WO2021013716A1 - Method for manufacturing a photovoltaic collector and photovoltaic collector - Google Patents

Abstract

The manufacturing method aims to obtain a photovoltaic collector (2) configured to convert solar radiation into electrical energy, the photovoltaic collector (2) comprising at least one photovoltaic cell (4), each photovoltaic cell (4) being encapsulated in an encapsulation substrate. The manufacturing method comprises the production of the encapsulation substrate by shaping at least one encapsulation material (M1, M2) in the liquid state over each photovoltaic cell (4).

Description

TITLE: Manufacturing process of a photovoltaic collector and photovoltaic collector

The present invention relates to photovoltaic collectors (or photovoltaic panels) and in particular to their manufacture.

A photovoltaic collector is generally of general planar shape and formed of a laminated stack comprising, in superposition, a transparent protective front plate, a front encapsulation layer, a layer of photovoltaic cells and connections for the interconnection of the photovoltaic cells. and their connection to a connection box making it possible to connect the photovoltaic cells to a load, a rear encapsulation layer and a support back plate, the stack being framed by a support frame and the connection box being generally arranged on the back support plate.

The protective front plate is designed to protect the photovoltaic collector from bad weather and receive solar radiation. It is for example made of glass.

The front and back encapsulation layers sandwich the photovoltaic cells to encapsulate and protect them. The encapsulation layers are made, for example, of ethylene vinyl acetate (EVA).

The back support plate and the frame are designed to support the entire photovoltaic collector and for its attachment to a support structure. The back support plate is for example made of glass or of polyvinyl fluoride (PVF). The frame is made for example of metal, in particular aluminum

The photovoltaic collector is fabricated, for example, by providing the protective front plate, the encapsulation layers and the supporting back plate, then forming the assembly comprising the photovoltaic cells sandwiched between the encapsulation layers, then adding the front protection plate and the back support plate, and securing them inside the frame.

It is desirable to be able to provide photovoltaic collectors which are efficient, reliable, easy to use and which can be obtained at low cost.

To this end, the invention provides a method of manufacturing a photovoltaic collector configured to convert solar radiation into electrical energy, the photovoltaic collector comprising at least one photovoltaic cell, each photovoltaic cell being encapsulated in an encapsulation substrate, the manufacturing process comprising the production of the encapsulation substrate by shaping at least one encapsulation material in the liquid state on each photovoltaic cell. The shaping of an encapsulation substrate in the liquid state enables the encapsulation substrate to be easily formed into the desired shape.

Further, shaping of a liquid encapsulation substrate can be accomplished easily, inexpensively and on a large scale. The shaping of an encapsulation substrate in the liquid state is carried out, for example, by injection molding, by rotational molding and / or by extrusion molding.

The shaping of an encapsulation substrate in the liquid state can also make it possible to arrange the photovoltaic cells along a non-planar surface, for example a concave surface or a convex surface, to improve the efficiency of photovoltaic collectors. converting solar radiation into electricity.

According to particular embodiments, the manufacturing process comprises one or more of the following optional characteristics, taken in isolation or in any technically possible combination:

- it includes the shaping of a said encapsulation material by rotational molding;

- shaping includes placing each photovoltaic cell in a rotational molding mold, introducing said encapsulating material into the rotational molding mold, and molding this encapsulating material into the rotational molding mold;

- It comprises the introduction of a first encapsulation material into the rotomolding mold and the molding of this first encapsulation material in the liquid state in the rotomoulding mold with at least partial solidification of this first material of encapsulation, opening the rotational molding mold, introducing each photovoltaic cell into the rotational molding mold, introducing a second encapsulating material into the rotational molding mold, and molding this second encapsulating material in the liquid state in the rotational molding mold and on each photovoltaic cell;

- the first encapsulating material and the second encapsulating material are identical;

- at least one said encapsulation material is shaped on each photovoltaic cell by injection molding;

- at least one said encapsulation material is shaped on each photovoltaic cell by extrusion molding; and

- each encapsulation material is shaped on at least one connection element configured to electrically connect several photovoltaic cells between them and / or to electrically connect each encapsulated photovoltaic cell to a connection box for the electrical connection of the photovoltaic collector to a power grid or load. The invention also relates to a photovoltaic collector comprising an encapsulation substrate and at least one photovoltaic cell, each photovoltaic cell being encapsulated in the encapsulation substrate, the encapsulation substrate being at least partly overmolded on each photovoltaic cell.

The invention and its advantages will be better understood on reading the description which follows, given solely by way of non-limiting example, and made with reference to the accompanying drawings, in which:

- [Fig 1] Figure 1 is a schematic sectional view of a photovoltaic collector;

- [Fig 2] Figure 2 is a schematic sectional view of a rotational molding mold during a molding step of a first encapsulation material;

- [Fig 3] Figure 3 is a schematic sectional view of the rotational molding of Figure 2 during a step of introducing photovoltaic cells;

- [Fig 4] Figure 4 is a schematic sectional view of the rotational molding of Figure 2 during a molding step of a second encapsulation material on the first encapsulation material and the photovoltaic cells;

- [Fig 5] Figure 5 is a schematic sectional view of an injection molding mold during a molding step of a first encapsulating material;

- [Fig 6] Figure 6 is a schematic sectional view of an injection molding mold for molding a second encapsulation material onto the first encapsulation material and the photovoltaic cells;

- [Fig 7] Figure 7 is a schematic view of a molding step of a first encapsulation material by extrusion molding on the photovoltaic cells; and

- [Fig 8] Figure 8 is a schematic view of a molding step of a second encapsulation material by extrusion molding on the first encapsulation material and the photovoltaic cells.

The photovoltaic collector 2 (or photovoltaic panel) shown in Figure 1 is configured to receive solar radiation S and convert it into electrical energy.

The photovoltaic collector 2 comprises photovoltaic cells 4 and connection elements 6 encapsulated in an encapsulation substrate 8.

The encapsulation substrate 8 surrounds the photovoltaic cells 4. Each photovoltaic cell 4 receives solar radiation S through the encapsulation substrate 8.

Each photovoltaic cell 4 is configured to convert solar radiation S into electrical energy. The connection elements 6 are configured for the interconnection of the photovoltaic cells 4 and for the connection of the cells photovoltaic 4 to a connection box 10 of the photovoltaic collector 2 making it possible to electrically connect the photovoltaic collector 2 to an electrical network or a load.

The photovoltaic collector 2 has a front surface 2A intended to receive solar radiation for its conversion into electrical energy.

Hereinafter, the terms "front" and "rear" are understood by reference to the front surface 2A intended to receive solar radiation and to the opposite rear surface 2B of the photovoltaic collector 2.

The encapsulation substrate 8 comprises for example two encapsulation layers 12 sandwiching the photovoltaic cells 4 and the connection elements 6 connecting the photovoltaic cells 4 together.

The encapsulation substrate 8 preferably comprises a front encapsulation layer 12 and a rear encapsulation layer 12, the photovoltaic cells 4 and the connection elements 6 connecting the photovoltaic cells 4 to each other being located between the encapsulation layer 12 front and the encapsulation layer 12 rear.

The encapsulation substrate 8 defines the front protective layer of the photovoltaic collector 2. Ensuring the protection of the photovoltaic collector 2, and in particular the photovoltaic cells 4, against bad weather.

The encapsulation substrate 8 defines in particular the front surface 2A of the photovoltaic collector 2, intended to receive solar radiation.

The photovoltaic collector 2 does not have a protective front plate separate from the encapsulation substrate 8 and located in front of the photovoltaic cells 4, in particular a protective glass plate

More specifically here, the encapsulation layer 12 before the encapsulation substrate 8 defines the front protective layer of the photovoltaic collector 2.

The encapsulation layer 12 before the encapsulation substrate 8 defines in particular the front surface 2A of the photovoltaic collector 2 intended to receive solar radiation.

The encapsulation substrate 8 defines the back support layer of the photovoltaic collector 2. The photovoltaic collector 2 does not have a back support plate separate from the encapsulation substrate 8 and located behind the photovoltaic cells 4.

More particularly here, the rear encapsulation layer 12 of the protective substrate 8 defines the rear support layer of the photovoltaic collector 2.

In operation, the photovoltaic collector 2 is arranged so as to receive solar radiation S on its front face 2A, this solar radiation S reaching the photovoltaic cells 4 through the encapsulation substrate 8, in particular through the encapsulation layer 12 before, and being converted into electrical energy by each photovoltaic cell 4.

The electrical energy thus generated is transmitted, in particular via the connection elements 6, to the connection box 10, for example to be sent to an electrical network or to supply a load connected to the connection box 10.

According to a method of manufacturing the photovoltaic collector 2, the encapsulation substrate 8 is produced by forming in the liquid state at least one encapsulation material on each photo voltaic cell 4. The encapsulation substrate is thus at least partly overmolded on the photovoltaic cells 4.

In an exemplary implementation, the encapsulation substrate 8 is formed by rotational molding also called "rotational molding" or "rotary molding".

Generally speaking, rotational molding comprises introducing an encapsulating material into a rotational molding mold and heating and rotating the rotational molding mold around an axis of rotation or several distinct axes of rotation, in in particular two distinct axes of rotation, so that the encapsulation material, brought and / or maintained in the liquid state due to the heating, is distributed inside the rotational molding due to the rotation of the rotational molding .

The rotomolding mold is then cooled passively (ie while awaiting its cooling in ambient air) or actively (for example using a forced air flow or by circulating a cooling liquid in the walls of the molds) to allow solidification of the encapsulating material before opening the rotomolding mold.

The encapsulating material can be introduced into the rotomolding mold in a powder state or in a liquid state. Heating the mold makes it possible to bring the encapsulation material introduced in powder form to the liquid state and to maintain the encapsulation material in the liquid state to allow the distribution of the encapsulation material in the rotomolding mold. during the rotation of the latter.

Molding the encapsulating material in the rotational molding includes heating the mold and rotating the mold around one or more axes of rotation.

It is possible to manufacture several superimposed layers by implementing a rotational molding process with successive moldings of several molding materials in the same rotational molding mold.

In one embodiment of the method of manufacturing the photovoltaic collector 2 illustrated in Figures 2 to 4, the manufacturing method comprises: - the introduction of a first encapsulation material M1 into a rotomolding mold 14 and the molding of this first encapsulation material M1 in the liquid state in the rotational molding 14 (Figure 2),

- at least partial solidification of this first M1 encapsulation material,

- opening the rotational molding 14 and introducing each photovoltaic cell 4, and preferably each connecting element 6, into the rotational molding 14 (Figure 3), then

- the introduction of a second encapsulation material M2 into the rotational molding mold 14, and the molding of this second encapsulating material M2 into the rotational molding mold, in the liquid state and on the photovoltaic cells 4, and preferably the connection elements 6 (Figure 4).

The manufacturing process then comprises of course the sufficient solidification of the first encapsulation material M1 and of the second encapsulation material M2 before the demolding of the assembly formed by the photovoltaic cells 4, and where appropriate the connection elements 6, encapsulated in the encapsulation substrate 8 formed by the first encapsulation material M1 and the second encapsulation material M2.

During rotational molding, the rotational molding mold 14 is for example driven in rotation about an axis of rotation parallel to the axis X of the orthogonal reference mark shown in Figures 2 to 4 and / or in rotation about an axis of rotation parallel to the Y axis of the orthogonal coordinate system.

During the introduction of the photovoltaic cells 4, each photovoltaic cell 4 is preferably disposed on a surface of the first encapsulation material M1 at least partially solidified.

After the second overmolding material M2 has been molded on the photovoltaic cells 4, the photovoltaic cells 4 are taken between the first overmolding material M1 and the second overmolding material M2.,

In one embodiment, when the encapsulation substrate 8 comprises a front encapsulation layer 12 and a rear encapsulation layer 12 sandwiching the photovoltaic cells, the rotational molding is for example carried out so that the first material encapsulation M1 and the second encapsulation material M2 each form a respective layer of the front encapsulation layer 12 and the rear encapsulation layer 12.

Advantageously, the first encapsulation material M1 and the second encapsulation material M2 come into contact and bond with each other during the molding of the second encapsulation material M2. In other words, the second material encapsulation M2 is at least partially overmolded on the first encapsulation material M1.

When the manufacturing process uses a first M1 encapsulation material and a second M2 encapsulation material, it is possible that the first M1 encapsulation material and the second M2 encapsulation material are the same or different.

In one embodiment, the first encapsulation material M1 and the second encapsulation material M2 are identical. This makes it possible to obtain good cohesion of the first encapsulation material M1 and the second encapsulation material M2 molded in part on the first encapsulation material M1.

In one embodiment, the first encapsulation material M1 and the second encapsulation material M2 are different. The use of a first M1 encapsulation material and a second M2 encapsulation material allows the use of encapsulation materials having different properties, in particular different optical and / or mechanical properties.

Each encapsulation material can for example be chosen depending on whether it forms the front encapsulation layer 12, which must in particular provide protection against bad weather and be transparent to allow the passage of solar radiation S through it, or the rear encapsulation layer 12 which must possibly support the photovoltaic collector 2.

Preferably, the first M1 encapsulation material and the second M2 encapsulation material M2 are chosen with respect to each other to have good cohesive properties between them when one is molded on the other.

Preferably, each encapsulation material molded by rotational molding to obtain the encapsulation substrate 8 is chosen from: a low density polyethylene (LDPE), a high density polyethylene (HDPE), a polypropylene (PP) and an ethylene acetate. vinyl (EVA).

These materials exhibit good rheological behavior suitable for rotational molding, and in particular homogeneous coalescence during rotational molding, without material front.

In particular, low density or high density polyethylene shaped by rotational molding can have the following advantages: impact resistance, abrasion resistance, adjustable rigidity (flexible or rigid), chemical inertness (ability to resist certain attacks, in particular particularly from chemical or electrochemical attacks) and electrical insulation. Polypropylene formed by rotational molding can have the following advantages: high rigidity, impact resistance and resistance to high temperatures, in particular to temperatures above 100 ° C, see 140 ° C, and chemical inertness.

It is possible that the encapsulating substrate 8 is at least in part formed by injection molding.

In one embodiment of the manufacturing process, at least one encapsulation material is shaped in the liquid state on each photovoltaic cell 4 by injection molding.

In an injection molding process, an encapsulating material is injected in a liquid state into a closed injection molding mold so as to take the shape of the mold cavity of the mold, and then after cooling and solidification of the material encapsulation, the injection molding mold is opened to demold the part thus obtained.

In a method of manufacturing a photovoltaic collector 2, it is possible to position photovoltaic cells 4, and preferably connecting elements 6, in an open injection molding mold, to close the injection molding mold, d 'injecting an encapsulating material in the liquid state into the closed injection molding mold for shaping the encapsulating material in a liquid state into the injection molding mold with the encapsulating material being overmolded on photovoltaic cells 4.

Thus, the encapsulation substrate is at least partially overmolded on the photovoltaic cells.

In one embodiment illustrated in Figures 5 and 6, the manufacturing process comprises:

- injection molding of a first encapsulation material M1 in a first injection molding mold 16 (Figure 5),

- the positioning of the photovoltaic cells 4, and preferably of the connection elements 6, on the first injection-molded M1 encapsulation material (Figure 6),

- the positioning of the intermediate part (first encapsulation material M1 shaped and photovoltaic cells 4) thus obtained in a second injection molding mold 18, and the injection molding of a second encapsulation material M2 in the second mold 18, and overmolding the intermediate part, in particular the photovoltaic cells 4, and preferably the connection elements 6, and the first encapsulation material M1 shaped during the first injection molding.

Advantageously, in one embodiment of the manufacturing process by injection molding with two molding materials, the first material encapsulation M1 and the second encapsulation material M2 each define a respective layer among a front encapsulation layer 12 and the rear encapsulation layer 12 of the encapsulation substrate 8.

As before for rotational molding, the first M1 encapsulation material and the second M2 encapsulation material used for injection molding may be the same or different, with the same or similar advantages.

Preferably, each encapsulation material molded by injection molding to obtain the encapsulation substrate 8 is selected from: a low density polyethylene (LDPE), a high density polyethylene (HDPE), a polypropylene (PP) and an ethylene. vinyl acetate (EVA).

In the case of injection molding, these materials provide the same advantages as for rotational molding, in addition to high fluidity, which facilitates injection, and a fast recrystallization rate.

It is possible that the encapsulating substrate 8 is at least in part formed by extrusion molding.

Thus, in an exemplary implementation, the encapsulation substrate 8 is at least partly obtained by extrusion molding.

In an exemplary implementation, the encapsulation substrate 8 is at least in part obtained by extrusion molding of at least one encapsulation material on each photovoltaic cell.

In an exemplary implementation of the manufacturing method, the encapsulation substrate 8 is at least partly obtained by extrusion molding of a first encapsulation material M1 and the extrusion molding of a second encapsulation material M2 on the photovoltaic cells 4, and preferably the connection elements 6.

As illustrated in Figures 7 and 8, the extrusion molding of a material is carried out by means of an extruder 20 making it possible to force the material in the liquid state through an outlet opening 22 making it possible to obtain the desired shape. for the material.

For the extrusion molding of an encapsulating material on the photovoltaic cells 4, the photovoltaic cells 4 are moved relative to the extruder 20 so that the encapsulating material is applied to the photovoltaic cells 4 at the outlet of. the extruder 20, and thus shaped in the liquid state on the photovoltaic cells 4.

In an exemplary implementation, a first encapsulation material M1 and a second encapsulation material M2 are for example molded by extrusion so that each of the first encapsulation material M1 and of the second encapsulation material M2 form two layers sandwiching the photovoltaic cells 4.

In particular, the first encapsulation material M1 and the second encapsulation material M2 form, for example, a respective layer of a front encapsulation layer 12 and a rear encapsulation layer 12 of an encapsulation substrate 8.

In an exemplary implementation, the first encapsulation material M1 and the second encapsulation material M2 are extrusion molded sequentially.

For example, the first encapsulation material is extrusion molded on the photovoltaic cells 4 so that the first encapsulation material M1 forms a layer on one face of which the photovoltaic cells are located (Figure 7), then the second material encapsulation M2 is extrusion molded on said face of the layer formed by the first encapsulation material M1 (Figure 8).

Thus, the photovoltaic cells 4 are found sandwiched between a layer resulting from the extrusion molding of the first encapsulation material M1 and a layer resulting from the molding by extrusion of the second encapsulation material M2.

The extrusion molding of the first M1 encapsulating material and the second M2 encapsulating material can be performed with the same extruder 20 as shown in Figures 7 and 8, or with separate extruders.

In another exemplary implementation, the extrusion molding of the first encapsulation material M1 and the extrusion molding of the second encapsulation material M2 are carried out simultaneously, for example each on a respective face of a set of photovoltaic cells. 7.

As with rotational molding and injection molding, the first encapsulating material M1 and the second encapsulating material M2 may be the same or different with the same advantages as previously stated or similar advantages.

Preferably, each encapsulation material molded by extrusion molding to obtain the encapsulation substrate 8 is chosen from the materials already mentioned above for rotational molding and injection molding: a low density polyethylene (LDPE), a polyethylene high density (PEFID), polypropylene (PP) or ethylene vinyl acetate (EVA).

The same advantages as above are sought. In addition, preferably, the material here is chosen with a relatively high viscosity. Thanks to the invention, it is possible to easily obtain a photovoltaic collector 2 with a desired shape. For reasons of simplification, the photovoltaic collector 2 is shown in Figures 1 to 8 with a generally planar shape, but the molding of at least part of the substrate on the photovoltaic cells 4 allows different shapes, in particular a curved front surface, in particular concave or convex, the photovoltaic cells 4 being arranged along this curved surface. The shaping of an encapsulation substrate in the liquid state can furthermore be carried out easily, inexpensively and on a large scale.

The invention is not limited to the embodiments described and illustrated in Figures 1 to 8. Other embodiments can be envisaged.

For example, it is possible to combine different molding techniques to obtain the encapsulation substrate.

Thus, in an exemplary implementation, the encapsulation substrate is partly produced by rotational molding, partly produced by injection molding and / or partly produced by extrusion molding.

In particular, in an exemplary implementation, the encapsulation substrate is obtained by molding a first encapsulation material M1 using a first molding technique chosen from rotational molding, injection molding and extrusion molding, and by molding a second encapsulation material M2 using a second molding technique distinct from the first molding technique, selected from rotational molding, injection molding and extrusion molding.

At least one of the first encapsulation material M1 and the second encapsulation material M2 is molded by being shaped in the liquid state on the photovoltaic cells 4. It is thus overmolded on the photovoltaic cells 4.

Preferably, the photovoltaic cells 4 are sandwiched between the first encapsulation material M1 and the second encapsulation material M2, defining for example a front encapsulation layer 12 and a rear encapsulation layer 12 of the substrate. encapsulation 8.

Furthermore, it is possible to provide the photovoltaic collector with a structural frame extending along peripheral edges of the encapsulation substrate 8 encapsulating the photovoltaic cells.

The frame can be made of metal or plastic.

The frame can be attached to the encapsulation substrate 8, for example by being formed of frame elements assembled together around the encapsulation substrate.

Alternatively, the frame can be overmolded on the encapsulation substrate 8, for example by injection molding or by rotational molding, in particular on the edges. peripherals of the encapsulation substrate 8. In this case, the frame is for example made of plastic.

Claims

1. A method of manufacturing a photovoltaic collector (2) configured to convert solar radiation into electrical energy, the photovoltaic collector (2) comprising at least one photovoltaic cell (4), each photovoltaic cell (4) being encapsulated in a substrate encapsulation (8), the manufacturing process comprising the production of the encapsulation substrate (8) by shaping at least one encapsulation material (M1, M2) in the liquid state on each photovoltaic cell ( 4).

2. The manufacturing method according to claim 1, comprising shaping said encapsulation material by rotational molding.

3. The manufacturing method according to claim 2, wherein the shaping comprises the arrangement of each photovoltaic cell (4) in a rotational molding mold, the introduction of said encapsulating material (4) into the mold. rotational molding, and the molding of this encapsulating material in the rotational molding mold.

4. The manufacturing method according to claim 2, comprising the introduction of a first encapsulation material (M1) in the rotomolding mold and the molding of this first encapsulation material (M1) in the liquid state in the mold. rotomolding mold with at least partial solidification of this first encapsulation material (M1), opening of the rotational molding mold, introduction of each photovoltaic cell (4) into the rotational molding mold, introduction of a second encapsulation material (M2) in the rotomolding mold, and the molding of this second encapsulation material in the liquid state in the rotomoulding mold and on each photovoltaic cell (4).

5. The manufacturing method according to claim 4, wherein the first encapsulation material (M1) and the second encapsulation material (M2) are identical.

6. The manufacturing method according to any one of the preceding claims, wherein at least one said encapsulating material is shaped on each photovoltaic cell (4) by injection molding.

7. The manufacturing method according to any one of the preceding claims, wherein at least one said encapsulating material is shaped on each photovoltaic cell (4) by extrusion molding.

8. The manufacturing method according to any one of the preceding claims, wherein each encapsulation material is shaped on at least one connection element (6) configured to electrically connect several photovoltaic cells (4) between them and / or for electrically connecting each encapsulated photo voltaic cell (4) to a connection box (10) for the electrical connection of the photovoltaic collector (2) to an electrical network or a load.

9. Photovoltaic collector comprising an encapsulation substrate (8) and at least one photovoltaic cell (4), each photovoltaic cell being encapsulated in the encapsulation substrate (8), the encapsulation substrate (8) being at less partially overmolded on each photo voltaic cell (4).