阅读说明：本技术 一种用于制造光伏模块的方法 (Method for manufacturing photovoltaic module ) 是由 M·鲍德里特 于 2020-03-13 设计创作，主要内容包括：本发明涉及一种光伏模块的制造方法。模块(1)至少包括前层、后层和封装在前层与后层之间的太阳能电池装置(100)。太阳能电池装置包括连接到聚合物箔(110)的多个光伏电池和电池之间的电连接。在一些实施例中,光伏电池是晶体硅光伏电池。该方法包括提供太阳能电池装置然后将前层和/或后层的至少一部分注射成型到太阳能电池装置上的步骤。(The present invention relates to a method of manufacturing a photovoltaic module. The module (1) comprises at least a front layer, a rear layer and a solar cell arrangement (100) encapsulated between the front layer and the rear layer. The solar cell arrangement comprises a plurality of photovoltaic cells connected to a polymer foil (110) and electrical connections between the cells. In some embodiments, the photovoltaic cell is a crystalline silicon photovoltaic cell. The method comprises the steps of providing a solar cell device and then injection molding at least a portion of the front layer and/or the back layer onto the solar cell device.)

1. A method for manufacturing a photovoltaic module (1), the module (1) comprising at least one front layer and at least one rear layer and a solar cell arrangement (100) encapsulated between the front layer and the rear layer, the solar cell arrangement (100) comprising a plurality of photovoltaic cells (10) and electrical connections (11) connecting the cells;

-the method comprises at least the following steps:

-providing a solar cell arrangement (100);

-providing a polymer foil (110);

-arranging a solar cell device (100) on a polymer foil (110);

-bonding together the polymer foil (110) and the solar cell device (100); and

-providing a molding layer (120) by injection molding at least a part of the front layer and/or at least a part of the back layer onto the solar cell device (100);

wherein the foil (110) and the solar cell device (100) are bonded together before injection molding the molding layer (120); and

wherein the injection molding step is performed directly on the at least one photovoltaic cell (10) and on the polymer foil (110).

2. The method of claim 1, wherein the photovoltaic cells included in the solar cell device (100) are rigid, wafer-based silicon photovoltaic cells (10).

3. The method according to any of the preceding claims, wherein the polymer foil (110) and the solar cell device (100) are joined together by heating or by a lamination process, wherein the heating or lamination process excludes the use of rigid plates.

4. The method according to any of the preceding claims, wherein the molding layer (120) is injection molded onto a side of the solar cell device (100) opposite the polymer foil (110).

5. The method according to any of the preceding claims, further comprising the step of:

-encapsulating the solar cell device (100) at least partially or completely in an encapsulation film, gel and/or liquid (130), wherein the front layer and/or the back layer is injection molded directly onto the encapsulated solar cell device (100).

6. The method of any preceding claim, wherein the injection molding step comprises:

-a first injection molding step, wherein a first molding layer (120) is injection molded onto the solar cell device (10);

-a second injection molding step, wherein a second molding layer (140) is injection molded onto the solar cell device (10);

preferably, wherein at least the first injection molding step is performed directly on the photovoltaic cell (10).

7. The method of claim 6, wherein the first injection molding step is performed at a lower pressure than the second injection molding step.

8. The method according to one of claims 6 and 7, wherein the first polymer composition is injected in a first injection molding step and the second polymer composition is injected in a second injection molding step.

9. The method according to one of claims 6 to 8,

wherein the first injection molding step is performed in a mold comprising at least a first mold part (250) and a second mold part (260);

wherein the solar cell device (100) is arranged on a first mould part (250);

wherein a first cavity (291) is formed between the solar cell device (100) and the second mould part (260), the cavity (291) being configured to receive material injected into the mould during the first injection moulding step.

10. The method of claim 9, wherein the first and second light sources are selected from the group consisting of,

wherein the mould comprises a third mould part (270);

wherein a second cavity (292) is formed between the solar cell device (100) and the first molding layer (120) and the third mold portion (270), the second cavity (292) being configured to receive material injected into the mold during the second injection molding step.

11. The method of any one of the preceding claims, wherein

-one or more mounting brackets (190); and/or

-one or more mounting holes (191); and/or

-a support structure; and/or

-a protective frame (195); and/or

-a junction box (197) for connecting a plurality of cells (10) or a plurality of cell strings of a solar cell arrangement (100);

is injection molded to the photovoltaic module (1), wherein the mounting brackets (190), the mounting holes (191), the support structure, the protective frame (195) and/or the junction box (197) are integrally molded with the front layer and/or with the rear layer, preferably at the time of injection molding the layers.

12. The method of claim 11, wherein the support structure comprises a plurality of ribs (180), preferably wherein the ribs (180) intersect one another, more preferably wherein the support structure is a honeycomb structure;

preferably, wherein the back layer comprises a first major surface facing the front layer and a second major surface opposite to said first major surface, wherein the support structure is arranged on the second major surface.

13. The method according to any one of the preceding claims,

wherein each cell (10a, 10b) of the solar cell arrangement (100) extends in a respective reference plane (A, B);

wherein at least some of the reference planes (A, B) of adjacent cells (10a, 10b) intersect at an angle (α), preferably an angle (α) greater than 2 °, more preferably an angle (α) greater than 4 ° or greater than 5 °; and/or

Wherein the reference planes (A, B) of adjacent cells (10a, 10B) are parallel but offset from each other in a direction perpendicular to the reference planes (A, B).

14. A photovoltaic module (1) comprising,

a solar cell arrangement (100), the solar cell arrangement (100) comprising a plurality of photovoltaic cells (10);

a polymer foil (110) to which the solar cell device (100) is bonded (110);

a front layer; and

a rear layer;

wherein the solar cell device (100) is encapsulated between a front layer and a back layer, and at least a part of the front layer and/or at least a part of the back layer is formed by injection molding.

15. The photovoltaic module (1) according to claim 14, wherein the photovoltaic cells comprised in the solar cell arrangement (100) are rigid, wafer-based silicon photovoltaic cells (10).

16. Photovoltaic module (1) according to one of claims 14 and 15, wherein the solar cell arrangement (100) is at least partially or completely encapsulated in an encapsulating film, gel and/or liquid (130).

17. Photovoltaic module (1) according to one of claims 14 to 16, wherein the front layer or the back layer comprises a first molding layer (120) formed by injection molding and a second molding layer (140) formed by injection molding.

18. The photovoltaic module (1) according to any of claims 14 to 17, wherein the solar cell arrangement (100) does not comprise a rigid plate having a higher rigidity than each of the front layer and the back layer.

19. The photovoltaic module (1) according to any of claims 14 to 18, wherein the back layer comprises a support structure,

preferably wherein the support structure comprises a plurality of ribs (180), more preferably wherein the ribs (180) intersect each other, even more preferably wherein the support structure is a honeycomb structure.

Background

In recent years, global trends continue to support the utilization of renewable energy technologies. In view of their versatility and modular nature, solar panels have become a key technology to provide renewable energy for general consumption. As a result, solar modules continue to become more prevalent and available to consumers, enabling them to produce their own electricity.

Therefore, there is a need to provide new and innovative ways to incorporate solar cells into the infrastructure of everyday life. One emerging aspect of this challenge is to provide solar panels within buildings or vehicles to meet some of their power requirements.

However, current solar cell placement technology limits the types of solar cells that can be used and how they can be attached or integrated into vehicles and other structures.

Generally, in the field of solar cells, solar panels are made by lamination. This process greatly limits the types of geometries in which planar or nearly planar solar panels can be implemented.

WO 2019/020718 a1 describes a vehicle body component having at least one solar cell which is arranged therein for the purpose of generating electrical energy.

US 2011/0100438 a1 describes a photovoltaic device comprising a photovoltaic cell assembly having an injection molded portion connected to at least one edge of the photovoltaic cell assembly for mounting outside a building.

EP 1245418 a2 discloses a solar panel for incorporation into a vehicle frame. The solar cells are embedded within the foam deposition cover.

US 5743970B 1 describes a photovoltaic module comprising at least one photovoltaic cell encapsulated in a non-reactive injection molded polymer material.

US 2009/0084432 a1 discloses an injection molded plastic housing for accommodating electrical and/or electronic built-in components such as thin film solar cells.

CN 206367145U, CN 205167427U and CN 102412328 a further disclose solar cell modules and injection molding techniques.

However, further improvements are still needed to efficiently manufacture solar modules.

It is therefore an object of the present invention to provide an improved method of manufacturing and forming photovoltaic modules that allows for more complex module geometries. Another object is to provide a method that allows efficient manufacturing of photovoltaic modules for integration into various structures.

Disclosure of Invention

At least some of these objects are achieved by the features of the independent claims. The dependent claims relate to preferred embodiments.

As found by the present inventors, the integration of solar cells into various articles and/or structures can be achieved in an advantageous manner by methods involving injection molding.

According to a first aspect, the invention relates to a method for manufacturing a photovoltaic module. The module includes a solar cell arrangement including a plurality of photovoltaic cells and electrical connections between the cells. The method comprises the steps of providing a solar cell device and then injection molding a layer onto the solar cell device. The injection molded layer may be at least a portion of a front layer and/or at least a portion of a back layer of the photovoltaic module.

The solar cell device may be at least partially or completely encapsulated by the injection molding material, for example between a front layer and a back layer. Such encapsulation may also refer to at least partially or completely encapsulating the solar cell device in an injection molding material, for example between a front layer and a back layer.

One or more intermediate layers may be present between the solar cell device and the injection molding material. However, the material may also be directly moulded (moulded) onto a part of the device without the need to provide such an intermediate layer.

The term "upper" should not be construed as limiting the direction in which the injection molding material is injected onto the solar cell device. Those skilled in the art will appreciate that the injection molding material may be supplied into the mold and/or onto the solar cell device from above, below, and/or from the side, depending on the design of the mold and/or injection molding machine.

The photovoltaic cell may be an individual photovoltaic cell and the solar cell apparatus may optionally further comprise a carrier mechanically engaging and/or mechanically connecting and/or supporting the individual photovoltaic cell. Such a carrier may help to hold the individual photovoltaic solar cells together and to maintain the electrical connection by reducing mechanical stress. The carrier may be made of a flexible material without the rigid limitation of the photovoltaic cell in a particular configuration. The carrier may be made of a material comprising glass fibre, carbon fibre, Kevlar and/or a polymer.

In the context of the present invention, a photovoltaic cell may also be referred to as a solar cell. The solar cells may be provided as one or more strings. The electrical connection may be provided by one or more conductive strips and/or one or more braze joints between two adjacent photovoltaic cells, preferably between every two adjacent photovoltaic cells of the respective string.

The electrical connection between two (or more) solar cells (e.g., between two adjacent cells of a string) may include a release ring. Such a release ring may help accommodate thermal expansion of materials surrounding the photovoltaic cell, which may be particularly important when employing polymeric materials. The release ring may be part of an electrical connection configured to at least partially straighten when the solar cell device expands. The release ring may be formed, for example, by providing an electrical connection having a looped portion and/or a wave shape. In particular, the electrical connection may be formed by one or more loops and/or waves extending in a direction perpendicular to the longitudinal direction in which the connection extends. For example, the electrical connection may have a sinusoidal waveform. Alternatively or additionally, two portions of the electrical connection (e.g., two straight portions) may be connected by a wavy link. The release ring may be completely encapsulated in and/or surrounded by the polymeric material.

Any type of solar cell may be used, including single to multijunction solar cells, and even single crystal solar cells. For example, crystalline silicon or III-V compound photovoltaic cells may be used. The photovoltaic cell may be rigid. Photovoltaic cells can be manufactured on the basis of semiconductor wafers, in particular silicon wafers.

The photovoltaic cells can be of any size. The battery may have dimensions of at least 10mm x 10mm, preferably at least 20mm x 20mm, more preferably at least 100mm x 100mm (whether the battery is square, rectangular or has any other shape).

Preferably, the photovoltaic cell has a width dimension, a length dimension perpendicular to the width dimension, and a thickness dimension perpendicular to both the length dimension and the thickness dimension. The thickness may be less than the width dimension and/or the length dimension, preferably by at least 5, 10, 50 or 1000 times. For example, the thickness may be 30 μm to 1mm, preferably 100 μm to 500 μm. Therefore, the battery can be thin.

Preferably, the width and/or length dimension is at least 10mm, preferably at least 20mm, more preferably at least 100 mm. For example, the cell may be rectangular, at least 10mm, at least 20mm, or at least 100mm in length, while the width may be larger or smaller.

The photovoltaic cell may optionally be a full-scale solar cell having a width dimension of 156mm and a length dimension of 156 mm. The battery may also be larger.

Optionally, the front layer and/or the back layer may form an exposed outer surface of the photovoltaic module.

The pre-mold layer and/or post-mold layer can have at least 100cm²Preferably at least 1000cm²At least 2000cm²Or at least 5000cm²Of (2) is provided.

Injection molding onto solar cells or solar cell devices provides many benefits because it allows the creation of more complex geometries of photovoltaic modules, and the modules can be manufactured continuously with high fidelity.

Suitable injection molding materials may include thermoplastic materials, thermoset materials, and elastomers. Materials such as polypropylene (PP), Polycarbonate (PC), Polyethylene (PE), Polytetrafluoroethylene (PTFE), Polyoxymethylene (POM), Acrylonitrile Butadiene Styrene (ABS), Polyaryletherketone (PAEK), Polyetheretherketone (PEEK), polypropylene and ethylene copolymers, epoxy, phenolic, nylon, Polystyrene (PS) and/or silicone (or any combination thereof) may be used for the injection molded layer.

According to the present disclosure, the method may comprise the step of providing the solar cell device with a substrate and/or superstrate before performing the injection molding step. The substrate may be a polymer foil and/or the superstrate may be a polymer foil. For example, the polymer foil may have a thickness of 500 μm to 2500 μm. The substrate may abut and/or cover a portion or all of the first surface of each photovoltaic cell in the solar cell device. Similarly, the superstrate can abut and/or cover a portion or all of a second surface of each photovoltaic cell in the solar cell device, the second surface being opposite the first surface. The polymer foil forming the base plate and the polymer foil forming the cover plate may have different thicknesses. The thicknesses may differ by more than 200% or even more than 500%. The polymer foil forming the base plate and the polymer foil forming the cover plate may have different rigidities. The stiffness may differ by more than 200% or from so much as to exceed 500%. The rigidity of one of the foils, or preferably both foils, may be significantly less than the rigidity of the photovoltaic cell. Thus, in contrast to photovoltaic cells, the foil may be substantially bendable, i.e. may be reversibly bendable with a bending radius of less than 100mm or even less than 10 mm. The polymer foil may be made of various polymer materials such as Polycarbonate (PC), polyethylene terephthalate (PET), Polyamide (PA) or mixtures thereof.

The injection molding material may then be deposited directly on the photovoltaic cell and/or on the material used as the substrate or superstrate. The substrate and/or superstrate (e.g., one or more polymer foils) may provide additional protective layers for the photovoltaic cell and/or may hold the photovoltaic cell in place during the injection molding process. In particular, the substrate and/or superstrate may prevent the enclosed photovoltaic cell from being damaged, e.g., cracked, during the injection molding process. Furthermore, the substrate and/or superstrate may interconnect and/or stabilize photovoltaic cells included in the solar cell device. The injection molded layer may be thicker and/or harder than the substrate and/or superstrate.

The molding layer is preferably a front layer or a back layer of the photovoltaic module. Alternatively, only the front layer or only the rear layer may be injection molded in this case. The substrate or superstrate of the solar cell device can form an exposed outer surface.

Optionally, a molding layer is injection molded to the side of the solar cell device opposite the substrate or superstrate (e.g., opposite the polymer foil used as the substrate or superstrate). In such a configuration, the injection molded layer may provide the structure and shape of the photovoltaic module, while the substrate or superstrate (e.g., a polymer foil) of the solar cell device may provide some protection on the opposite side, e.g., from fluid ingress.

Preferably, the method may further comprise the step of bonding together the substrate or superstrate (e.g. foil) with the photovoltaic cell (e.g. with the string (s)) and/or the solar cell device prior to injection moulding the layer. Such bonding may optionally be performed by heating, which in some cases may partially melt the polymer foil and allow it to adhere to the photovoltaic cell. In the context of the present invention, a solar cell arrangement with such a superstrate and/or substrate may also be referred to as a "solar cell module".

Further, in the case where both the substrate formed of the first polymer foil and the superstrate formed of the second polymer foil are provided, the two polymer foils can be bonded not only to the photovoltaic cell but also to each other. Thus, the two polymer foils can tightly enclose or encapsulate the photovoltaic cell from opposite sides.

Alternatively, the polymer foil and the photovoltaic cell string (and/or the solar cell device) may be joined together by a lamination process to form the solar cell device. The lamination process will preferably exclude the use of rigid plates, such as polycarbonate and/or glass plates, which are conventionally used in solar cell arrangement lamination processes. The stiffness of such rigid plates is typically higher than the stiffness of the polymer foil and typically also higher than the stiffness of the front and/or back layer formed by injection molding and/or higher than the stiffness of the photovoltaic cell. The lamination of individual solar cells on a rigid plate often severely limits the spatial configuration of the photovoltaic cells, necessitating the provision of an arrangement of substantially coplanar photovoltaic cells. Thus, the elimination of rigid plates allows for a wider range of photovoltaic cell configurations and a higher degree of design flexibility. Such flexibility allows photovoltaic cells to be used in new locations and for new purposes.

In the context of the present disclosure, an element (e.g., a plate) may be considered "rigid," e.g., if it does not substantially deform under the influence of gravity. For example, when such a rigid plate stands on its narrow side, it may deflect slightly under the influence of gravity, but-under the influence of gravity-preferably does not collapse (e.g. due to its own weight). Instead, the polymer foil may be made of a soft and/or flexible material. Alternatively, the polymeric foil cannot stand on its narrow side or otherwise fold and/or collapse under its own weight.

Alternatively or additionally to the use of a polymer foil as described above, the method may comprise the step of at least partially or fully encapsulating the solar cell arrangement and/or the one or more strings of photovoltaic cells in an encapsulating liquid or gel. The encapsulating liquid or gel may be a hardened liquid or gel, respectively. Hardening may be due to, for example, evaporation of volatile components, chemical reactions (e.g., polymerization), and/or the effects of heat and/or ultraviolet light. The encapsulated solar cell device may also be referred to as a "solar cell assembly". The front and/or back layers may then be subsequently injection molded directly onto the encapsulated solar cell device. For example, the front and/or back layers may be injection molded directly onto the encapsulating liquid or gel, preferably after it has at least partially hardened. The encapsulation of the photovoltaic cell provides the photovoltaic cell with a further barrier against fluid ingress, oxidation and further damaging environmental effects. In addition, the encapsulation may hold the photovoltaic cells in place during the injection molding process.

Whether a polymer foil or an encapsulating liquid or gel is used, the above-described solar cell module is preferably manufactured in a flat or substantially flat configuration. This may facilitate production, especially when using lamination techniques. Such a flat or substantially flat solar cell module may be slightly curved (preferably only slightly curved) when inserted into an injection molding mold. This may include bending of the photovoltaic cell within acceptable limits. Alternatively, the solar cell module may be manufactured in a curved shape. This may facilitate subsequent production steps and may allow the module to have a stronger curvature and/or a sharper bend.

Alternatively or in addition to the use of the above-described polymer foils and/or encapsulations, the mould may also be provided with one or more recesses and/or one or more protrusions for holding the photovoltaic cell, solar cell device or solar cell assembly in place in the mould to reduce the risk of cell misalignment during injection moulding. For example, each solar cell and/or solar cell arrangement may be arranged in a respective recess and/or each cell, solar cell arrangement or solar cell assembly may be held by a respective holder arrangement. The retainer means may comprise one or more protrusions. Alternatively or additionally, the injection molding mold may be configured to clamp the solar cell device and/or its photovoltaic cell between two movable mold portions, e.g. between two halves of the mold.

Alternatively or additionally to the use of the above-mentioned polymer foil and/or the above-mentioned encapsulating liquid and/or the use of the above-mentioned recesses, protrusions and/or clamps, the method may comprise: a first injection molding step in which a first molding layer is injection molded onto a photovoltaic cell, a solar cell device, or a solar cell module; and a second injection molding step, wherein a second molding layer is injection molded onto the first molding layer, the photovoltaic cell, the solar cell device, and/or the solar cell device. Optionally, the first injection molding step is performed directly on the photovoltaic cell or solar cell device.

The first molding layer may form a front layer and the second molding layer may form a back layer of a photovoltaic module for solar energy, or vice versa. Providing the front and back layers as injection molded layers has the advantage of protecting the photovoltaic cell from both sides, and the photovoltaic cell may optionally be completely encapsulated or embedded within the injection molded material. This may protect the photovoltaic cell from environmental damage and may allow for direct inclusion in various technologies. Furthermore, the process can be more easily automated.

Optionally, the first injection moulding step is performed at a lower pressure than the second injection moulding step. Such a method may be particularly beneficial if the injection molding step is performed directly on the photovoltaic cell when the photovoltaic cell is not supported (e.g., by a rigid plate). Since the photovoltaic cells may subsequently be fragile and/or movable in the injection molding mold, performing the first injection molding step at a lower pressure may help prevent damage to the cells and/or cell misalignment in the photovoltaic module. Once the first injection molding step is performed, the photovoltaic cell can be better stabilized and supported. The second injection molding step can then be carried out at a higher pressure if desired.

Optionally, the first polymer composition is injected in a first injection molding step and the second polymer composition is injected in a second injection molding step. Preferably, one of the first and second compositions is transparent and the other is translucent or opaque. Alternatively, the first composition may be transparent and the second composition may be coloured. The transparent layer is then preferably formed on a side of the photovoltaic module and/or a side of the photovoltaic cell configured to face the sun and/or receive sunlight to generate electricity. The first and second compositions may also have different colors. The first composition may form a front layer of a photovoltaic module. The second composition may form a back layer of the photovoltaic module.

Optionally, the first composition comprises a different type of polymer than the second composition. The first composition may include a first polymer, such as a first thermoplastic or thermoset polymer, that forms the matrix of the first molding layer. The second composition may include a second polymer, such as a second thermoplastic or thermoset polymer, that forms the matrix of the second molding layer. The first polymer and the second polymer may have different structural formulae. Alternatively or additionally, one of the compositions may include reinforcing fibers (e.g., carbon fibers, glass fibers, and/or kevlar fibers) while the other does not include, or the first and second compositions may include, different amounts of such reinforcing fibers. This may help to adjust the mechanical and/or optical properties of the front and back layers. For example, the first polymer may be or may include a material such as polypropylene (PP), Polyurethane (PU), Polycarbonate (PC), Polyethylene (PE), Polytetrafluoroethylene (PTFE), Polyoxymethylene (POM), Acrylonitrile Butadiene Styrene (ABS), Polyaryletherketone (PAEK), Polyetheretherketone (PEEK), polypropylene and ethylene copolymers, epoxy, phenolic, nylon, Polystyrene (PS), and/or silicone (or any combination thereof). The second polymer may include materials such as polypropylene (PP), Polyurethane (PEI), Polycarbonate (PC), Polyethylene (PE), Polytetrafluoroethylene (PTFE), Polyoxymethylene (POM), Acrylonitrile Butadiene Styrene (ABS), Polyaryletherketone (PAEK), Polyetheretherketone (PEEK), copolymers of polypropylene and ethylene, epoxy, phenolic, nylon, Polystyrene (PS), and/or silicone (or any combination thereof). Any combination of these materials may be used as appropriate. Furthermore, providing the first and second polymers with two different compositions may facilitate performing the first and second injection molding steps at different pressures.

Preferably, the first injection molding step is performed in a mold comprising at least a first mold part and a second mold part, wherein a first cavity is formed between the first mold part and the second mold part and the material injected during the first injection molding step is contained in the first cavity. The solar cell device may then be arranged on the first mould part before the first injection moulding step is performed.

Optionally, the mould may further comprise a third mould part. A second cavity may then be formed between the partially fabricated photovoltaic module and the third mold portion, where the second cavity may be configured to receive material injected into the mold during the second injection molding step. Such a mold configuration allows for a two-step injection molding process, optionally using two different injection molding compositions and/or different pressures.

The method may comprise a further moulding step (e.g. a third injection moulding step) depending on the shape to be produced, the layer to be provided and/or the material to be used. For example, an elastomeric material (e.g., a thermoplastic elastomer) may be molded to the photovoltaic module to provide one or more sealing components (e.g., a sealing profile for a movable component of a structure or vehicle).

Preferably, one or more mounting brackets, one or more mounting holes, one or more support structures, one or more protective frames and/or one or more junction boxes for connecting a plurality of cells and/or a plurality of cell strings of a solar cell arrangement are injection molded onto the photovoltaic module. Optionally, one or more mounting brackets, one or more mounting holes, one or more support structures, one or more protective frames, and/or one or more junction boxes may be integrally formed with the front and/or rear layers when injection molding the layers. Such a step may be advantageous when the photovoltaic module is to be included in a larger structure, such as a roof or an automotive panel, so that the module is immediately available and further assembly steps are avoided.

The protective frame may at least partially or completely surround the photovoltaic module, preferably around its narrower edges. Such a frame may, for example, protect the module from side impacts.

One or more mounting brackets may allow for attachment of the photovoltaic module to another structure. One or more mounting holes may be provided in the mounting bracket to facilitate attachment. One or more mounting brackets may extend from the protective frame.

The one or more support structures may include one or more ribs. The ribs may intersect one another and may optionally form a honeycomb structure. Optionally, the back layer of the photovoltaic module may include a first major surface facing the front layer and a second major surface opposite the first major surface, and the support structure may be disposed on the second major surface. Such a support structure can physically support the photovoltaic module and protect the photovoltaic cells from damage. The ribs may be integrally formed with the rear layer. The one or more ribs may be longer (preferably in a direction along the rear layer) than they are tall (preferably in a direction away from the rear layer). The ribs may form a mesh and/or a lattice.

Preferably, the method may further comprise the step of providing external electrical connection means of the photovoltaic module onto the front layer and/or the rear layer of the photovoltaic module. The external electrical connection means may be provided after the injection molding step is performed.

Optionally, at least a portion of the back layer of the photovoltaic module may include reinforcing fibers, such as reinforcing fibers surrounded by its polymer matrix. Such fibers may be made of carbon fibers, glass fibers, kevlar fibers, or combinations thereof. In particular, a portion of the rear layer forming the support structure may comprise such reinforcing fibers.

Preferably, each photovoltaic cell of the solar cell arrangement extends in a respective reference plane. At least some of the reference planes of adjacent cells intersect at an angle greater than 2 °, more preferably greater than 4 ° or greater than 5 °. Alternatively or additionally, the reference planes of adjacent cells may be parallel but offset from each other in a direction perpendicular to the reference planes. Any of these configurations may employ photovoltaic modules in curved, angled, and/or complex forms and provide more versatility in the manufacture of photovoltaic modules. Preferably, the photovoltaic cells are spaced apart from each other and electrically interconnected by conductive tape, wires or interconnectors. Alternatively or additionally, the positive side of one cell may be connected with the negative side of an adjacent cell.

The photovoltaic module may have two major surfaces: a first major surface configured to receive sunlight to cause the module to generate electrical energy; and a second major surface opposite the first major surface. The second major surface may be configured to face away from the sun, e.g., toward the interior of a building or vehicle. The first major surface may be configured to form an exterior surface of a structure or vehicle on which the module is mounted. For example, the first major surface may be configured to form an exterior surface of a body panel (e.g., a side body panel), hood, door, trunk, and/or roof of an automobile. Accordingly, a module according to the present disclosure may be shaped as a body panel, hood, door, trunk, and/or roof of an automobile. A support structure (e.g., one or more ribs) may be provided along the second major surface of the module, i.e., on a side configured to face away from the sun and/or toward the interior of the structure or vehicle to which the module is attached.

Preferably, the first and/or second main surface is not flat. More preferably, the first and/or second main surface is curved and/or angled and/or has a complex shape. For example, at least a portion of the first and/or second major surfaces may be curved in a three-dimensional manner. For example, the radius of curvature of the curved portion may be at least 10cm, at least 40cm, at least 50cm, or at least 60cm, or at least 80 cm. Alternatively or additionally, the radius of curvature of the curved portion may be no greater than 1000cm, or may be no greater than 500cm, or may be no greater than 300cm, or may be no greater than 200 cm. Preferably, the injection molded layer is shaped as a non-flat layer. The outer surface of the injection molded layer facing the first major side and/or the outer surface of the injection molded layer facing the second major side may have a radius of curvature of less than 1000cm, less than 500cm, less than 300cm or less than 200 cm.

At the same time, the photovoltaic cell may be substantially flat or only slightly curved. In particular, each photovoltaic cell may be flat, or the radius of curvature of each photovoltaic cell may be greater than the radius of curvature of the first major surface and/or greater than the radius of curvature of the second major surface. In other words, the radius of curvature of each photovoltaic cell may be larger than the outer surface of the injection molded layer facing the first main side and/or larger than the outer surface of the injection molded layer facing the second main side of the module.

The method according to the present disclosure may further comprise the step of providing a protective layer, in particular a protective layer or film, on the front side (e.g. on the first main surface) of the module, preferably by injection molding the layer or film onto the front and/or back layer. Materials that may be used for such a protective layer or film are polypropylene (PP), Polyurethane (PU), Polycarbonate (PC), Polyethylene (PE), Polytetrafluoroethylene (PTFE), Polyoxymethylene (POM), Acrylonitrile Butadiene Styrene (ABS), Polyaryletherketone (PAEK), Polyetheretherketone (PEEK), polypropylene and ethylene copolymers, epoxy, phenolic, nylon, Polystyrene (PS) and/or silicone (or any combination thereof). When injection molding is not possible, any type of clear coat or spray coating may be used.

Those skilled in the art will appreciate that injection molding is a process that is performed at elevated temperatures and/or pressures. For example, the injection pressure at the nozzle may be 5MPa or more, 10MPa or more, 20MPa or more, 50MPa or more, or 100MPa or more. The method preferably comprises plasticizing the raw material provided as granules, powder and/or noodles so that it becomes flowable. The forming machine may comprise a screw, preferably a reciprocating screw. The mold may be cooled and/or the material may be cooled in the mold (e.g., when injection molding a thermoplastic material). The melt temperature may be selected depending on the material being molded. For example, melt temperatures above 150 ℃, above 180 ℃ or above 200 ℃ may be used. In other cases, the mold may be heated to crosslink the polymer (e.g., when injection molding thermoset or elastomeric materials).

According to another aspect, the invention relates to a photovoltaic module comprising a solar cell arrangement, preferably comprising a plurality of rigid photovoltaic solar cells and electrical connections connecting the cells. Optionally, the photovoltaic cell is rigid and/or the photovoltaic cell is a crystalline silicon photovoltaic solar cell. Any of the above types may be used. The photovoltaic module further comprises a front layer and a back layer, wherein the solar cell device is at least partially or completely encapsulated between the front layer and the back layer. At least a portion of the front layer and/or at least a portion of the back layer are formed by injection molding.

The photovoltaic module can be manufactured by any of the methods discussed above and can have any of the features mentioned above.

Preferably, the photovoltaic cells are individual photovoltaic cells and the solar cell device may further comprise a carrier interconnecting the individual photovoltaic cells. The support may be a layer that serves for mechanical stabilization. Alternatively or additionally, the solar cell may be bonded to a foil and/or soldered to a substrate. In the case of a foil, it may be used as a substrate or superstrate. Additionally, the solar cell device may consist of only one solar cell. The solar cell apparatus may comprise a string of cells.

The inclusion of a carrier may allow flexible interconnection of the photovoltaic cells and protect the electrical connections without substantially limiting the physical placement of the photovoltaic cells relative to each other.

As described above, the photovoltaic cells of the photovoltaic module may be at least partially or fully encapsulated in an encapsulating gel or liquid. Such an encapsulation further protects the photovoltaic cell from the elements and may also help to maintain the integrity of the photovoltaic cell during the injection molding process.

As described above, the front layer and/or the rear layer of the photovoltaic module may include a first molding layer formed by injection molding and a second molding layer formed by injection molding.

Alternatively or additionally, the front and/or back layers may comprise a polymeric foil. The polymer foil may help protect the solar cells from the environment or protect them during injection molding.

Preferably, the solar cell device does not comprise a rigid plate. Such a lack of rigid plates, for example for mounting solar cell devices, allows for more flexibility in placing the photovoltaic cells and allows for a wider range of shapes to be obtained by injection molding processes. The method according to the invention preferably does not comprise attaching the solar cell device to a prefabricated rigid panel (e.g. a prefabricated panel made of glass or PC).

Preferably, the back layer further comprises a support structure, preferably wherein the support structure comprises a plurality of ribs, more preferably wherein the ribs intersect each other, even more preferably wherein the support structure is a honeycomb structure. The support structure can help maintain the rigidity and strength of the photovoltaic module and protect the solar cells from damage.

Optionally, at least a portion of the back layer comprises reinforcing fibers in a polymer matrix.

According to another aspect, the invention relates to a vehicle (e.g. a car, bus, truck, train or airplane) or a building (e.g. a house) comprising a photovoltaic module according to the invention. In particular, the photovoltaic module itself may be shaped as a body panel, hood, door, trunk or roof of such a vehicle. Optionally, the photovoltaic module may include molded brackets and inserts for direct attachment to a structure or frame (e.g., a vehicle structure and/or frame) and/or a hinge (e.g., a hinge connected to the vehicle structure and/or frame). These brackets and inserts may be injection molded and/or integrally molded with the module. In other words, the connecting and/or supporting module may not require additional structure, such as additional frames (e.g., metal frames), or functional elements extending around and/or holding the module to connect and/or support the module, such as at the vehicle structure and/or frame and/or hinges connected to the structure and/or frame.

Drawings

The subject matter of the invention will be explained in more detail below with reference to preferred exemplary embodiments shown in the drawings, in which:

fig. 1 schematically illustrates a perspective view of a photovoltaic module including a polymer film;

figure 2 schematically illustrates a perspective view of a photovoltaic module with encapsulated solar cells;

figure 3 schematically illustrates a perspective view of a photovoltaic module having two injection molded layers;

FIG. 4a schematically illustrates a cross-sectional view of an injection molding die or mold for use in an injection molding process;

FIG. 4b schematically shows a cross-sectional view of an injection molding die or punch for the second step of the two-step injection molding process;

fig. 5 schematically illustrates a photovoltaic module including a protective frame and a mounting bracket;

figure 6 schematically shows a cross-sectional view of the photovoltaic module of figure 5;

FIG. 7 schematically illustrates a cross-sectional view of a curved photovoltaic module, wherein the photovoltaic cells are positioned at an angle to each other;

fig. 8 schematically illustrates a cross-sectional view of a curved photovoltaic module in which the photovoltaic cells are positioned offset from one another.

Figure 9a schematically illustrates a cross-sectional view of a photovoltaic module including representative electrical connections.

Figure 9b schematically illustrates a cross-sectional view of a photovoltaic module including a representative electrical connection and release ring.

Fig. 9c shows an exemplary configuration of the release ring.

Fig. 9d shows another exemplary configuration of the release ring.

Detailed Description

In the present description, the term "solar cell" preferably refers to a photovoltaic cell that converts radiant light energy into electrical energy by the photovoltaic effect. A solar cell arrangement comprises at least one solar cell provided with electrical connection elements. The solar cell device may comprise a plurality of solar cells electrically interconnected. The solar cells may be connected in series or in parallel or any combination thereof.

Many different types of known or commercially available solar cells can be used in the present invention. The solar cell material may include any kind of solar cell, including single-junction to multi-junction solar cells and/or single crystal cells. For example, cadmium telluride, gallium arsenide, amorphous or crystalline silicon, or III-V compound photovoltaic cells may be used. The solar cells may be rigid or flexible. The present invention is particularly applicable to rigid solar cells, such as solar cells made from semiconductor wafers, as other methods of forming photovoltaic modules may not be suitable for rigid solar cells. Injection molding can provide a curved or complex geometry for a photovoltaic module, which other manufacturing methods may not provide without damaging the rigid solar cells.

The solar cells of the solar cell arrangement may preferably be connected in a string configuration comprising a plurality of solar cells arranged in a row and connected in series. The positive electrode side of a solar cell may be connected to the negative electrode side of an adjacent solar cell. The electrical connection between each solar cell may be formed by conductive tape, wires or interconnects.

In general, a solar cell device may include a plurality of other components or substrates. The solar cell device may include a bus bar and a mounting substrate or superstrate. Such a mounting substrate may be a flexible substrate or a superstrate, such as a polymer foil. However, rigid substrates such as glass or polycarbonate may also be used.

The present invention relates to a method of manufacturing a photovoltaic module using an injection molding process. The photovoltaic module includes a front layer and a back layer, with the solar cell device being encapsulated between the front layer and the back layer. The solar cell device comprises a plurality of photovoltaic cells, which may be rigid. In some cases, the photovoltaic cell may be a crystalline silicon photovoltaic cell or any of the above types. The solar cell device comprises an electrical connection between the individual solar cells and an optional substrate or superstrate.

The formation of the photovoltaic module comprises providing a solar cell arrangement as described above, and then providing the solar cell arrangement with a layer by injection molding at least a part of the front layer or the back layer to the solar cell arrangement.

More specifically, fig. 1 shows a photovoltaic module 1 with one possible configuration of a solar cell arrangement 100. The solar cell arrangement 100 comprises a string of photovoltaic cells 10 and electrical connections 11 for electrically connecting said cells 10. Although two strings of cells 10, 10 cells per string, are shown here, it should be understood that any number of solar cells 10 may be present, including a single solar cell 10. Preferably, the solar cell arrangement 100 comprises at least 4, at least 10 or at least 20 solar cells.

The solar cells of fig. 1 may be disposed on the surface of the polymer foil 110 in linearly arranged rows. In such a configuration, the solar cell may be bonded to the polymer foil 110, preferably by heating, thereby melting the polymer foil 110 to the solar cell 10 and/or embedding the cell in the foil 110. Alternatively or additionally, the foil and the solar cell may be joined together by a lamination process and/or an adhesive. Alternatively, the solar cell 10 may rest only on the polymer sheet. In some cases, the polymer sheet may comprise a polyester thermoplastic selected from the list of thermoplastics disclosed herein. The polymer sheet may alternatively comprise EVA, optionally in combination with additional polymers. In this configuration, the polymer foil 110 and the solar cell 10 are placed within an injection molding apparatus. Then, an injection molding process is performed, with the injection molding material 120 being deposited directly on the solar cell 10 and/or directly on the polymer foil 110.

The injection molding material 120 provides structure and protection for the solar cell device from elements. The injection molding material 120 may be optically transparent to allow light radiation to pass through, particularly when the injection molding material 120 is deposited on the sun-facing side of the solar cell 10. Alternatively, the injection molding material 120 may be optically opaque and/or colored, for example, if the injection molding material 120 is deposited on the polymer foil 110 (e.g., on the side opposite the side on which the solar cells 10 are disposed). A preferred configuration of the photovoltaic module 1 is to deposit the injection molding material 120 on the side of the solar cell device 100 opposite the polymer foil 110.

It is also preferable that, in the configuration of fig. 1, no rigid plate is provided for the solar cell 10. In particular, further lamination of the solar cell with polycarbonate and/or glass plates is preferably not performed and/or required. In this manner, the injection molding material 120 may provide structure and support to the solar cell apparatus 100 that would otherwise be lacking without a rigid glass plate or the like.

Fig. 2 depicts a perspective view of another possible configuration of a photovoltaic module 1 with a solar cell arrangement 100. In this variation, the solar cell device 100 has been encapsulated in the encapsulant 130 prior to deposition of the injection molding material 120. The encapsulant 130 may partially or completely surround the solar cell device 100. The encapsulant can be any number of materials. Preferably, a sealant liquid or gel is provided, for example an Ethylene Vinyl Acetate (EVA) based sealant liquid or gel. The encapsulant liquid and/or gel is poured, deposited, or otherwise applied to the solar cell device 100 and then allowed to cure over time or cured using heat, UV radiation, or by other chemical means to obtain a hardened encapsulant 130.

For example, the encapsulation of the solar cell 10 may also be combined with the presence of a polymer foil 110, as shown in fig. 1. For example, the solar cell device may first be encapsulated within the encapsulant 130 and then disposed and/or bonded to the polymer foil 110. In this case, the injection molding material 120 is preferably deposited on the side of the solar cell device 100 opposite the polymer foil 110.

The solar cell device 100 may also be arranged and/or bonded to the polymer foil 110 and then both encapsulated within the encapsulant 130. In this case, the injection molding material 120 may be deposited on either side of the encapsulated solar cell device.

Fig. 3 illustrates a perspective view of another possible configuration of the photovoltaic module 1 and the solar cell apparatus 100. In this case, the photovoltaic module 1 undergoes two different injection molding steps. The first molding layer 120 has been injection molded on a first surface (an upper surface in fig. 3) of the solar cell apparatus 100 and the second molding layer 140 has been injection molded on a second surface (a lower surface in fig. 3) of the solar cell apparatus 100. In this configuration, the first molding layer 120 and/or the second molding layer 140 may be directly formed on the solar cell 10. The configuration of fig. 3 may optionally be combined with the polymer foil 110 and/or the sealant 130, for example as shown in fig. 1 and 2.

Since rigid photovoltaic cells may be susceptible to damage or rupture, in this embodiment, the first injection molding step may be performed at a first pressure that is lower than the second pressure of the second injection molding step. The lower pressure may help protect the solar cell from damage, such as cracking, during the injection molding process. It is also possible to prevent movement of the solar cell and/or the solar cell device.

Once the solar cell has been provided with support and protection by the first molding layer 120, the second injection molding step may be performed at a higher pressure. The first and/or second pressure may be 1MPa or more, 5MPa or more, 10MPa or more, 20MPa or more, 50MPa or more, or 100MPa or more. Without wishing to be bound by these values (or any other values disclosed herein), the first pressure may be less than 20MPa, less than 10MPa, or less than 5 MPa.

One or both of the shaping layers 120, 140 may be transparent. Alternatively, one of the shaping layers may be transparent and the other opaque. Further, the first and second molding layers 120, 140 may be different colors or have different compositions. The first molding layer 120 may include a different type of polymer than the second molding layer 140.

Optionally, the first molding layer 120 comprises a first thermoplastic polymer forming the matrix of the first molding layer and the second molding layer 140 comprises a second thermoplastic polymer forming the matrix of the second molding layer. The first and second thermoplastic polymers may have different structural formulae.

Fig. 4a and 4b illustrate an example of a molding process. As shown in fig. 4a, the first injection molding step occurs within the injection molding die 200. The mold includes at least a first mold portion 250 and a second mold portion 260, however it should be understood that the mold may include additional molded parts to facilitate different types of injection molding processes. A cavity 291 is formed between the mold portions 250, 260 in which the solar cell apparatus 100 may be placed. Alternatively, the first mold portion 250 may have one or more grooves in which the solar cell apparatus 100 or individual solar cells 10 may be placed. Such grooves may help to maintain the solar cell 10 in a particular position and configuration during the injection molding process. Injection molding material, such as thermoplastic material, is injected from reservoir 280 into molding die 200 by an injection molding machine. The injection molding material then forms a layer on one side of the solar cell device 100. As shown in fig. 4b, another additional injection molding step may optionally be performed by removing one of the first or second mold portions and replacing it with a third mold portion 270. Another cavity 292 is then formed in the molding die with the solar cell device 100 inside. Subsequently, a second injection molding step is performed on the side of the solar cell apparatus 10 opposite to the first side. In this way, the solar cell device 100 may be completely encapsulated and/or enclosed by the injection molding material.

As further illustrated in the figures. Referring to fig. 5 and 6, one benefit of manufacturing the photovoltaic module 1 by an injection molding process is the integral inclusion and/or integration of the secondary structure. For example, one or more mounting brackets 190 may be integrally formed with photovoltaic module 1. This may reduce the number of steps required to produce a finished photovoltaic module 1 and make the module immediately ready for mounting on, for example, the frame of a vehicle. Alternatively or additionally, the mounting holes 191 may be integrally formed in the front and/or rear layers of the module 1, in the protective frame 195, and/or in one or more mounting brackets 190 during the injection molding process. Other support structures, such as protective frame 195, may also be integrally formed during the injection molding process. Advantageously, a junction box 197 for electrically connecting the solar cell 10 (e.g., to additional electronics of a structure or vehicle) may be injection molded integrally with the photovoltaic module (e.g., with the protective frame 195).

As shown in more detail in fig. 6, the photovoltaic module may optionally include a support structure, which may also be integrally formed during the injection molding process. The support structure may help provide mechanical strength and rigidity to the module 1. Such a support structure may take any configuration, such as a plurality of ribs 180. The ribs 180 may, for example, be parallel to each other and/or may cross each other to form a lattice support structure. One example of such a support structure includes intersecting ribs 180 that form a honeycomb structure. Preferably, such a honeycomb support structure is included on the rear side of the module 1, which is not intended to receive sunlight.

In an injection molding process, one of the molding layers may also be formed using an injection molding material that includes reinforcing fibers in a polymer matrix. Such reinforcing fibers may be made of carbon, glass and/or kevlar.

Fig. 7 and 8 illustrate further example configurations of injection molded photovoltaic modules. As shown in fig. 7 and 8, the solar cell may be completely encapsulated and/or enclosed within the injection molded material. The front and back layers of the solar cell device and photovoltaic module may include any number of other features as described above, including but not limited to polymer foils, encapsulating fluids, support structures, and/or reinforcing fibers. They may be produced by any of the methods discussed in this disclosure.

Fig. 7 and 8 show how a photovoltaic cell 10, in particular a rigid photovoltaic cell, can be used while still providing an injection molded photovoltaic module 1 having a curved or angled shape. In particular, the preferably transparent sun-facing outer surface of the module 1 (e.g. the outer surface of the front layer) may have such a curved or angled outer shape.

In fig. 7, the photovoltaic module 1 itself is curved and can therefore be integrated in larger structures requiring more complex geometries. The solar cells 10 are located within the photovoltaic module 1, wherein each solar cell 10 extends within a particular plane. For example, solar cell 10a extends in plane a and solar cell 10B extends in plane B. As shown, the solar cells 10a and 10B are fixed at an angle relative to each other such that an angle α is formed between plane a and plane B. The intersection may be at an angle of greater than 2 deg., more preferably greater than 4 deg. or greater than 5 deg.. This enables the photovoltaic module 1 to assume a curved and/or angled form.

Further geometries are contemplated wherein the angle of intersection may even be up to 30 ° or more, up to 45 ° or more, or even up to 90 ° or more. In this manner, structurally complex photovoltaic modules can be created for integration into larger structures.

Fig. 8 shows an alternative arrangement of the solar cell 10, wherein the solar cell 10 may be embedded within the photovoltaic module 1. In this particular example, the photovoltaic module 1 employs a curved geometry, however, it may employ any number of complex geometries, including planar geometries or angled geometries. In this variant, the solar cells 10 all extend in a plane. For example, solar cell 10a extends in plane a and solar cell 10B extends in plane B. In the configuration shown in fig. 8, planes a and B are substantially parallel to each other. However, the planes a and B are offset from each other in a direction perpendicular to the extending direction of the planes a and B. This provides an alternative method for arranging individual solar cells 10 within the photovoltaic module 1, such that the photovoltaic module 1 has a complex geometry, including a curved geometry. Those skilled in the art will appreciate that the arrangement shown in fig. 1 and 5 is not so limited.

The solutions of fig. 7 and 8 can also be combined.

Fig. 9a illustrates an example of a photovoltaic module comprising encapsulated solar cells 10 and representative electrical connections 11 in the form of conductive tapes or wires. In this example, the negative side of one solar cell may be electrically connected in series to the positive side of the next solar cell. The cells and electrical connections in the present arrangement are encapsulated within a hardened encapsulant 130. As described above, the polymer foil 110 may be included instead of or in addition to the sealant 130. However, the sealant 130 and the polymer foil 110 may also be omitted.

The first molding layer 120 and the second molding layer 140 surround the encapsulated solar cell device. The present system depicts two solar cells 10, however any number of solar cells may be included in such embodiments in a similar manner. Furthermore, it should be understood that the solar cells 10 of the present arrangement may be injection molded in an angled or offset pattern, such as in fig. 1 and 2. Referring to fig. 7 and 8, to form a non-planar photovoltaic module. A single shaped layer may be provided in place of layers 120,140 if desired.

An optional frame 195 is also shown which may be injection molded to the solar cell device. The frame 195 may be manufactured (e.g., from a third material) in a third injection molding step. Alternatively, the frame may be made of the material used for the first molding layer 120 or of the material used for the second molding layer 140, for example, when injection molding said first layer 120 or said second layer 140, respectively.

Fig. 9b illustrates an exemplary embodiment of a photovoltaic module, which may include all of the features as illustrated in fig. 9 a. Further, a release ring 12 is shown. The release ring 12 may be a wire or ribbon that is preformed into a curved or looped shape. The release ring 12 forms part of an electrical connection between adjacent solar cells 10. When a photovoltaic module is subjected to thermal stress, such as heating, the component materials of the photovoltaic module may not respond equivalently to temperature changes. For example, some materials may expand more than others. This can place mechanical stress on the various components of the photovoltaic module. By including a relief loop 12 such as shown herein, the relief loop 12 may be partially straightened or further coiled to compensate for mechanical stresses generated by thermal variations in the photovoltaic module. Such a release ring 12 may be included only at selected electrical junctions within the photovoltaic module or as part of each electrical connection between individual elements and/or individual cells.

Fig. 9c and 9d show further exemplary configurations of the release ring 12. In fig. 9c, the shape of the relief is shown. In fig. 9d, the ring-shaped part is shown. It should be understood that each of these designs includes one or more portions extending away from the axis L along which the connector typically extends to accommodate thermal expansion and/or contraction. While the invention has been illustrated and described in detail in the drawings and foregoing description, such illustration and description are to be considered illustrative or exemplary and not restrictive; the invention is therefore not limited to the disclosed embodiments. Variations to the disclosed embodiments can be understood and effected by those skilled in the art and practicing the claimed invention, from a study of the drawings, the disclosure, and the appended claims. In the claims, the word "comprising" does not exclude other elements or steps, and the indefinite article "a" or "an" does not exclude a plurality, possibly indicating "at least one".

The following are preferred aspects of the invention:

1. a method of manufacturing a photovoltaic module is provided,

the module comprises at least one front layer and at least one back layer and a solar cell arrangement encapsulated between the front layer and the back layer, the solar cell arrangement comprising a plurality of photovoltaic cells, preferably rigid photovoltaic cells, more preferably crystalline silicon photovoltaic cells; and an electrical connection connecting the cells;

the method at least comprises the following steps:

-providing a solar cell arrangement; and

-providing a molding layer by injection molding at least a part of the front layer and/or at least a part of the back layer onto the solar cell device.

2. The method of aspect 1, further comprising the steps of:

-providing a polymer foil;

-arranging a solar cell device on a foil;

wherein the injection molding step is performed directly on the solar cell and/or the foil.

3. The method according to aspect 2, wherein the molding layer is a front layer or a back layer, preferably wherein the foil forms the other of the front layer and the back layer, more preferably wherein the front layer and/or the back layer form an outer surface of the photovoltaic module.

4. The method according to aspect 2 or 3, wherein the molding layer is injection molded onto a side of the solar cell device opposite the foil.

5. The method of any of aspects 2-4, further comprising the steps of:

-joining the foil and the solar cell device together, preferably by heating, before injection moulding the moulding layer.

6. The method according to any of aspects 2 to 5, wherein the foil and the solar cell device are joined together by a lamination process, preferably without using a rigid plate, in particular made of glass.

7. The method according to any of the preceding aspects, further comprising the steps of:

-at least partially or completely encapsulating the solar cell device in an encapsulating polymer, wherein the front layer and/or the back layer is injection molded directly onto the encapsulated solar cell device.

8. The method according to any one of the preceding aspects, wherein the step of injection molding comprises:

-a first injection molding step, in which a first molding layer is injection molded onto the battery;

a second injection molding step in which a second molding layer is injection molded onto the battery,

preferably wherein the first injection molding step is performed directly on the solar cell.

9. The method according to aspect 8, wherein the first injection molding step is performed at a lower pressure than the second injection molding step.

10. The method according to aspect 8 or 9,

-wherein the first polymer composition is injected in a first injection molding step and the second polymer composition is injected in a second injection molding step;

preferably wherein

-one of the first and second compositions is transparent and the other is translucent or opaque;

-wherein the first and second compositions have different colors;

-wherein the first composition comprises a different type of polymer than the second composition, preferably wherein the first composition comprises a first thermoplastic polymer forming the matrix of the first molding layer and the second composition comprises a second thermoplastic polymer layer forming the matrix of the second molding layer, wherein the first and second thermoplastic polymers have different structural formulae.

11. The method according to any one of aspects 8 to 10,

wherein the first injection molding step is performed in a mold comprising at least a first mold portion and a second mold portion;

wherein the solar cell device is arranged on the first mould part;

wherein a cavity is formed between the solar cell apparatus and the second mold portion, the cavity being configured to receive material injected into the mold during the first injection molding step.

12. According to the method of the aspect 11,

wherein the mold comprises a third mold portion;

wherein a second cavity is formed between the solar cell apparatus and the third mold portion, the second cavity being configured to receive material injected into the mold during the second injection molding step.

13. According to the method of the aspect 11 or 12,

wherein each cell of the solar cell device is arranged on a curved or flat surface portion of the first mould part; and/or

Wherein each cell of the solar cell device is arranged in a recess of the first mould part.

14. The method according to any of the preceding aspects, wherein the solar cells are individual solar cells and the solar cell arrangement further comprises a carrier between the individual solar cells.

15. The method according to any of the preceding aspects, wherein

-one or more mounting brackets; and/or

-one or more mounting holes; and/or

-a support structure; and/or

-a protective frame; and/or

Junction box for connecting a plurality of cells or a plurality of cell strings of a solar cell arrangement

Is injection molded to the photovoltaic module, preferably wherein preferably the mounting brackets, mounting holes, support structures, protective frames and/or junction boxes are integrally formed in the front layer and/or the rear layer when the layers are injection molded.

16. According to the method of the aspect 15,

wherein the support structure comprises a plurality of ribs, preferably wherein the ribs intersect one another, more preferably wherein the support structure is a honeycomb structure;

preferably, wherein the back layer comprises a first major surface facing the front layer and a second major surface opposite to said first major surface, wherein the support structure is arranged on the second major surface.

17. The method according to any of the preceding aspects, further comprising the steps of:

-providing external electrical connection means of the module on the front layer and/or the rear layer.

18. The method of any of the preceding aspects, wherein at least a portion of the back layer comprises reinforcing fibers in a polymer matrix, in particular forming part of a support structure.

19. The method according to any of the preceding aspects,

wherein each cell of the solar cell arrangement extends in a respective reference plane, wherein at least some reference planes of adjacent cells intersect at an angle, preferably an angle greater than 2 °, more preferably an angle greater than 4 ° or more than 5 °; or

Wherein the reference planes of adjacent cells are parallel but offset from each other in a direction perpendicular to the reference planes.

20. The method according to any of the preceding aspects,

wherein the solar cells are spaced apart from each other and electrically interconnected by conductive ribbons, wires, interconnectors, and/or wherein the positive side of one cell is connected to the negative side of an adjacent cell, preferably wherein the electrical connection between the solar cells comprises a release loop.

21. The method according to any one of the preceding aspects, wherein the shaped layer is shaped as a non-flat layer.

22. The method according to any of the preceding aspects, further comprising the steps of:

preferably, a protective layer, in particular a protective film, is provided on the front side of the module by injection molding the film onto the front layer and/or the rear layer.

23. A photovoltaic module, comprising a photovoltaic module having a photovoltaic cell,

a solar cell device comprising a plurality of rigid solar cells, preferably crystalline silicon photovoltaic solar cells, and electrical connections connecting the cells;

a front layer;

a rear layer;

wherein the solar cell device is encapsulated between the front layer and the back layer and at least a portion of the front layer and/or at least a portion of the back layer is formed by injection molding.

24. The photovoltaic module of aspect 23, wherein the solar cells are individual solar cells and the solar cell apparatus further comprises a carrier interconnecting the individual solar cells.

25. The photovoltaic module of aspect 23 or aspect 24, wherein the solar cell device is at least partially or fully encapsulated in an encapsulating polymer.

26. The photovoltaic module according to any of aspects 23-25, wherein the front layer or the back layer comprises a first molding layer formed by injection molding and a second molding layer formed by injection molding.

27. The photovoltaic module of any of aspects 23-26, wherein the front layer or the back layer comprises a polymer foil.

28. The photovoltaic module of any of aspects 23-27, wherein the solar cell device does not comprise a rigid plate.

29. The photovoltaic module of any of aspects 23-28, wherein the back layer comprises a support structure,

preferably wherein the support structure comprises a plurality of ribs, more preferably wherein the ribs intersect each other, even more preferably wherein the support structure is a honeycomb structure.

30. The photovoltaic module of any of aspects 23-29, wherein at least a portion of the back layer comprises reinforcing fibers in a polymer matrix.

The claims (modification according to treaty clause 19)

1. A method for manufacturing a photovoltaic module (1), the module (1) comprising at least one front layer and at least one rear layer and a solar cell arrangement (100) encapsulated between the front layer and the rear layer, the solar cell arrangement (100) comprising a plurality of photovoltaic cells (10) and electrical connections (11) connecting the cells;

-the method comprises at least the following steps:

-providing a solar cell arrangement (100), wherein the photovoltaic cells comprised in the solar cell arrangement (100) are rigid, wafer-based silicon photovoltaic cells (10);

-providing a polymer foil (110);

-arranging a solar cell device (100) on a polymer foil (110);

-bonding together the polymer foil (110) and the solar cell device (100); and

-providing a molding layer (120) by injection molding at least a part of the front layer and/or at least a part of the back layer onto the solar cell device (100);

wherein the foil (110) and the solar cell device (100) are bonded together before injection molding the molding layer (120); and

wherein the injection molding step is performed directly on the at least one photovoltaic cell (10) and on the polymer foil (110).

2. The method of the preceding claim 1, wherein the polymer foil (110) and the solar cell device (100) are joined together by heating or by a lamination process, wherein the heating or lamination process excludes the use of rigid plates.

3. The method according to any of the preceding claims, wherein the molding layer (120) is injection molded onto a side of the solar cell device (100) opposite the polymer foil (110).

4. The method according to any of the preceding claims, further comprising the step of:

-encapsulating the solar cell device (100) at least partially or completely in an encapsulation film, gel and/or liquid (130), wherein the front layer and/or the back layer is injection molded directly onto the encapsulated solar cell device (100).

5. The method of any preceding claim, wherein the injection molding step comprises:

-a first injection molding step, wherein a first molding layer (120) is injection molded onto the solar cell device (10);

-a second injection molding step, wherein a second molding layer (140) is injection molded onto the solar cell device (10);

preferably, wherein at least the first injection molding step is performed directly on the photovoltaic cell (10).

6. The method of claim 5, wherein the first injection molding step is performed at a lower pressure than the second injection molding step.

7. The method according to one of claims 5 and 6, wherein the first polymer composition is injected in a first injection molding step and the second polymer composition is injected in a second injection molding step.

8. The method according to one of claims 5 to 7,

wherein the first injection molding step is performed in a mold comprising at least a first mold part (250) and a second mold part (260);

wherein the solar cell device (100) is arranged on a first mould part (250);

wherein a first cavity (291) is formed between the solar cell device (100) and the second mould part (260), the cavity (291) being configured to receive material injected into the mould during the first injection moulding step.

9. The method of claim 8, wherein the first and second light sources are selected from the group consisting of,

wherein the mould comprises a third mould part (270);

wherein a second cavity (292) is formed between the solar cell device (100) and the first molding layer (120) and the third mold portion (270), the second cavity (292) being configured to receive material injected into the mold during the second injection molding step.

10. The method of any one of the preceding claims, wherein

-one or more mounting brackets (190); and/or

-one or more mounting holes (191); and/or

-a support structure; and/or

-a protective frame (195); and/or

-a junction box (197) for connecting a plurality of cells (10) or a plurality of cell strings of a solar cell arrangement (100);

is injection molded to the photovoltaic module (1), wherein the mounting brackets (190), the mounting holes (191), the support structure, the protective frame (195) and/or the junction box (197) are integrally molded with the front layer and/or with the rear layer, preferably at the time of injection molding the layers.

11. The method of claim 10, wherein the support structure comprises a plurality of ribs (180), preferably wherein the ribs (180) intersect one another, more preferably wherein the support structure is a honeycomb structure;

preferably, wherein the back layer comprises a first major surface facing the front layer and a second major surface opposite to said first major surface, wherein the support structure is arranged on the second major surface.

12. The method according to any one of the preceding claims,

wherein each cell (10a, 10b) of the solar cell arrangement (100) extends in a respective reference plane (A, B);

wherein at least some of the reference planes (A, B) of adjacent cells (10a, 10b) intersect at an angle (α), preferably an angle (α) greater than 2 °, more preferably an angle (α) greater than 4 ° or greater than 5 °; and/or

Wherein the reference planes (A, B) of adjacent cells (10a, 10B) are parallel but offset from each other in a direction perpendicular to the reference planes (A, B).

13. A photovoltaic module (1) comprising,

a solar cell arrangement (100), the solar cell arrangement (100) comprising a plurality of photovoltaic cells (10), wherein the photovoltaic cells comprised in the solar cell arrangement (100) are rigid, wafer-based silicon photovoltaic cells (10);

a polymer foil (110) to which the solar cell device (100) is bonded (110);

a front layer; and

a rear layer;

wherein the solar cell device (100) is encapsulated between a front layer and a back layer, and at least a part of the front layer and/or at least a part of the back layer is formed by injection molding.

14. The photovoltaic module (1) according to claim 13, wherein the solar cell arrangement (100) is at least partially or completely encapsulated in an encapsulating film, gel and/or liquid (130).

15. The photovoltaic module (1) according to one of claims 13 to 14, wherein the front layer or the back layer comprises a first molding layer (120) formed by injection molding and a second molding layer (140) formed by injection molding.

16. The photovoltaic module (1) according to any of claims 13 to 15, wherein the solar cell arrangement (100) does not comprise a rigid plate having a higher rigidity than each of the front and rear layers.

17. The photovoltaic module (1) according to any of claims 13 to 16, wherein the back layer comprises a support structure,

preferably wherein the support structure comprises a plurality of ribs (180), more preferably wherein the ribs (180) intersect each other, even more preferably wherein the support structure is a honeycomb structure.

Statement or declaration (modification according to treaty clause 19)

In response to International Search Reports (ISRs), international search organization (WOISA) written comments and according to PCT article 19;

a modified set of claims 1 to 17 is filed herewith. Wherein modified claim 1 comprises a combination of features initially defined in claims 1 and 2 and modified claim 13 comprises a combination of features initially defined in claims 14 and 15. All other claims have been renumbered accordingly. It is assumed that the subject matter of the independent claims 1 and 13 as modified is both novel and inventive for the reasons stated in the accompanying informal statement.