IT201800003093A1 - Stratiform structure reflecting by solar radiation and method of realization - Google Patents

Description

REFLECTIVE STRATIFORM STRUCTURE FOR SOLAR RADIATION AND METHOD OF

REALIZATION

TECHNICAL FIELD

The present invention relates to the field of solar radiation reflection. In particular, the present invention relates to the field of reflective sheets used in solar plants. Therefore, the present invention relates to a reflective stratiform structure configured so as to reflect incident radiation, a method of forming such a reflective stratiform structure and a solar mirror, with its manufacturing method, comprising such a reflective stratiform structure.

BACKGROUND

Today, for a more sustainable development, there is a widespread need to exploit solar radiation as much as possible for the production of electricity. However, it is equally evident that the concentration of solar energy is relatively low and therefore the concentration of energy is necessary. An example is that of the use of parabolic mirrors designed to concentrate the radiation incident on them towards a solar collector positioned in the focus of the parabola. Another example is that provided by the solar mirrors used in a photovoltaic system to allow the radiation incident between two adjacent rows of photovoltaic panels, which would otherwise be dispersed, to be reflected on them through mirrors in order to be recovered.

Regarding this last example, it should be noted that large photovoltaic systems provide for the positioning of photovoltaic panels with a precise inclination with respect to the ground in order to maximize the radiation captured and, due to the fact that one does not want to somehow obscure two rows successive rows of photovoltaic modules, there will be a predetermined distance between two successive rows of photovoltaic modules. This therefore implies that a part of the solar radiation will affect the space between two adjacent rows of photovoltaic modules. Therefore, thanks to the positioning of these solar mirrors, it is possible to direct this radiation which would otherwise be dispersed towards the adjacent photovoltaic modules.

Similarly, nowadays there is a need to have economical, efficient and long-lasting reflective structures. In fact, with regard to the fact of economy, it is clear that a fundamental problem is that of a reduction in production costs to obtain from plants that are competitive with other energy sources. Furthermore, with regard to efficiency and duration over time, it is clear that, while on the one hand it is necessary that these structures withstand bad weather, humidity and strong thermal changes for a long time, thus requiring a covering layer, on the other hand it is necessary that these structures comprising this covering layer are very transparent to allow the incident radiation to reach the reflecting layer and therefore be reflected as much as possible.

The present invention therefore aims to provide a reflective stratiform structure configured to reflect the incident radiation coming from the upper side with respect to the structure which is at the same time economical, with a high degree of reflectivity and resistant. Furthermore, the present invention comprises a method of forming such a reflective stratiform structure and a solar mirror, with its own manufacturing method, comprising such a reflective stratiform structure.

SUMMARY

The present invention is based on the idea of providing a transparent thermoplastic film placed on top and in direct contact with a reflective layer.

In the context of the present invention, the terms "above", "below", "lower", "upper", "high", "low", "front" and "rear", unless otherwise specified, refer to the location relative of the various layers considering a sectional view of the final architecture of the structure in which the surface facing the sun occupies the highest level.

According to an embodiment of the present invention, a reflective stratiform structure is provided, configured so as to reflect the incident radiation coming from an upper side with respect to the structure, the structure comprises a reflecting layer, preferably metallic, and a first transparent thermoplastic film placed above and at direct contact with the reflective layer so that the incident radiation can pass through the first transparent thermoplastic film and be reflected by the reflective layer. This solution is particularly advantageous as it allows to have a reflecting layer in direct contact with a transparent thermoplastic film placed above it and therefore capable of protecting the reflecting layer from external agents. At the same time, the transparent thermoplastic film allows incident radiation to be transmitted through it.

According to a further embodiment of the present invention, a reflective stratiform structure is provided in which the first transparent thermoplastic film is of polyethylene terephthalate (PET), preferably in amorphous form. As is well known, PET is an electrically insulating material, having a high chemical resistance and resistant over a wide range of temperatures. Therefore, thanks to these properties, and therefore thanks to the use of PET, it is possible to have an excellent insulator for the reflective layer. Moreover, thanks to the characteristics of PET, it is possible to achieve very high molding speeds. In addition, thanks to its amorphous form, PET is a perfectly transparent material capable of transmitting almost all of the radiation incident on it, thus having a very low reflection coefficient.

According to a further embodiment of the present invention, a reflective stratiform structure is provided in which the first thermoplastic film has a thickness between 50 µm and 100 µm, preferably equal to 75 µm. This solution is particularly advantageous as it allows to have a layer capable of effectively isolating the reflecting layer, preventing external agents from interacting with the reflecting layer. Furthermore, the low thickness of the first thermoplastic film allows to have a reflective stratiform structure having a relatively low overall thickness.

According to a further embodiment of the present invention, a reflective stratiform structure is provided in which this structure further comprises a coating layer positioned above and preferably in direct contact with the first thermoplastic film. This solution is particularly advantageous as it allows to have a coating layer capable of further protecting the reflective layer. Furthermore, this coating layer will preferably have a surface pattern which will allow to capture the greatest amount of incident radiation and to convey it effectively towards the reflecting layer.

According to a further embodiment of the present invention, a reflective layered structure is provided in which this reflective layered structure further comprises a second thermoplastic film, preferably polyethylene terephthalate (PET), placed below the reflective layer, in which the second thermoplastic film has a thickness preferably comprised between 75 µm and 350 µm, more preferably equal to 150 µm. This solution is particularly advantageous for three different reasons. The first relates to the fact that having a thermoplastic film placed below the reflecting layer guarantees protection of the reflecting layer against external agents such as atmospheric ones and also guarantees electrical insulation. Furthermore, secondly, having such a thickness guarantees the possibility of having a self-reflecting stratiform structure as this thermoplastic film can also act as a support. Thirdly, as is well known, PET is an electrically insulating material, having a high chemical resistance and resistant over a wide range of temperatures. Therefore, thanks to these properties, it is possible to have an excellent insulator for the reflective layer also from below.

According to a further embodiment of the present invention, a reflective stratiform structure is provided in which the second thermoplastic film is attached to the reflective layer through an adhesive layer having a thickness preferably between 6 µm and 12 µm, more preferably equal to 8 µm. This solution is particularly advantageous as it allows to guarantee a fastening between the two layers. The fixing is guaranteed by a layer having a constant thickness and therefore this layer guarantees the possibility of having a reflective stratiform structure having a constant thickness. In fact, having for example simple glue would involve the risk of having points with more glue and some without, therefore going to have inconsistent thicknesses.

According to a further embodiment of the present invention, a reflective layered structure is provided in which the reflective layered structure further comprises a pressure-sensitive adhesive layer positioned below the second thermoplastic film in order to be able to apply the layered structure to an external body, in which the adhesive layer is preferably in direct contact with the second thermoplastic film. This solution is particularly advantageous as it allows to apply the reflective stratiform structure to an external support layer with extreme ease. In fact, it will be sufficient to simply remove the film covering the pressure-sensitive adhesive layer and apply pressure on the reflective stratiform structure in contact with the support layer to fix the reflective stratiform structure to the support layer.

According to a further embodiment of the present invention, a reflective layered structure is provided in which the reflective layered structure further comprises an amorphous side positioned below the second thermoplastic film in order to be able to apply the layered structure to an external body, in which the amorphous side is preferably in direct contact with the second thermoplastic film. This solution is particularly advantageous as it allows to apply the reflective stratiform structure to an external support layer with extreme ease thanks to a simple heat sealing.

According to a further embodiment of the present invention, a reflective stratiform structure is provided in which the reflective stratiform structure is supplied in a reel. This solution is particularly advantageous as it allows to have a finished product wound on a reel and ready to be applied on any type of surface. Furthermore, thanks to being able to supply this structure in reel, there is the possibility of having very small dimensions and the possibility of having very simple and fast processes for applying this structure to support layers.

According to a further embodiment of the present invention, a solar mirror is provided configured to reflect the light incident thereon towards an external body, wherein the solar mirror comprises a reflective stratiform structure according to an embodiment of the present invention and a support layer placed at the bottom and in direct contact with the reflecting stratiform structure configured in such a way as to support the reflecting stratiform structure and preferably having a thickness between 0.5 mm and 2 mm, more preferably equal to 1.2 mm. This solution is particularly advantageous in that it allows to fix the reflective stratiform structure on a support layer so as to be positioned in a fixed manner and have a predetermined shape guaranteed by the support layer from which it is supported, and preferably to which it is fixed.

According to a further embodiment of the present invention, a solar mirror is provided in which this solar mirror is used as a reflecting mirror to reflect the incident radiation towards a photovoltaic module positioned at a predetermined distance with respect to the solar mirror. This solution is particularly advantageous since it allows to use this reflective stratiform structure to reflect the incident radiation towards a photovoltaic module so as to increase the quantity of energy incident on said photovoltaic module.

According to a further embodiment of the present invention, a solar mirror is provided in which the solar mirror is used as a mirror for parabolic surfaces configured so as to concentrate the incident radiation towards a solar collector. This solution is particularly advantageous as it allows to focus the incident radiation towards a point in which a collector is positioned, which can for example be represented by a photovoltaic panel or by a simple collector in the case of a thermodynamic solar system.

According to a further embodiment of the present invention, a method is provided for forming a reflective stratiform structure configured to reflect the incident radiation coming from an upper side with respect to the structure comprising the following steps:

to. providing a reflective layer, preferably metallic;

b. providing a first thermoplastic film over and in direct contact with the reflective layer so that incident radiation can pass through the first transparent thermoplastic film and be reflected by the reflective layer.

This solution is particularly advantageous as it allows to have a reflecting layer in direct contact with a transparent thermoplastic film placed above it and therefore capable of protecting the reflecting layer from external agents. At the same time, the thermoplastic film allows incident radiation to be transmitted through it.

According to a further embodiment of the present invention, a method is provided which further comprises the following step:

c. providing a second thermoplastic film beneath the reflective layer, wherein the second thermoplastic film is preferably applied via an adhesive layer to the lower surface of the reflective layer.

This solution is particularly advantageous for three different reasons. The first relates to the fact that having a thermoplastic film placed below the reflecting layer guarantees protection of the reflecting layer against external agents such as atmospheric ones and also guarantees electrical insulation. Furthermore, secondly, this layer guarantees the possibility of having a self-reflecting stratiform structure since this thermoplastic film can also act as a support. Thirdly, if this layer is made of PET, as is well known it is an electrically insulating material, having a high chemical resistance and resistant over a wide range of temperatures. Therefore, thanks to these properties, it is possible to have an excellent insulator for the reflective layer also from below.

According to a further embodiment of the present invention, a method is provided which further comprises the following step:

d. providing a coating layer on top of the first thermoplastic film.

This solution is particularly advantageous as it allows to have a coating layer capable of further protecting the reflective layer. Furthermore, this coating layer will preferably have a surface pattern which will allow to capture the greatest amount of incident radiation and to convey it effectively towards the reflecting layer.

According to a further embodiment of the present invention, a method is provided in which the reflective layer is provided on a first thermoplastic film by vacuum thermal evaporation. This solution is particularly advantageous since, through vacuum thermal evaporation, it is possible to have a perfectly homogeneous surface despite the very thin thickness of the layer. In addition, vacuum thermal evaporation is also very advantageous from an economic point of view, thus allowing for low construction costs.

According to a further embodiment of the present invention, a method is provided which further comprises the following step:

And. applying a layer of pressure-sensitive adhesive below the second thermoplastic film so as to be able to apply the layered structure to an external body, in which the adhesive layer is preferably applied in direct contact with the second thermoplastic film.

This solution is particularly advantageous as it allows to apply the reflective stratiform structure to an external support layer with extreme ease. In fact, it will be sufficient to simply remove the film covering the pressure-sensitive adhesive layer and apply pressure on the reflective stratiform structure in contact with the support layer to fix the reflective stratiform structure to the support layer.

According to a further embodiment of the present invention, a method is provided which further comprises the following step:

f. apply a heat-sealable amorphous side on the lower surface of the second thermoplastic film.

This solution is particularly advantageous since it allows to apply this reflective stratiform structure to an external body by means of hot rolling.

According to a further embodiment of the present invention, a method is provided for producing a solar mirror for solar concentrators comprising a reflective layered structure made according to one of the embodiments of the present invention, in which the reflective layered structure is applied to a layer of support, preferably a metal sheet, by means of hot rolling. This solution is particularly advantageous as the application by hot lamination allows for an effective long-lasting fixing of the two layers. In addition, hot rolling allows for a high production speed.

BRIEF DESCRIPTION OF THE FIGURES

The present invention will be described with reference to the attached figures in which the same reference numbers and / or signs indicate the same parts and / or similar and / or corresponding parts of the system.

Figure 1 schematically shows a section of a reflective layered structure according to an embodiment of the present invention;

Figure 2 schematically shows a section of a reflective layered structure positioned on a support layer according to an embodiment of the present invention;

Figure 3 schematically shows a reflective stratiform structure used as a reflecting system for a retrofit type solar system according to an embodiment of the present invention;

Figure 4 schematically shows a reflective stratiform structure used as a parabolic solar concentrator in a thermodynamic solar plant according to an embodiment of the present invention;

Figure 5 schematically shows a reflective stratiform structure used as a photovoltaic concentrator in a photovoltaic system according to an embodiment of the present invention.

DETAILED DESCRIPTION

Hereinafter, the present invention is described with reference to particular embodiments, as illustrated in the attached drawing tables. However, the present invention is not limited to the particular embodiments described in the following detailed description and shown in the figures, but rather the described embodiments merely exemplify the various aspects of the present invention, the purpose of which is defined by the claims. Further modifications and variations of the present invention will appear clear to the man of the trade.

In the present description, by film is meant a layer of thin planar material which is applicable over a surface, preferably flat, and which has a preferably constant thickness along the plane on which it extends. Furthermore, with thermoplastic film we therefore mean a layer of a substance that is thermoplastic and therefore has the property of acquiring plasticity in a reversible form, and therefore moldability, under the action of heat.

Figure 1 schematically shows a reflective stratiform structure 100 which allows to reflect the incident radiation coming from an upper side with respect to this structure 100. The various layers included in this stratiform structure 100 will be described below. However, it should be emphasized that it is clear for the person skilled in the art that some such layers can be omitted or other layers can be added without departing from the scope of the invention which is defined by the attached claims.

In the particular example shown in Figure 1, a transparent thermoplastic film 102 is positioned above and in direct contact with a reflective layer 103 so as to protect the underlying reflective layer 103. It is in fact important to have insulation between the reflective layer and the outside so that external agents, such as humidity, do not deteriorate the reflective layer 103.

Such transparent thermoplastic film described above, used in such film 102, can be for example a PET layer having a thickness for example between 50 µm and 100 µm, in which this thickness is preferably equal to 75 µm. Alternatively, the layer 102 can be a layer of fluorinated film (FEP, PVF, PVDF) or a layer of acrylate film (PMMA). The use of fluorinated or acrylate films is particularly advantageous as these materials are particularly resistant to atmospheric agents.

The reflective layer 103, as will be explained in more detail below, is preferably a metallic layer of aluminum in the case of a retrofit-type solar plant or a metallic layer of silver in the case of a solar concentrator. Said reflective layer 103 has the purpose of reflecting as much incident light as possible. Therefore, thanks to the metallic layer made for example of silver or aluminum, incident light can be reflected, even more than 94% in the case of silver. Said reflective layer 103 has a very thin thickness equal for example to 0.1 µm.

Therefore, the solar radiation incident on this reflective stratiform structure 100 will be able to penetrate through this transparent thermoplastic film 102, be reflected by the reflecting layer 103 and emerge from this structure passing again through this transparent thermoplastic film 102. At this notice, the layer 102 will have a high radiation transmission coefficient in such a way as to allow the transmission of almost all of the radiation incident through it along both directions: both the radiation coming from above and that reflected by the reflecting layer 103 positioned below it.

A layer of transparent protective coating of solidified thermoplastic resin 101 is positioned above the layer 102. The transparent protective coating of solidified thermoplastic resin 101 (hereinafter referred to as "transparent protective coating layer 101") provides greater protection to the reflecting layer 103. This transparent protective coating layer 101 can have either a perfectly smooth surface or a pattern in order to better interact with the light. However, it is important that this transparent protective coating layer 101 also has a high transmission coefficient so as to allow as much incident radiation as possible to be transmitted through it.

Below the reflecting layer 103, in the particular example shown in the figure, a second thermoplastic film 105 is positioned which is applied to the reflecting layer 103 by means of an adhesive layer 104 therefore positioned between the reflecting layer 103 and the second thermoplastic film 105.

This thermoplastic film used in the thermoplastic film 105 can, also in this case, be represented by PET even if in this case it is not necessary that it is a transparent material since, being located behind the reflecting layer, it obviously does not perform the task of reflecting the incident light as occurs instead for the first thermoplastic film 102 described above.

As regards the thicknesses, the second thermoplastic film 105 can have a thickness between 75 µm and 350 µm and is preferably equal to 150 µm. However, this thickness will strongly depend on the application within which this reflective stratiform structure 100 is applied. In the case, for example, in which it is desired to have a structure in its own right, it will be preferable to have a very high thickness of this layer 105, equal for example to 350 µm. If, on the other hand, the reflective stratiform structure 100 is subsequently applied to a support layer, the layer 105 can also have a much lower thickness, equal for example to 75 µm.

The adhesive layer 104 which allows the layer 105 to be fixed to the reflecting layer 103 can have a thickness ranging from 6 µm to 12 µm, preferably equal to 8 µm.

Therefore, as described, the reflective layer 103 will be positioned between two thermoplastic films, such as PET, which thus allow the reflecting layer to be incorporated in a "sandwich" manner, protecting it from external agents. Furthermore, it is clear that, being a thermoplastic film, it is also possible in this way to electrically isolate the reflecting layer, preventing its possible electromagnetic alterations. In fact, the layer 105 will also have the advantage of providing protection against the galvanic corrosion that would occur between the reflecting layer 103 (which as mentioned is preferably made of metal material) and a support layer on which this structure 100 is applied, if the support layer is metallic.

Below this second thermoplastic film 105, in the case in which it is desired to apply the reflective stratiform structure 100 to an external body, it is possible to install a layer of pressure-sensitive adhesive 106 in direct contact with the second thermoplastic film 105. In this thus, by applying a simple pressure on this stratiform structure, it will be possible to apply the structure 100 to an external support. It is clear that, beneath this pressure-sensitive adhesive layer 106, a tear-off coating (not shown) can be applied which can be removed before applying the reflective layered structure 100 to an external element.

Alternatively, the lower side of the second thermoplastic film 105 can be made in such a way that this surface is sealable, for example heat sealable. In fact, amorphous surfaces applicable to stratiform structures, such as the one described here, are known in the state of the art, which allow the structure to be applied to an external body by means of a heat welding.

The stratiform reflective structure 100 described above can be supplied in coils of high length, even for example equal to 1000 m in length. For example, a reel may have a length of the order of 1000 m and a width of the order of 1.5 m.

Figure 2 shows, as previously described, a support layer 200 on which this reflective stratiform structure 100 described above is positioned. Said support layer 200 can preferably have a thickness comprised between 0.5 mm and 2 mm, more preferably equal to 1.2 mm.

The surface of the support layer 200 can have a roughness (Ra) equal to 2 thus allowing to have a fairly rough surface of the support layer 200. The support layer 200 can be made for example of steel or aluminum, on top of which the reflective stratiform structure 100 can be applied.

Figures 3 to 5 show possible applications of the reflective stratiform structure 100 described above.

As shown in Figure 3, the reflective stratiform structure 100 can be applied as a reflecting system for a retrofit type solar system. As is in fact known to the state of the art, due to the optimal inclination of the photovoltaic modules 99 which allows to absorb the greatest possible amount of solar radiation, empty spaces are formed between two adjacent rows of photovoltaic modules 99. These spaces are due to the fact that we want to prevent the possibility that two rows of photovoltaic modules inclined with respect to the ground shadow each other. For this reason, part of the solar radiation will be dispersed and partially absorbed by the ground in correspondence with these empty spaces.

It is therefore necessary to recover this energy, which would otherwise be dispersed, by means of solar mirrors configured to reflect the radiation incident on them towards a photovoltaic module so as to recover at least partially the radiation that would otherwise be dispersed. It is estimated that the increase in energy produced thanks to these mirrors is of the order of 10-15% at a latitude of 23 °.

In the present invention, it has therefore been discovered that it is very advantageous to make such mirrors by means of a reflective stratiform structure 100 in which the reflective layer 103 is placed underneath and in direct contact with a transparent thermoplastic film 102 capable of effectively protecting the reflective layer 103 and to allow almost all of the incident light to penetrate through it.

In this case, given the extent that these mirrors must cover and the relatively low concentration of incident radiation, it will be preferable to make this reflective layer 103 in aluminum allowing for relatively low production costs.

As shown in Figures 4 and 5, this reflective stratiform structure 100 can also be used as a parabolic solar concentrator in a thermodynamic solar system (Figure 4) and as a photovoltaic concentrator in a photovoltaic system (in Figure 5).

In this case, given the high concentration of incident radiation, it will be preferable to make the reflective layer 103 of the reflective stratiform structure 100 in silver having a very high reflection coefficient that allows it to reflect even more than 94% of the incident radiation.

In general, the reflective layered structure 100 can be applied directly on a support layer 200 made for example of metal such as iron or polymeric surfaces.

In the following, the method of manufacturing a reflective stratiform structure 100 according to a particular embodiment of the present invention is described.

As a first step, a first thermoplastic film 102 is provided, such as the one described above, on which a reflective layer 103 is applied. The metallic reflective layer 103 can be applied to the lower surface of the first thermoplastic film 102 by means of vacuum thermal evaporation which allows to obtain a very thin layer thickness and, in spite of this, a perfectly homogeneous surface, thus having a small footprint and low production costs.

Above the first thermoplastic film 102, a transparent protective coating layer 101 is provided in order to protect the underlying layers from external agents, such as humidity. This transparent protective coating layer 101 can have a thickness from 4 µm to 50 µm, and preferably equal to 15 µm.

Below the reflective layer 103, a second thermoplastic film 105 is provided which is applied to the reflective layer 103 by means of a layer of adhesive 104.

Below the second thermoplastic film 105 a layer of pressure-sensitive adhesive 106 can alternatively be provided, so as to be able to apply the reflective stratiform structure 100 to an external body, or the second thermoplastic film 105 can be provided with a lower amorphous side which is sealable, for example heat sealable.

Therefore, there will be two different methods of applying the reflective stratiform structure 100 described above to a support layer 200 located below the structure 100.

In fact, in the case in which the structure comprises a layer of pressure-sensitive adhesive 106, the structure 100 can be applied to the support layer 200 by simply exerting a pressure on the structure 100 against the support layer 200. This solution is preferably applicable in the case in point. which the solar mirror 1000 that will thus be formed is used for concentrators, as shown in figures 4 and 5. The reason is due to the fact that, since the concentrators are normally curved surfaces, it will thus be easier to apply the stratiform structure reflecting 100 to such surfaces.

If, on the other hand, the structure comprises a heat-sealable amorphous lower side, the reflective stratiform structure 100 can be applied to the support layer 200, which as said can be a metal sheet, by means of hot rolling. This solution is preferably applicable in the case in which the solar mirror 1000 that will be formed is used as a reflecting mirror to reflect the incident radiation towards a photovoltaic module positioned at a predetermined distance with respect to said solar mirror 1000. The reason is due to the fact that in these types of mirrors the surfaces are usually flat and therefore hot rolling is advantageous.

Although the present invention has been described with reference to the embodiments described above, it is clear to the person skilled in the art that it is possible to carry out various modifications, variations and improvements of the present invention in light of the teaching described above and within the scope of the attached claims, without departing from the object and scope of the invention.

For example, even if the presence of only one layer of transparent protective coating 101 has been described, it is possible that multiple layers of coating placed one on top of the other are provided. Moreover, even if not specifically described, it is clear that this reflective stratiform structure 100 can be applied in various fields, such as for example the building one. In fact, this structure 100 can be applied for example on the surfaces of buildings to allow the incident light to be reflected and thus have better thermal insulation.

Finally, those areas that are considered to be known by those skilled in the art have not been described to avoid unnecessarily overshadowing the invention described.

Consequently, the invention is not limited to the embodiments described above, but is only limited by the scope of the attached claims.

Claims (17)

CLAIMS 1. Reflective stratiform structure (100) configured so as to reflect the incident radiation coming from an upper side with respect to said structure (100), said structure (100) comprising a reflecting layer (103), preferably metallic, and a first thermoplastic film transparent (102) placed above and in direct contact with said reflective layer (103) so that the incident radiation can pass through said first transparent thermoplastic film (102) and be reflected by said reflective layer (103). 2. Reflective layered structure (100) according to claim 1, wherein said first transparent thermoplastic film (102) is of polyethylene terephthalate (PET). 3. Reflective layered structure (100) according to any one of claims 1 or 2, wherein said first transparent thermoplastic film (102) has a thickness comprised between 50 µm and 100 µm, preferably equal to 75 µm. 4. Reflective layered structure (100) according to any one of claims 1 to 3, further comprising a layer of transparent protective coating (101), positioned above and preferably in direct contact with said first transparent thermoplastic film (102). 5. Reflective layered structure (100) according to any one of claims 1 to 4, further comprising a second thermoplastic film (105), preferably of polyethylene terephthalate (PET), placed below said reflective layer (103), wherein said second thermoplastic film (105) has a thickness preferably between 75 µm and 350 µm, more preferably equal to 150 µm. 6. Reflective layered structure (100) according to claim 5, wherein said second thermoplastic film (105) is attached to said reflective layer (103) through an adhesive layer (104) having a thickness preferably between 6 µm and 12 µm, plus preferably equal to 8 µm. 7. Reflective layered structure (100) according to any one of claims 5 or 6, further comprising a pressure sensitive adhesive layer (106) positioned below said second thermoplastic film (105) in order to be able to apply said layered structure (100) to a body external, in which said adhesive layer (106) is preferably in direct contact with said second thermoplastic film (105). Reflective layered structure (100) according to any one of claims 1 to 7, wherein said layered structure (100) is supplied in a reel. Solar mirror (1000) configured so as to reflect the light incident on it towards an external body, said solar mirror comprising a reflective stratiform structure (100) according to any one of claims 1 to 8 and a support layer (200 ) placed at the bottom and in direct contact with said reflective stratiform structure (100) configured so as to support said reflective stratiform structure (100) and preferably having a thickness between 0.5 mm and 2 mm, more preferably equal to 1.2 mm. 10. Solar mirror according to claim 9, wherein said solar mirror (1000) is used as a reflecting mirror to reflect the incident radiation towards a photovoltaic module positioned at a predetermined distance with respect to said solar mirror (1000). Solar mirror according to claim 9, wherein said solar mirror (1000) is used as a mirror for parabolic surfaces configured to concentrate the incident radiation towards a solar collector. 12. Method for forming a reflective layered structure (100) configured to reflect incident radiation coming from a side higher than said structure (100) comprising the following steps: to. Providing a reflective layer (103), preferably metallic; b. Providing a first transparent thermoplastic film (102) above and in direct contact with said reflective layer (103) so that the incident radiation can pass through said first transparent thermoplastic film (102) and be reflected by said reflective layer (103). The method according to claim 12, further comprising the following step: c. Providing a second thermoplastic film (105) underneath said reflective layer (103), wherein said second thermoplastic film (105) is preferably applied via an adhesive layer (104) to the lower surface of said reflective layer (103). Method according to any one of claims 12 or 13, further comprising the following step: d. Providing a layer of clear protective coating (101) on top of said first clear thermoplastic film (102). Method according to any one of claims 12 to 14, wherein said reflective layer (103) is provided on said first transparent thermoplastic film (102) by vacuum thermal evaporation. Method according to any one of claims 13 to 15, further comprising the following step: And. Apply a layer of pressure-sensitive adhesive (106) below said second thermoplastic film (105) so as to be able to apply said layered structure (100) to an external body, in which said layer of adhesive (106) is preferably applied to direct contact with said second thermoplastic film (105). Method for producing a solar mirror (1000) for solar concentrators comprising a reflective layered structure (100) made according to any one of claims 12 to 16, wherein said reflective layered structure (100) is applied to a support layer ( 200), preferably a metal sheet, by hot rolling.