.

The assembly elements 148 are for example when manufacturing the base body 134 molded onto this in an injection process.

The hybrid component 132 is, for example, a motor vehicle component 150 , for example a body component for a motor vehicle.

The front 146 of the main body 134 is in particular one of the assembly side 144 remote side of the base body 134 .

The depression 142 , in which the solar module 100 of the hybrid component 132 is arranged, is in particular on the front 146 of the main body 134 arranged.

The depression 142 of the main body 134 preferably has an inner contour which is essentially an outer contour of the solar module 100 is equivalent to.

The depression 142 is in particular one of a surface of the base body 134 on the front side 146 the same outgoing material recess.

The solar module 100 is preferably at least partially, in particular essentially completely, in the depression 142 of the main body 134 recorded.

It can be beneficial if the deepening 142 of the main body 134 a depth 152 has (cf. 7th and 10 ), which is equal to or greater than a thickness 154 of the solar module 100 (cf. 8th and 10 ).

The depression preferably has 142 of the base body a depth 152 on which is the sum of the thickness 154 of the solar module 100 and a material thickness 156 of the adhesive material 138 is equivalent to.

One surface of the solar module is preferably 100 on the visible side 147 of the hybrid component 132 flush with a surface of the base body 134 on the visible side 147 of the hybrid component 132 arranged. The surface of the solar module 100 and the surface of the base body 134 are on the visible side 147 of the hybrid component 132 in particular arranged in one plane.

This in 10 Hybrid component shown 132 includes on one of the base body 134 remote side of the solar module 100 preferably a coating 158 from a coating material 160 which on the solar panel 100 and / or on the front 146 of the main body 134 is upset.

The coating 158 is preferably in the same shaping tool on the solar module 100 and / or on the front 146 of the main body 134 applied in which the base body 134 of the hybrid component 132 is made.

The coating material 160 is preferably a translucent, in particular transparent or translucent, plastic material, in particular a lacquer material.

It can be beneficial if the coating material 160 comprises or consists of a polyurethane (PU) lacquer, a polyurea (PUA) lacquer, a silicone resin material and / or an epoxy resin.

The coating 158 covers the solar panel 100 of the hybrid component 132 preferably completely.

It can also be favorable if the coating 158 the main body 134 of the hybrid component 132 on the front side 146 the same partially covers.

The hybrid component 132 points to the visible side 147 preferably a Class A surface.

One in 11 illustrated embodiment of a hybrid component 132 differs from the in 10 illustrated embodiment of a hybrid component 132 essentially in that the base body 134 of the hybrid component 132 not just partially, but completely from the coating 158 is covered.

Incidentally, the in 11 illustrated embodiment of a hybrid component 132 in terms of structure and function with the in 10 illustrated embodiment of a hybrid component 132 so that reference is made to their description above.

Another embodiment of the hybrid component, not shown in the drawing 132 differs from the in 10 illustrated embodiment of a hybrid component 132 essentially in that the base body 134 is manufactured in a two-component injection molding process, the base body 134 comprises a translucent, in particular transparent or translucent, base body part made of a translucent, in particular transparent or translucent, plastic material and a non-transparent base body part made of an opaque plastic material, the translucent base body part on a front side 146 of the main body 134 is arranged.

It can be favorable if the translucent, in particular transparent or translucent, plastic material of the translucent base body part comprises or consists of polycarbonate (PC) or polymethyl methacrylate (PMMA).

It can also be favorable if the non-transparent plastic material of the non-transparent base body part comprises or consists of a blend of polycarbonate (PC) and acrylonitrile-butadiene-styrene (ABS).

The non-transparent main body part in particular forms a frame element for the translucent main body part.

The depression 142 of the main body 134 to accommodate the solar module 100 is preferably a material recess in the non-transparent main body part. The translucent base body part preferably covers the solar module 100 on one side 147 of the hybrid component 132 completely off.

12th shows a schematic section through an embodiment of a shaping tool 162 .

The shaping tool 162 is in particular a plunge edge tool 164 .

The shaping tool 162 preferably comprises a first mold half 166 , a second mold half 168 as well as a third mold half 170 .

The second half of the mold 168 is preferably on an insert 172 arranged.

The insert 172 is preferably in the direction of the arrow 174 rotatable so that the second mold half 168 by means of the insert 172 optionally to the first half of the mold 166 or to the third mold half 170 is directed.

The second half of the mold 168 preferably comprises several displacement elements 176 , which in particular as slide elements 178 are trained. For reasons of clarity, the displacement elements are 176 and / or the slide elements 178 only in 12th marked with a reference symbol.

It can be beneficial if the slide elements 178 the second half of the mold 168 are displaceable between an injection position and an insertion position.

The slide elements of the second mold half are preferably located 168 in the injection position of the same on a mold wall 179 the first half of the mold 166 especially when the forming tool 162 closed is.

This in 12th Shaping tool shown 162 is used in particular to carry out the 13th until 25th illustrated further embodiment of a method for producing a hybrid component 132 .

the 13th until 25th show method steps of the embodiment of a method for producing an in 26th illustrated embodiment of a hybrid component 132 , which has a basic body 134 and a functional element 136 includes.

A base body is preferably used first 134 made of a plastic material in an injection molding process in the molding tool 162 produced.

When manufacturing the base body 134 is preferably a depression 142 to accommodate the functional element 136 , in particular for receiving the solar module according to the invention 100 , produced.

The basic body 134 is in particular by introducing an injectable plastic material, in particular by introducing a melt-processable plastic material, into an injection cavity 180 of the shaping tool 162 manufactured (cf. 13th ).

The injection cavity 180 is particularly affected by the first half of the mold 166 and from the second mold half 168 of the shaping tool 162 limited.

The injection process is, for example, an injection molding process or an injection compression molding process.

Preferably with the plunge edge tool 164 an injection compression molding process can be carried out.

It can be beneficial if the injection molding cavity is used in an injection compression molding process 180 of the shaping tool 162 is reduced or enlarged after the injection of the injectable plastic material.

The plastic material preferably comprises the base body 134 Polycarbonate (PC), polymethyl methacrylate (PMMA) or polypropylene (PP) or a blend of polycarbonate (PC) and acrylonitrile-butadiene-styrene (ABS) or consists of this.

When manufacturing the base body 134 are preferably one or more passage openings 182 in the main body 134 produced, which in particular for receiving and / or implementation of one or more connection elements 118 of a functional element 136 , for example a solar module 100 , serve. The passage openings 182 are for example in the 15th , 18th , 20th and 26th marked with a reference symbol.

The one or more passage openings are preferably used 182 when manufacturing the base body 134 by means of the displacement elements 176 , in particular by means of the slide elements 178 , produced.

Preferably the slide elements 178 for making the passage openings 182 on a tool wall of the first mold half 166 created.

It can be beneficial if the slide elements 178 the second half of the mold 168 after manufacturing the base body 134 be moved from the injection position to the loading position.

Preferably the slide elements are 178 the second half of the mold 168 in the insertion position partially or essentially completely out of the passage openings 182 of the main body 134 moved out so that connecting elements 118 of a functional element 136 in the passage openings 182 can be received or passed through them.

After producing the base body 134 becomes the shaping tool 162 preferably opened by the first mold half 166 and the second mold half 168 be moved apart (cf. 14th ).

The basic body 134 of the hybrid component 132 is for example in 15th shown in isolation, with the functional element 136 in 16 is shown.

The functional element is preferably 136 the shaping tool 162 by means of an in the 13th until 25th handling device not shown in the drawing supplied (cf. 17th ).

Thereby the functional element 136 by means of the handling device in particular relative to the base body 134 positioned. The connection elements are preferably 118 of the functional element 136 at least partially in the passage openings 182 of the main body 134 introduced (cf. 17th and 18th ).

The functional element 136 is particularly in the recess 142 of the main body 134 introduced.

Preferably is in the recess 142 already an adhesive material 138 which is in the 14th until 26th is only indicated schematically by means of an arrow, introduced. As an alternative or in addition to this, it is conceivable that the adhesive material 138 on the functional element 136 , especially on an assembly side 144 of the functional element 136 is upset.

It can be beneficial if the adhesive material 138 as a film material on the functional element 136 and / or on the main body 134 is applied.

Alternatively, it is conceivable that the adhesive material 138 in liquid or paste form on the functional element 136 and / or on the main body 134 is applied.

The adhesive material 138 is for example a temperature-curing and / or UV-curing adhesive material 138 .

It is conceivable that a temperature-curing adhesive material 138 by means of the shaping tool 162 is cured, which is, for example, a variothermal shaping tool 162 is.

A UV curing adhesive material 138 is preferably cured by means of UV radiation. It can be advantageous if the handling device by means of which the functional element 136 the shaping tool 162 is supplied, a UV radiation device is arranged.

As an alternative to applying the adhesive material 138 on the main body 134 it is conceivable that the plastic material, in particular the thermoplastic plastic material, of the base body 134 on a surface of the base body 134 is melted in areas, especially in the recess 142 .

The functional element is preferably 136 with the main body 134 of the hybrid component 132 then firmly bonded (cf. 19th and 20th ).

It can be beneficial if the functional element 136 before the material connection with the base body 134 of the hybrid component 132 is heated.

For example, it is conceivable that the functional element 136 before the material connection with the base body 134 is heated by means of a heating device, for example by means of an infrared heating device, which is arranged for example on the handling device by means of which the functional element 136 the shaping tool 162 is fed.

The main body preferably remains 134 during the material connection of the same with the functional element 136 in the forming tool 162 shape-related, by means of which the base body 134 will be produced.

The basic body 134 is used for a material connection with the functional element after it has been produced 136 especially not from the second mold half 168 of the shaping tool 162 demolded.

The basic body 134 is used for a material connection with the functional element after it has been produced 136 preferably only from the first half of the mold 166 demolded.

19th shows that the functional element 136 and the main body 134 are pressed against each other for the material connection of the same, in particular by moving the first mold half together 166 and the second mold half 168 of the shaping tool 162 .

As an alternative or in addition to this, it is conceivable that the functional element 136 by means of a handling device against the base body 134 is pressed. If the functional element 136 by means of a handling device against the base body 134 is pressed, it is preferably supported on a tool wall of the second mold half 168 of the shaping tool 162 away.

Preferably the functional element 136 and the main body 134 pressed together for a cohesive connection of the same.

It can be beneficial if the functional element 136 is at least partially deformed when the functional element 136 and the main body 134 are pressed against each other for a material connection of the same.

If the functional element 136 one in the 1 until 6th shown solar module 100 is, become the carrier material 110 the carrier layer 108 of the solar module 100 and / or the plastic material of the base body 134 preferably matched to one another, in particular in such a way that molecules of the carrier material 110 and molecules of the plastic material of the base body 134 preferentially enter into an interaction with one another.

The carrier material 110 and the plastic material of the base body 134 preferably have mutually compatible surface properties.

It can also be favorable if by choosing a color of the plastic material of the base body 134 a color of the hybrid component can be specified. Preferably the two are protective layers 104 , the carrier layer 108 and / or the top layer 112 of the solar module 100 made from a translucent, in particular transparent or translucent, polymer material.

The one with the functional element 136 cohesively connected base body 134 is for example in 20th shown.

Preferably, after the material connection of the functional element 136 with the main body 134 a coating 158 from a coating material 160 on the functional element 136 and / or on the main body 134 upset.

The shaping tool is preferably used first 162 opened by the first mold half 166 and the second mold half 168 in an opening direction and / or main demolding direction of the forming tool 162 be moved apart (cf. 21 ).

Then preferably the first mold half 166 through the third mold half 170 of the shaping tool replaced, in particular by turning the insert 172 (cf. 22nd ).

The shaping tool 162 is then preferably closed again, in particular by removing the second mold half 168 and the third mold half 170 be brought together again (cf. 23 ).

The second half of the mold 168 and the third mold half 170 limit it together with a surface of the base body 134 and a surface of the functional element 136 a coating cavity 184 (cf. 23 ).

It is preferred to apply the coating 158 a coating material 160 , in particular a translucent plastic material, preferably a lacquer material, into the coating cavity 184 introduced (cf. 24 ). Thus the coating 158 preferably in the same forming tool 162 on the functional element 136 and / or on the main body 134 applied, by means of which the base body 134 will be produced.

Preferably the coating material comprises 160 a polyurethane (PU) lacquer, a polyurea (PUA) lacquer, a silicone resin material and / or an epoxy resin or is formed by these.

It can be beneficial if the coating material 160 a scratch-resistant coating material 160 is.

The coating cavity is preferably 184 when applying the coating material 160 essentially completely filled. It is conceivable that the coating cavity 184 after the application of the coating material 160 is reduced or enlarged in the same.

The coating 158 is achieved in particular by introducing the coating material 160 into the coating cavity 184 on the functional element 136 and / or on the main body 134 upset.

After applying the coating 158 on the main body 134 and / or on the functional element 136 becomes the shaping tool 162 preferably reopened, in particular by placing the second mold half 168 and the third mold half 170 be moved apart in the opening direction and / or in the main demolding direction (cf. 25th ).

The in 26th illustrated hybrid component 132 covers the coating 158 preferably the functional element 136 of the hybrid component 132 completely off.

It can also be favorable if the coating 158 the main body 134 of the hybrid component 134 on the front side 146 the same essentially completely covers.

If the coating is the functional element 136 and the main body 134 of the hybrid component 132 on the visible side 147 of the hybrid component 132 essentially completely covers, a uniform and, in particular, attractive visual appearance of the hybrid component can preferably be achieved 132 can be achieved.

The functional element can preferably 136 , especially the solar panel 100 by applying the coating 158 be protected from external influences, such as the weather.

The functional element 136 , in particular the solar module according to the invention 100 , can be done by applying the coating 158 in particular be protected from UV radiation.

29 shows a further embodiment of a hybrid component 132 , in which the main body 134 to a solar module 100 is molded on.

The basic body 134 in particular forms a reinforcing element of the hybrid component 132 .

This in 29 illustrated embodiment of the hybrid component 132 is in particular by an embodiment of a in the 27 and 28 illustrated method for the production of a hybrid component 132 produced.

The basic body 134 of the in 29 illustrated hybrid component 132 is with the solar panel 100 by molding on the base body 134 to the solar module 100 preferably cohesively connected.

This in 27 Shaping tool shown 162 is preferably a plunge edge tool 164 .

The shaping tool 162 preferably comprises a first mold half 166 and a second mold half 168 .

Preferably the solar module 100 before molding on the base body 134 on a mold wall 186 the second half of the mold 168 of the shaping tool 162 applied, in particular in such a way that a surface of the cover layer 112 of the solar module 100 essentially completely on the mold wall 186 is present.

It is possible, for example, that the solar module 100 when applying it to the tool wall 186 of the shaping tool 162 is at least partially reshaped.

Preferably delimit the first mold half 166 , the second half of the mold 168 and the solar panel 100 an injection cavity 180 (cf. 27 ).

The basic body 134 is achieved in particular by introducing an injectable plastic material, in particular by introducing a melt-processable plastic material, into the injection cavity 180 of the shaping tool 162 to the solar module 100 injected (cf. 28 ).

An injection process in which the main body 134 to the solar module 100 is injected is, for example, an injection molding process or an injection compression molding process.

The basic body 134 is made in particular by back-molding onto the solar module 100 injected.

This is where the carrier material works 110 the carrier layer 108 of the solar module 100 in particular as an adhesion promoter, which creates an integral connection of the solar module 100 with the plastic material of the base body 134 relieved.

The plastic material of the base body 134 is for example a non-transparent plastic material.

It can be favorable if the plastic material of the base body 134 Polycarbonate (PC), polymethyl methacrylate (PMMA) or polypropylene (PP) or a blend of polycarbonate (PC) and acrylonitrile-butadiene-styrene (ABS) or consists of this.

One in 32 illustrated embodiment of a hybrid component 132 differs from the in 29 illustrated embodiment of a hybrid component 132 essentially in that the hybrid component 132 on one of the main body 134 remote side of the solar module 100 a coating 158 from a coating material 160 includes which on the solar module 100 and / or on a front side 146 of the main body 134 is upset.

The coating 158 covers the basic body 134 of the hybrid component 132 on the front side 146 preferably essentially completely.

The hybrid component preferably has 132 on the visible side 147 a Class A surface.

By that the coating 158 the solar module 100 and the main body 134 of the hybrid component 132 on the visible side 147 of the hybrid component 132 essentially completely covers, a uniform and, in particular, attractive visual appearance of the hybrid component can preferably be achieved 132 can be achieved.

In the 32 illustrated embodiment of a hybrid component 132 is preferably by an embodiment of a method for producing a hybrid component 132 manufactured, which in addition to those in the 27 and 28 procedural steps shown in the 30th and 31 comprises illustrated process steps.

For applying the coating 158 a translucent, in particular transparent or translucent, plastic material, in particular a lacquer material, is preferably placed in a coating cavity 184 introduced, which from a tool wall 186 of the shaping tool 162 on the one hand and from a surface of the base body 134 as well as a surface of the solar module 100 on the other hand is limited.

Preferably the coating 158 in the same forming tool 162 on the solar module 100 and / or on the main body 134 applied in which the base body 134 to the solar module 100 is injected.

The base body remains after it has been molded onto the solar module 100 for applying the coating 158 preferably in the first half of the mold 166 of the shaping tool 162 form-bound.

The coating 158 is achieved in particular by introducing the coating material 160 into the coating cavity 184 on the solar module 100 and / or on the main body 134 upset.

The coating cavity is preferably 184 when applying the coating material 160 essentially completely filled.

It is possible, for example, that the coating cavity 184 after the application of the coating material 160 is reduced or enlarged in the same.

The coating material 160 is preferably a translucent, in particular a transparent or translucent, plastic material, in particular a lacquer material.

Preferably the coating material comprises 160 a polyurethane (PU) lacquer, a polyurea (PUA) lacquer, a silicone resin material and / or an epoxy resin or consists of these.

It can be beneficial if the coating material 160 a scratch-resistant coating material 160 is.

Preferably, the solar module 100 by applying the coating 158 from outside Influences, for example from the weather, in particular from UV radiation, are protected.

It can be particularly advantageous if the carrier material 110 the carrier layer 108 of the solar module 100 and / or the plastic material of the base body 134 are coordinated with one another, in particular in such a way that molecules of the carrier material 110 and molecules of the plastic material of the base body 134 preferentially enter into an interaction with one another.

It can be beneficial if the carrier material 110 the carrier layer 108 of the solar module 100 and the plastic material of the base body 134 have mutually compatible surface properties.

In particular, there can be a shrinkage behavior of the plastic material of the base body 134 to the carrier material 110 the carrier layer 108 of the solar module 100 be adjusted.

Incidentally, the in 32 illustrated embodiment of a hybrid component 132 in terms of structure and function with the in 29 illustrated embodiment of a hybrid component 132 so that reference is made to their description above.

One in 33 illustrated embodiment of a hybrid component 132 differs from the in 32 illustrated embodiment of the hybrid component 132 essentially in that the coating is the base body 134 of the hybrid component 132 only partially covers.

Incidentally, the in 33 illustrated embodiment of a hybrid component 132 in terms of structure and function with the in 32 illustrated embodiment of a hybrid component 132 so that reference is made to their description above.

One in 34 illustrated embodiment of a hybrid component 132 differs from the embodiment of the hybrid component shown in FIG 132 essentially in that the base body 134 by spraying it onto the solar module 100 is positively connected with this.

It can be particularly advantageous if the base body 134 the solar module 100 at least partially encompassed, in particular at an edge region of the solar module 100 .

Incidentally, the in 34 illustrated embodiment of a hybrid component 132 in terms of structure and function with the in 29 illustrated embodiment of a hybrid component 132 so that reference is made to their description above.

In the 35 and 36 are method steps of an embodiment of a method for producing an in 36 illustrated hybrid component 132 shown.

The in 36 illustrated hybrid component 132 is the basic body 134 especially in a two-component spray process on the solar module 100 molded on and preferably comprises a translucent, in particular transparent or translucent, base body part 188 made of a translucent, in particular transparent or translucent, plastic material and a non-transparent main body part 190 made of a non-transparent plastic material

It is conceivable, for example, that the translucent main body part 188 on one side 147 of the solar module 100 is injected onto this (cf. 35 ).

It can be advantageous, for example, if the light-permeable, in particular transparent or translucent, plastic material of the light-permeable base body part 188 Polycarbonate (PC) or polymethyl methacrylate (PMMA) comprises or consists of this.

The translucent body part 188 covers the solar panel 188 on one side 147 of the hybrid component 132 preferably completely.

It can also be favorable if the non-transparent main body part 190 on one of the visible side 147 of the solar module 100 remote side is injected onto this (cf. 36 ).

The non-transparent plastic material preferably comprises the non-transparent main body part 190 a blend of polycarbonate (PC) and acrylonitrile-butadiene-styrene (ABS) or consists of this.

By choosing a color for the non-transparent plastic material of the non-transparent main body part 190 can preferably be a color of the hybrid component 132 be determined.

The non-transparent main body part preferably covers 190 the solar module 100 on one of the visible side 147 remote side of the solar module 100 completely off.

The non-transparent main body part 190 includes in particular a mounting side 144 of the main body 134 .

The non-transparent main body part 190 forms in particular a frame element for the translucent main body part 188 .

One in the 37 and 38 illustrated embodiment of a hybrid component 132 differs from the in 36 illustrated embodiment of the hybrid component 132 essentially in that the non-transparent main body part 190 the solar module 100 on one of the visible side 147 of the hybrid component 132 remote side of the solar module 100 only partially covers.

The non-transparent main body part 190 includes, for example, a rib structure 192 .

Incidentally, it is correct in the 37 and 38 illustrated embodiment of a hybrid component 132 in terms of structure and function with the in 36 illustrated embodiment of a hybrid component 132 so that reference is made to their description above.

39 shows a further embodiment of a forming tool 162 .

The shaping tool 162 is used in particular to carry out the 40 until 48 illustrated embodiment of a method for producing a hybrid component 132 .

The shaping tool 162 preferably comprises a first mold half 166 and a second mold half 168 .

The first mold halves are preferably 166 and second mold half 168 movable relative to one another, in particular between an open position and a closed position of the shaping tool 162 .

Preferably delimit the first mold half 166 and the second mold half 168 in a closed position of the forming tool 162 an injection cavity 180 , in particular together with one in the shaping tool 162 introduced functional element 136 (cf. 44 ).

The second mold half preferably comprises 168 one or more slide elements 178 .

The slide elements 178 are preferably so-called "leading slide elements".

It can be beneficial if the slide elements 178 are essentially cylindrical. The one or more slide elements 178 are for example pin elements.

The slide elements 178 the second half of the mold 168 are preferably relative to the second mold half 168 movable on the second half of the mold 168 arranged.

It can be beneficial if the slide elements 178 parallel to a main demolding direction and / or parallel to an opening direction of the forming tool 162 are relocatable.

It can be beneficial if the shaping tool 162 furthermore a displacement device 194 comprises, by means of which the slide elements 178 relative to the second mold half 168 are relocatable.

At the in 39 illustrated embodiment of the shaping tool 162 are in particular all slide elements 178 by means of the displacement device 194 synchronously relocatable.

The displacement device preferably comprises 194 thereby a slide plate 196 .

In particular, there are all slide elements 178 of the shaping tool 162 with the slide plate 196 motion-coupled.

The slide plate 196 is preferably on the second mold half 168 of the shaping tool 162 arranged, but displaceable relative to this.

Alternative to a gate valve 196 it can be provided that by means of the displacement device 194 individual slide elements 178 can be moved independently of one another.

For example, it can be provided that a respective slide element 178 by means of a piston device, not shown in the drawing, of the displacement device 194 is relocatable.

A respective piston device of the displacement device 194 is for example a hydraulic or pneumatic piston device and preferably comprises a piston which can be displaced by applying pressure to a pressure chamber.

It can be beneficial if a functional element 136 by means of the slide elements 178 by moving the same to a tool wall 186 the first half of the mold 166 can be applied (cf. 42 and 43 ).

The slide elements are in particular here 178 to the functional element 136 applicable.

Preferably the slide elements are 178 which are attached to a functional element 136 can be applied, each by means of a spring device 198 resilient on the second half of the mold 168 of the shaping tool 162 arranged.

Preferably the slide elements are 178 by means of the spring device 198 each resilient with the displacement device 194 , especially with the slide plate 196 the relocation facility 194 , connected.

The slide elements 178 are by means of the spring device 198 in particular parallel to a direction of displacement of the slide elements 178 resilient on the second half of the mold 168 of the shaping tool 162 arranged.

By means of the on the spring device 198 arranged slide elements 178 is preferably a compensation for a thickness tolerance of a functional element 136 realizable. In particular, by means of the on the spring device 198 arranged slide elements 178 a defined pressure on a functional element 136 feasible so that the slide elements 178 to a functional element 136 can be applied without destroying it.

It can be beneficial if the slide elements 178 themselves are essentially rigid, in particular parallel to a direction of displacement thereof.

Preferably, a spring action is essentially completely provided by the spring device 198 provided.

In the case of the 39 until 46 illustrated embodiment of the shaping tool 162 is the spring device 198 in particular a mechanical spring device and comprises, for example, one helical spring element in each case 200 , which consists in particular of spring steel.

It can be favorable if a spring force of the spring device 198 is adjustable and / or controllable.

It can also be favorable if the spring device 198 a pneumatic spring device, not shown in the drawing, or a hydraulic spring device, not shown in the drawing. A pneumatic spring device or a hydraulic spring device preferably each comprises a piston device or is formed by this.

It can be beneficial if the relocation device 194 the spring device 198 includes or forms, especially if the displacement device 194 comprises a piston device. The spring device 198 is for example of the piston device of the displacement device 194 educated.

A spring force of a pneumatic or hydraulic spring device is preferably adjustable and / or controllable, for example by setting and / or regulating a pressure in a pressure chamber of a piston device.

the 39 until 46 and in particular the enlarged view in 37 show that a slide element 178 a cover element 202 for covering a connection element 118 of the functional element 136 includes or forms.

The cover element 202 serves, for example, to cover a single connection element 118 of a functional element 136 .

The cover element 202 preferably comprises a receiving space 204 , in which a connection element 118 of a functional element 118 is recordable, in particular completely.

A recording room 204 a cover element is, for example, through a recess in the slide element 178 formed, for example by a cylindrical recess.

A recess in the slide element 178 is for example a passage opening.

When the recess in the slide element 178 is a passage opening, is the slide element 178 preferably a slide sleeve.

The enlarged representation in 47 also shows in dashed form an alternative embodiment of the cover element 202 , in which the recess in the slide element 178 is designed as a blind hole.

The cover element 202 preferably comprises a sealing surface 206 , which on an end face of a respective slide element 178 is arranged (cf. 40 and 47 ). The sealing surface 206 is in particular closed in a ring.

It can be beneficial if the sealing surface 206 of the cover element 202 in an annular closed sealing area on a functional element 136 can be applied.

Preferably by means of the cover element 202 a connection element 118 of a functional element 136 can be covered in a sealing manner, in particular in such a way that the connection element 118 of the functional element 136 when introducing a Plastic material into the injection cavity 180 of the shaping tool 160 is not brought into contact with the plastic material.

A connection element is preferred 118 of a functional element 136 by means of the cover element 202 thermally and / or mechanically protectable from damage.

• Vorzugsweise wird das Formgebungswerkzeug 162 zunächst geöffnet, insbesondere indem die erste Formhälfte 166 und die zweite Formhälfte 168 auseinandergefahren werden (vergl. 40).

Preferably with the in 39 Shaping tool shown 162 those in the 40 until 46 illustrated embodiment of the method for producing a hybrid component 132 can be carried out as follows:

• The shaping tool is preferably 162 initially opened, in particular by placing the first mold half 166 and the second mold half 168 be moved apart (cf. 40 ).

Then a functional element 136 preferably by means of a handling device 208 the shaping tool 162 fed and in particular in the shaping tool 162 brought in.

The functional element 136 is in particular an insert element. It can be beneficial if the functional element 136 a the 1 until 6th shown solar module 100 is.

The functional element 136 preferably comprises a connection element 118 , which of the functional element 136 protrudes away. The connection element 118 is for example an electrical connection element 122 .

The handling device 208 includes, for example, a gripper and / or an industrial robot.

The functional element 136 is by means of the handling device 208 preferably between the first mold half 166 and the second mold half 168 of the shaping tool 162 moved in ( 41 ).

The functional element is preferably 136 by means of the handling device 208 on several slide elements 178 the second half of the mold 168 positioned, in particular placed on this.

The functional element 136 is by means of the handling device 208 in particular is positioned such that the connection element 118 of the functional element 136 in the cover element 202 a slide element 178 the second half of the mold 168 is at least partially included.

The functional element is preferably 136 then to the mold wall 186 the first half of the mold 166 of the shaping tool 162 applied, in particular by means of the slide elements 178 the second half of the mold 168 (cf. 42 ).

The functional element 136 is preferably by means of the slide elements of the second mold half 168 in the forming tool 162 fixed.

It can be beneficial if the functional element 136 by means of the slide elements 178 aligned and / or relative to the forming tool 162 positioned, in particular centered.

In particular, a sealing surface is used 206 of the cover element 202 , which on an end face of a slide element 178 is arranged sealingly on the functional element 136 created.

In particular, the cover element 202 to cover the connection element 118 in a particularly encircling sealing area on the functional element 136 pressed on.

The functional element 136 is achieved in particular by moving the slide elements 178 on the mold wall 186 the first half of the mold 166 of the shaping tool 162 created, in particular by moving the slide elements 178 by means of the displacement device 194 .

Alternatively, it is conceivable that the first mold half 166 to the slide elements 178 and / or to that on the slide elements 178 positioned functional element 136 is shifted towards.

It can be beneficial if the slide elements 178 by moving the slide plate 196 be relocated.

The slide elements 178 are in particular displaced in a displacement direction which is parallel to a main demolding direction and / or parallel to an opening direction of the molding tool 162 is.

Preferably the handling device 208 then from the forming tool 162 moved out (cf. 43 ).

The slide elements 178 the second half of the mold 168 are preferably on one of the tool walls 186 the first half of the mold 166 of the shaping tool 162 facing away from the functional element 136 on the functional element 136 on.

An end face of the slide elements is preferably located here 178 on the functional element 136 on, in particular an end face at a free end of the slide elements 178 .

It can be beneficial if the slide elements 178 by means of a spring device 198 resilient on the functional element 136 issue.

The shaping tool 162 is preferably then closed, in particular by moving the first mold half together 166 and the second mold half 168 .

Preferably delimit the first mold half 166 , the second half of the mold 168 and the functional element 136 thereby an injection cavity 180 (cf. 44 ).

It can be beneficial if, if, then a base body 134 made of a plastic material in an injection molding process on the functional element 136 is injected.

The injection molding process is preferably in which the base body 134 to the functional element 136 is injected, an injection molding process and / or injection compression molding process.

The basic body 134 is particularly on the side of the functional element 136 to the functional element 136 molded onto which the connection element 118 of the functional element 136 is arranged.

One in 49 illustrated embodiment of a shaping tool 162 differs from the in 39 illustrated embodiment of a shaping tool essentially in that the shaping tool 162 a plunge edge tool 164 is.

Incidentally, the in 49 illustrated embodiment of a shaping tool 162 in terms of structure and function with the in 39 illustrated embodiment of a shaping tool 162 so that reference is made to their description above.

Special embodiments are the following:

Embodiment 1:

• - ein oder mehrere Solarzellenelemente (102), welche zwischen zwei Schutzlagen (104) aus einem Schutzmaterial (106) angeordnet sind;
• - eine Trägerlage (108) aus einem Trägermaterial (110);
• - eine Decklage (112) aus einem Deckmaterial (114);

wobei das eine oder die mehreren zwischen den zwei Schutzlagen (104) angeordneten Solarzellenelemente (102) gemeinsam mit den zwei Schutzlagen (104) zwischen der Trägerlage (108) und der Decklage (112) angeordnet sind.Solar module ( 100 ), which includes:

• - one or more solar cell elements ( 102 ), which is between two protective layers ( 104 ) made of a protective material ( 106 ) are arranged;
• - a carrier layer ( 108 ) from a carrier material ( 110 );
• - a top layer ( 112 ) from a cover material ( 114 );

with the one or more between the two protective layers ( 104 ) arranged solar cell elements ( 102 ) together with the two protective layers ( 104 ) between the carrier layer ( 108 ) and the top layer ( 112 ) are arranged.

Embodiment 2:

Solar module ( 100 ) according to embodiment 1, characterized in that the protective material ( 106 ) of the two protective layers ( 104 ) comprises or consists of a polymer material, for example ethylene vinyl acetate (EVA), polyvinyl butyral (PVB), polyamide (PA), polymethyl methacrylate (PMMA) and / or polyurethane (PUR), and / or that the protective layers ( 104 ) Foils are.

Embodiment 3:

Solar module ( 100 ) according to embodiment 1 or 2, characterized in that the cover material ( 114 ) of the top layer ( 112 ) and / or the carrier material ( 110 ) the carrier layer ( 108 ) comprise or consist of a polymer material, for example polymethyl methacrylate (PMMA), polypropylene (PP), polycarbonate (PC) and / or ethylene-tetrafluoroethylene (ETFE), and / or that the cover layer ( 112 ) and / or the carrier layer ( 108 ) Foils are.

Embodiment 4:

Solar module ( 100 ) according to one of the embodiments 1 to 3, characterized in that the one or more solar cell elements ( 102 ) into the protective material ( 106 ) of the two protective layers ( 104 ) are welded in.

Embodiment 5:

Solar module ( 100 ) according to embodiment 4, characterized in that the two protective layers ( 104 ), in which the one or more solar cell elements ( 102 ) are welded between the carrier material ( 110 ) the carrier layer ( 108 ) and the cover material ( 114 ) of the top layer ( 112 ) are welded in.

Embodiment 6:

Solar module ( 100 ) according to one of the embodiments 1 to 5, characterized in that the solar module ( 100 ) a sandwich component ( 116 ) is.

Embodiment 7:

Solar module ( 100 ) according to one of the embodiments 1 to 6, characterized in that the solar module ( 100 ) also one or more connection elements ( 118 ), in particular one or more mechanical connection elements ( 120 ) and / or one or more electrical connection elements ( 122 ) includes.

Embodiment 8:

Hybrid component ( 132 ), which has a basic body ( 134 ) made of a plastic material and a solar module ( 100 ) according to one of the embodiments 1 to 7, wherein the base body ( 134 ) cohesively with the solar module ( 100 ) connected, in particular glued, is.

Embodiment 9:

Hybrid component ( 132 ) according to embodiment 8, characterized in that the hybrid component ( 132 ) on one of the base bodies ( 134 ) facing away from the solar module ( 100 ) a coating ( 158 ) from a coating material ( 160 ), which on the solar module ( 100 ) and / or on a front ( 146 ) of the main body ( 134 ) is applied.

Embodiment 10:

Hybrid component ( 132 ), which has a basic body ( 134 ) made of a plastic material and a solar module ( 100 ) according to one of the embodiments 1 to 7, wherein the base body ( 134 ) to the solar module ( 100 ) is molded on.

Embodiment 11:

Hybrid component ( 132 ) according to embodiment 10, characterized in that the hybrid component ( 132 ) on one of the base bodies ( 134 ) facing away from the solar module ( 100 ) a coating ( 158 ) from a coating material ( 160 ), which on the solar module ( 100 ) and / or on a front ( 146 ) of the main body ( 134 ) is applied.

Embodiment 12:

• - Herstellen eines Grundkörpers (134) aus einem Kunststoffmaterial in einem Spritzprozess in einem Formgebungswerkzeug (162) ;
• - Bereitstellen eines Funktionselements (136), insbesondere eines Solarmoduls (100) nach einer der Ausführungsformen 1 bis 7;
• - stoffschlüssiges Verbinden des Funktionselements (136) mit dem Grundkörper (134), insbesondere mittels eines Klebermaterials (138).

Process for the production of a hybrid component ( 132 ), especially a hybrid component ( 132 ) according to embodiment 8 or 9, wherein the hybrid component ( 132 ) a basic body ( 134 ) and a functional element ( 136 ), especially a solar module ( 100 ) according to any one of embodiments 1 to 7, wherein the method comprises:

• - Manufacture of a basic body ( 134 ) from a plastic material in an injection molding process in a molding tool ( 162 );
• - Provision of a functional element ( 136 ), especially a solar module ( 100 ) according to one of the embodiments 1 to 7;
• - material connection of the functional element ( 136 ) with the main body ( 134 ), in particular by means of an adhesive material ( 138 ).

Embodiment 13:

Method according to embodiment 12, characterized in that the functional element ( 136 ) and the main body ( 134 ) are pressed against each other to materially connect the same, in particular by moving two mold halves together ( 166 , 168 ) of the shaping tool ( 162 ) or by adding the functional element ( 136 ) by means of a handling device ( 208 ) against the main body ( 134 ) is pressed.

Embodiment 14:

Method according to embodiment 12 or 13, characterized in that before the material connection of the functional element ( 136 ) with the main body ( 134 ) an adhesive material ( 138 ) on the base body ( 134 ) and / or on the functional element ( 136 ) is applied.

Embodiment 15:

Method according to one of the embodiments 12 to 14, characterized in that the base body ( 134 ) during the material connection of the same with the functional element ( 136 ) in the forming tool ( 162 ) remains form-bound, by means of which the base body ( 134 ) will be produced.

Embodiment 16:

Method according to one of the embodiments 12 to 15, characterized in that the functional element ( 136 ) before the material connection with the base body ( 134 ) of the hybrid component ( 132 ) is heated.

Embodiment 17:

Method according to one of the embodiments 12 to 16, characterized in that after the material connection of the functional element ( 136 ) with the main body ( 134 ) a coating ( 158 ) from a coating material ( 160 ) on the functional element ( 136 ) and / or on the base body ( 134 ) is applied, whereby the coating ( 158 ) the functional element ( 136 ) of the hybrid component ( 132 ) completely covers and / or with the coating ( 158 ) the main body ( 134 ) of the hybrid component ( 132 ) on a front ( 146 ) covers the same at least partially, preferably essentially completely.

Embodiment 18:

Method according to embodiment 17, characterized in that the coating ( 158 ) in the same forming tool ( 162 ) on the functional element ( 136 ) and / or on the base body ( 134 ) is applied, by means of which the base body ( 134 ) will be produced.

Embodiment 19:

Method according to one of the embodiments 12 to 18, characterized in that when producing the base body ( 134 ) one or more passage openings ( 182 ) in the main body ( 134 ) getting produced.

Embodiment 20:

• - Bereitstellen eines Formgebungswerkzeugs (162);
• - Bereitstellen eines Solarmoduls (100) nach einer der Ausführungsformen 1 bis 7;
• - Einbringen des Solarmoduls (100) in das Formgebungswerkzeug (162) ;
• - Anspritzen eines Grundkörpers (134) aus einem Kunststoffmaterial an das Solarmodul (100) in einem Spritzprozess.

Process for the production of a hybrid component ( 132 ), especially a hybrid component ( 132 ) according to embodiment 10 or 11, wherein the hybrid component ( 132 ) a basic body ( 134 ) and a solar module ( 100 ) according to any one of embodiments 1 to 7, wherein the method comprises:

• - Providing a shaping tool ( 162 );
• - Provision of a solar module ( 100 ) according to one of the embodiments 1 to 7;
• - Insertion of the solar module ( 100 ) into the forming tool ( 162 );
• - Injection of a base body ( 134 ) made of a plastic material to the solar module ( 100 ) in one injection process.

Embodiment 21:

Method according to embodiment 20, characterized in that the base body ( 134 ) in a two-component spray process to the solar module ( 100 ) is injected, whereby the base body ( 134 ) a translucent, in particular transparent or translucent, base body part ( 188 ) made of a translucent, in particular transparent or translucent, plastic material as well as a non-transparent main body part ( 190 ) made of a non-transparent plastic material.

Embodiment 22:

Method according to embodiment 20 or 21, characterized in that after the injection-molding of the base body ( 134 ) to the solar module ( 100 ) a coating ( 158 ) from a coating material ( 160 ) onto the solar module ( 100 ) and / or on the base body ( 134 ) is applied, whereby the coating ( 158 ) the solar module ( 100 ) of the hybrid component ( 132 ) completely covers and / or with the coating ( 158 ) the main body ( 134 ) of the hybrid component ( 132 ) on a front ( 146 ) covers the same at least partially, preferably essentially completely.

Embodiment 23:

Method according to embodiment 22, characterized in that the coating ( 158 ) in the same forming tool ( 162 ) onto the solar module ( 100 ) and / or on the base body ( 134 ) is applied, in which the base body ( 134 ) to the solar module ( 100 ) is injected.

Embodiment 24:

Method according to one of the embodiments 20 to 23, characterized in that the base body ( 134 ) by spraying it onto the solar module ( 100 ) is positively connected to this.

Embodiment 25:

Method according to one of the embodiments 20 to 24, characterized in that the carrier material ( 110 ) the carrier layer ( 108 ) and / or the cover material ( 114 ) the top layer ( 112 ) of the solar module ( 100 ) Comprise or consist of polypropylene (PP), the plastic material of the base body ( 134 ) Comprises or consists of polypropylene (PP); or that the carrier material ( 110 ) the carrier layer ( 108 ) and / or the cover material ( 114 ) of the top layer ( 112 ) of the solar module ( 100 ) Comprise or consist of polycarbonate (PC), the plastic material of the base body ( 134 ) comprises or consists of a blend of polycarbonate (PC) and acrylonitrile-butadiene-styrene (ABS); or that the carrier material ( 110 ) the carrier layer ( 108 ) and / or the cover material ( 114 ) of the top layer ( 112 ) of the solar module ( 100 ) Comprise or consist of ethylene tetrafluoroethylene (ETFE), the plastic material of the base body ( 134 ) comprises or consists of a blend of polycarbonate (PC) and acrylonitrile-butadiene-styrene (ABS); or
that the carrier material ( 110 ) the carrier layer ( 108 ) and / or the cover material ( 114 ) of the top layer ( 112 ) of the solar module ( 100 ) Comprise or consist of ethylene tetrafluoroethylene (ETFE), the base body ( 134 ) is produced in a two-component injection molding process, with a translucent, in particular transparent or translucent, base body part ( 188 ) is made of a translucent, in particular transparent or translucent, plastic material which comprises or consists of polycarbonate (PC), and wherein a non-transparent base body part ( 190 ) is made from a non-transparent plastic material which comprises or consists of a blend of polycarbonate (PC) and acrylonitrile-butadiene-styrene (ABS); or
that the carrier material ( 110 ) the carrier layer ( 108 ) and / or the cover material ( 114 ) of the top layer ( 112 ) of the solar module ( 100 ) Comprise or consist of polycarbonate (PC), the base body ( 134 ) is produced in a two-component injection molding process, with a translucent, in particular transparent or translucent, base body part ( 188 ) is made of a translucent, in particular transparent or translucent, plastic material which comprises or consists of polycarbonate (PC), and wherein a non-transparent base body part ( 190 ) is made from a non-transparent plastic material which comprises or consists of a blend of polycarbonate (PC) and acrylonitrile-butadiene-styrene (ABS).

Embodiment 26:

• - Bereitstellen eines Formgebungswerkzeugs (162);
• - Bereitstellen eines Funktionselements (136), welches ein oder mehrere Anschlusselemente (118) umfasst;
• - Anlegen des Funktionselements (136) an eine Werkzeugwandung (186) einer ersten Formhälfte (166) des Formgebungswerkzeugs (162) und an ein oder mehrere Schieberelemente (178) einer zweiten Formhälfte (168) des Formgebungswerkzeugs (162);
• - Anspritzen eines Grundkörpers (134) aus einem Kunststoffmaterial an das Funktionselement (136) in einem Spritzprozess.

Process for the production of a hybrid component ( 132 ), which has a basic body ( 134 ) and a functional element ( 136 ), the method comprising:

• - Providing a shaping tool ( 162 );
• - Provision of a functional element ( 136 ), which has one or more connection elements ( 118 ) includes;
• - Creation of the functional element ( 136 ) to a mold wall ( 186 ) a first mold half ( 166 ) of the shaping tool ( 162 ) and to one or more slide elements ( 178 ) a second mold half ( 168 ) of the shaping tool ( 162 );
• - Injection of a base body ( 134 ) made of a plastic material to the functional element ( 136 ) in one injection process.

Embodiment 27:

Method according to embodiment 26, characterized in that the functional element ( 136 ) by moving one or more slide elements ( 178 ) to the mold wall ( 186 ) of the first half of the mold ( 166 ) of the shaping tool ( 162 ) is created.

Embodiment 28:

Method according to embodiment 27, characterized in that the one or more slide elements ( 178 ) by means of a relocation device ( 194 ) be relocated.

Embodiment 29:

Method according to one of the embodiments 26 to 28, characterized in that the one or more slide elements ( 178 ) resilient to the functional element ( 136 ), in particular by means of a spring device ( 198 ).

Embodiment 30:

Method according to embodiment 29, characterized in that a spring force of the spring device ( 198 ) is set and / or regulated.

Embodiment 31:

Method according to one of the embodiments 26 to 30, characterized in that one or more slide elements ( 178 ) one cover element each ( 202 ) comprise or form, wherein the one or more connecting elements ( 118 ) of the functional element ( 136 ) by means of a cover element ( 118 ) are covered.

Embodiment 32:

Method according to embodiment 31, characterized in that the cover element ( 202 ) to cover the one or more connection elements ( 118 ) in a particularly circumferential sealing area on the functional element ( 136 ) is applied, in particular sealing.

Embodiment 33:

Method according to one of the embodiments 26 to 32, characterized in that the functional element ( 136 ) the shaping tool ( 162 ) by means of a handling device ( 208 ) is supplied.

Embodiment 34:

Method according to one of the embodiments 26 to 33, characterized in that the functional element ( 136 ) by means of the one or more slide elements ( 178 ) aligned and / or relative to the shaping tool ( 162 ) is positioned.

Embodiment 35:

• - eine erste Formhälfte (166);
• - eine zweite Formhälfte (168);

wobei die zweite Formhälfte (168) ein oder mehrere Schieberelemente (178) umfasst, mittels welcher ein Funktionselement (136) an eine Werkzeugwandung (186) der ersten Formhälfte (166) anlegbar ist.Shaping tool ( 162 ), in particular for carrying out the method according to one of the embodiments 26 to 34, wherein the shaping tool ( 162 ) Includes:

• - a first mold half ( 166 );
• - a second half of the mold ( 168 );

where the second half of the mold ( 168 ) one or more slide elements ( 178 ), by means of which a functional element ( 136 ) to a mold wall ( 186 ) of the first half of the mold ( 166 ) can be applied.

Embodiment 36:

Shaping tool ( 162 ) according to embodiment 35, characterized in that the shaping tool ( 162 ) also a relocation facility ( 194 ), by means of which one or more slide elements ( 178 ) relative to the second mold half ( 168 ) are relocatable.

Embodiment 37:

Shaping tool ( 162 ) according to embodiment 35 or 36, characterized in that the one or more slide elements ( 178 ), which are attached to the functional element ( 136 ) can be applied, each by means of a spring device ( 198 ) resilient on the second half of the mold ( 168 ) of the shaping tool ( 162 ) are arranged.

Embodiment 38:

Shaping tool ( 162 ) according to embodiment 37, characterized in that a spring force of the spring device ( 198 ) is adjustable and / or controllable.

Embodiment 39:

Shaping tool ( 162 ) according to one of the embodiments 35 to 38, characterized in that one or more slide elements ( 178 ) a cover element ( 202 ) to cover one or more connection elements ( 118 ) of the functional element ( 116 ) include.

Embodiment 40:

Shaping tool ( 162 ) according to embodiment 39, characterized in that the cover element ( 202 ) a sealing surface ( 206 ), which on an end face of a respective slide element ( 178 ) is arranged.

Embodiment 41:

Use of a shaping tool ( 162 ) according to one of the embodiments 35 to 39 for the production of a hybrid component ( 132 ), which has a basic body ( 134 ) and a functional element ( 136 ), in particular for performing the method according to one of claims 26 to 34.

Claims (15)

A solar module (100) comprising: - One or more solar cell elements (102) which are arranged between two protective layers (104) made of a protective material (106); - A carrier layer (108) made of a carrier material (110); - A cover layer (112) made of a cover material (114); wherein the one or more solar cell elements (102) arranged between the two protective layers (104) are arranged together with the two protective layers (104) between the carrier layer (108) and the cover layer (112). Solar module (100) Claim 1 , characterized in that the protective material (106) of the two protective layers (104) comprises or consists of a polymer material, for example ethylene vinyl acetate (EVA), polyvinyl butyral (PVB), polyamide (PA), polymethyl methacrylate (PMMA) and / or polyurethane (PUR), and / or that the protective layers (104) are foils. Solar module (100) Claim 1 or 2 , characterized in that the cover material (114) of the cover layer (112) and / or the carrier material (110) of the carrier layer (108) comprise or consist of a polymer material, for example polymethyl methacrylate (PMMA), polypropylene (PP), polycarbonate (PC ) and / or ethylene-tetrafluoroethylene (ETFE), and / or that the cover layer (112) and / or the carrier layer (108) are films. Solar module (100) according to one of the Claims 1 until 3 , characterized in that the one or more solar cell elements (102) are welded into the protective material (106) of the two protective layers (104). Solar module (100) Claim 4 , characterized in that the two protective layers (104) into which the one or more solar cell elements (102) are welded are welded between the carrier material (110) of the carrier layer (108) and the cover material (114) of the cover layer (112) . Solar module (100) according to one of the Claims 1 until 5 , characterized in that the solar module (100) is a sandwich component (116). Solar module (100) according to one of the Claims 1 until 6th , characterized in that the solar module (100) further comprises one or more connection elements (118), in particular one or more mechanical connection elements (120) and / or one or more electrical connection elements (122). Hybrid component (132), which has a base body (134) made of a plastic material and a solar module (100) according to one of the Claims 1 until 7th comprises, wherein the base body (134) is injection-molded onto the solar module (100). Hybrid component (132) according to Claim 8 , characterized in that the hybrid component (132) on a side of the solar module (100) facing away from the base body (134) comprises a coating (158) made of a coating material (160) which is applied to the solar module (100) and / or to a front side (146) of the base body (134) is applied. Method for producing a hybrid component (132), in particular a hybrid component (132) according to Claim 8 or 9 , wherein the hybrid component (132) has a base body (134) and a solar module (100) according to one of the Claims 1 until 7th the method comprising: - providing a forming tool (162); - Providing a solar module (100) according to one of the Claims 1 until 7th ; - Introducing the solar module (100) into the shaping tool (162); - Injection molding of a base body (134) made of a plastic material onto the solar module (100) in an injection molding process. Procedure according to Claim 10 , characterized in that the base body (134) is injected onto the solar module (100) in a two-component injection molding process, the base body (134) having a light-permeable, in particular transparent or translucent, base body part (188) made of a light-permeable, in particular transparent or translucent, plastic material as well as a non-transparent base body part (190) made of a non-transparent plastic material. Procedure according to Claim 10 or 11 , characterized in that after the base body (134) has been molded onto the solar module (100), a coating (158) made of a coating material (160) is applied to the solar module (100) and / or to the base body (134), the Coating (158) completely covers the solar module (100) of the hybrid component (132) and / or wherein the coating (158) at least partially, preferably essentially completely, the base body (134) of the hybrid component (132) on a front side (146) thereof, covers. Procedure according to Claim 12 , characterized in that the coating (158) is applied to the solar module (100) and / or to the base body (134) in the same shaping tool (162) in which the base body (134) is injected onto the solar module (100). Method according to one of the Claims 10 until 13th , characterized in that the base body (134) is positively connected to the solar module (100) by molding it onto the latter. Method according to one of the Claims 10 until 14th , characterized in that the carrier material (110) of the carrier layer (108) and / or the cover material (114) of the cover layer (112) of the solar module (100) comprise or consist of polypropylene (PP), the plastic material of the base body (134) Comprises or consists of polypropylene (PP); or that the carrier material (110) of the carrier layer (108) and / or the cover material (114) of the cover layer (112) of the solar module (100) comprise or consist of polycarbonate (PC), the plastic material of the base body (134) being a blend Comprises or consists of polycarbonate (PC) and acrylonitrile butadiene styrene (ABS); or that the carrier material (110) of the carrier layer (108) and / or the cover material (114) of the cover layer (112) of the solar module (100) comprise or consist of ethylene tetrafluoroethylene (ETFE), the plastic material of the base body (134) being a Comprises or consists of a blend of polycarbonate (PC) and acrylonitrile-butadiene-styrene (ABS); or that the carrier material (110) of the carrier layer (108) and / or the cover material (114) of the cover layer (112) of the solar module (100) comprise or consist of ethylene-tetrafluoroethylene (ETFE), the base body (134) in a two -Component injection molding process is produced, with a light-permeable, in particular transparent or translucent, base body part (188) made of a light-permeable, in particular transparent or translucent, Plastic material is produced which comprises or consists of polycarbonate (PC), and wherein a non-transparent base body part (190) is produced from a non-transparent plastic material which comprises or consists of a blend of polycarbonate (PC) and acrylonitrile-butadiene-styrene (ABS) ; or that the carrier material (110) of the carrier layer (108) and / or the cover material (114) of the cover layer (112) of the solar module (100) comprise or consist of polycarbonate (PC), the base body (134) in a two-component -Injection process is produced, wherein a light-permeable, in particular transparent or translucent, base body part (188) is produced from a light-permeable, in particular transparent or translucent, plastic material which comprises or consists of polycarbonate (PC), and a non-transparent base body part (190) a non-transparent plastic material is produced, which comprises or consists of a blend of polycarbonate (PC) and acrylonitrile-butadiene-styrene (ABS).

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