ITMI20130152A1 - WINDOW AND PHOTOVOLTAIC KIT FOR INFRASTRUCTURE - Google Patents

Description

DESCRIPTION

Attached to a patent application for an INDUSTRIAL INVENTION PATENT entitled:

"WINDOW AND PHOTOVOLTAIC KIT FOR INFRASTRUCTURE"

FIELD OF THE TROVATO

The present invention relates to a window and a photovoltaic kit for infrastructures. The window and the kit are mainly intended for use in the building field and are suitable for use on any new or existing construction which requires a window together with an electricity production system.

STATE OF THE ART

As is known, the use of photovoltaic panels for the production of electricity starting from the conversion of solar energy is increasingly widespread today. There are several tools and techniques used to enable this production with the aim of maximizing yield while taking into account other design parameters, including for example the aesthetic and environmental impact. In particular, the construction of windows for infrastructures with integrated photovoltaic panels is known today. These windows include a containment frame (external frame of the window) which is fixed, removably or immovably, to a framework of an infrastructure. The containment frame engages inside a first glass and a photovoltaic panel which are spaced apart: the latter together with the containment frame define a double glazing. Generally, the photovoltaic panel is placed in such a way that, during a closed condition of the window, it defines the front portion facing outwards (the photovoltaic panel essentially acts as a front glass).

The integration of photovoltaic panels on windows allows the latter to provide solar shading and at the same time exploit the radiation for energy production.

Although the solutions known today are able to guarantee solar shading and energy production, these solutions are not without drawbacks. In particular, the use of traditional solar panels considerably constrains, both in terms of size and shape, the photovoltaic windows that can be created. In addition, the use of standard photovoltaic panels for the construction of photovoltaic windows significantly affects the overall weight of the latter. The high weight of the windows makes it difficult to assemble / disassemble the latter and also, in the case of movable (rolling and / or sliding) windows, structurally burdens the supporting elements of the windows themselves.

The standard photovoltaic panels also have a poor transparency which does not allow the window the correct passage of light.

PURPOSE OF THE FIND

The aim of the present invention is therefore to substantially solve at least one of the drawbacks and / or limitations of the previous solutions.

A first objective of the invention is to provide a window that is flexible in terms of construction, or that has no size and / or shape limits.

A further main purpose of the invention is to provide a light photovoltaic window which can be easily assembled and disassembled and which, in the case of movable windows (rotating and / or sliding windows), allows to minimize the load in correspondence with the elements. support of the window itself.

A further objective of the invention is to provide a window capable of providing proper solar shading and at the same time favoring the passage of natural light.

A further purpose of the invention is to provide an extremely efficient window in terms of electricity production.

One or more of the objects described above and which will appear better in the course of the following description are substantially achieved by a window and a photovoltaic kit in accordance with one or more of the appended claims.

SUMMARY

Aspects of the invention are described below.

In a 1st window aspect (1) it includes:

> at least one frame (2) defining a closed external profile,

> at least a first glass (3) perimeter engaged to the frame (2) inside the closed external profile of the latter,

> at least a second glass (4) perimetrically engaged to the frame (2) inside the external profile closed and spaced from said first glass (3), said frame (2), said first glass (3) and said second glass (4 ) defining a housing compartment (5) with a substantially closed volume, characterized in that said window (1) comprises at least one photovoltaic thin film (6) arranged inside the housing compartment (5), said photovoltaic thin film (6) ) comprising at least two electrical connectors (7) configured to contact at least one conductor (8) external to said housing compartment (5) to establish an electrical connection between said thin photovoltaic film (6) and at least one user.

In a 2nd aspect in accordance with the 1st aspect the photovoltaic thin film (6) is bonded to said first and / or second glass (3; 4).

In a 3rd aspect in accordance with any of the preceding aspects, the photovoltaic thin film (6) is in cohesion with said first or second glass (3; 4) and at least partially covers an extension surface of the glass.

In a 4th aspect in accordance with the 1st or 2nd aspect, the photovoltaic thin film (6) contacts the first and the second glass (3; 4) to define, according to a cross section of the window (1), a substantially sinusoidal.

In a 5th aspect in accordance with any of the preceding aspects, the photovoltaic thin film (6) has a thickness, measured transversely to a prevailing development plane of the film (6) itself, comprised between 700 nm and 5000 nm, in particular between 800 nm and 2000 nm, even more particularly between 1100 nm and 1400 nm.

In a 6th aspect in accordance with any of the preceding aspects, the distance between the first and the second glass (3; 4) is greater than 10 mm, in particular between 10 mm and 50 mm.

In a 7th aspect in accordance with any of the preceding aspects, the photovoltaic thin wire (6) is configured to generate a direct current at the ends of the electrical connectors (7), called window (1) comprising at least one inverter (10) engaged in the frame (2) and configured to connect to the electrical connectors (7) of at least one photovoltaic thin film (6) to receive the direct electric current generated by the latter, said inverter (10) being configured to convert the incoming direct current from said photovoltaic thin film (6) in alternating current.

In an 8th aspect in accordance with the previous aspect, the window comprises at least one pair of output contacts (11) electrically connected to the inverter (10) and engaged to the frame (2), said output contacts (11) being configured to electrically connect the inverter (10) to at least one user and / or a storage unit external to said window (1).

In a 9th aspect in accordance with any of the preceding aspects, the housing compartment (5) defines a closed volume under vacuum or containing at least one inert gas.

In a 10th aspect there is a photovoltaic kit (13) comprising:

> at least one frame (14) able to be stably bound to the inside of a recess of an infrastructure and able to define the perimeter of said recess, the frame (14) includes at least one engagement element (15) arranged in correspondence of at least one side edge of the frame (14) and at least one pair of contact means (22) arranged on the same side on which said engagement element (15) is arranged,

> at least one window (1), in accordance with any one of the preceding claims, comprising at least one engagement element (17) adapted to cooperate with the engagement element (15) of the frame (14) so that the window (1) is movably constrained in correspondence with at least one edge of said frame (15), the electrical connectors (7) of the photovoltaic thin film (6) of the window (1) being electrically connected to the electrical connectors (16) of the frame (14).

In an 11th aspect in accordance with the previous aspect, the output contacts (11) of the inverter (10) are electrically connected with the contact means (22) of the frame (14) to receive the alternating current at the output. from this inverter (10).

In a 12th aspect in accordance with the 11th or 12th aspect, the engagement elements (15; 17) respectively of the frame (14) and of the window (1) are designed to define a hinge type constraint, window (1) being able to rotate around the edge of the frame on which said engagement element (15) is present.

In a 13th aspect in accordance with the previous aspect the kit (13) comprises two windows (1), in accordance with any one of the 1st to 9th aspects, each window (1) being hinged at lateral edges of the frame (14) opposite each other, said windows (1) being configured to arrange themselves in a moving condition in which the latter are movable relative to each other and being also configured to arrange themselves in a closed condition in the which the latter are linked together to prevent the passage from said framework (14).

In a 14th aspect in accordance with the 10th or 11th aspect, the engagement elements (15; 17) respectively of the frame (14) and of the window (1) are able to define a runner type constraint, called window (1) being able to translate along at least one edge of the frame (14) on which said engagement element (15) is present to define a sliding window.

In a 15th aspect a process is provided for the realization of a window (1), according to any one of the aspects from the 1st to the 9th, comprising the following steps:

> preparing at least said first and second glass (3; 4);

> applying the photovoltaic thin film (6) to at least a portion of said first and / or second glass (3; 4);

> engage the first glass (3), the second glass (4) and the spacer (18) to define a chamber glass delimiting the housing compartment inside which there is the thin photovoltaic film (6); > cover the perimeter of the double glazing with the frame (2).

In a 16th aspect in accordance with the previous aspect, the preparation phase of the first and second glass (3; 4) comprises a sub-phase of preparation of a first and second glass sheet, subsequently this sub-phase involves the cutting of said sheets to respectively defining said first and second glass (3; 4), the step of applying the photovoltaic fil (6) is performed before or after the step of cutting said sheets.

BRIEF DESCRIPTION OF THE DRAWINGS

Some embodiments and some aspects of the invention will be described hereinafter with reference to the accompanying drawings, provided for indicative and therefore not limiting purposes only, in which:

Figure 1 is an exploded perspective view of a window according to the present invention according to a first embodiment;

Figure 2 is a perspective view of the window of Figure 1 placed in an assembled condition;

Figure 3 is a detail view of the window of Figures 1 and 2;

Figure 4 is a schematic diagram, according to a cross section, of the window according to the present invention;

> Figure 5 is a schematic, according to a top view, of the window in accordance with the present invention.

DETAILED DESCRIPTION

Window.

With 1, a window for infrastructure (dwelling) using a photovoltaic system for the production of electricity has been indicated overall. This window 1 can be used both as an infrastructure window frame suitable for exposure to the external environment and as a window used as a dividing element for different internal areas of the infrastructure.

From the structural point of view, the window 1 comprises a first glass 3 extending along a prevailing development surface and defining, in a non-limiting way, a rectangular profile. Figures 1 and 2 illustrate, in a non-limiting way, a single embodiment of the first glass 3 defining a rectangular profile; however, the first glass 3 can extend over a substantially flat or curved surface and define, according to a top view, different profiles, for example a square, rhomboid, elliptical or circular profile. window 1 also comprises a spacer 18 suitable for contacting and engaging the first glass 3: the spacer 18 substantially defines a frame suitable for engaging the external profile of the first glass 3. In fact, the spacer 18 defines a perimeter element having a shape substantially equal to the external shape of the first glass 3. In particular, considering the embodiment illustrated in Figures 1 and 2, the spacer 18 defines, in a non-limiting way, a substantially rectangular shape counter-shaped to the shape of the first glass 3.

The spacer 18 also develops along a prevailing development surface parallel to the prevailing development surface of the first glass 3. More in detail, the spacer 18 develops between a first and a second surface 18a, 18b whose distance defines the thickness of the spacer 18: the first glass 3 is in contact with the first surface 18a of the spacer 18.

From the dimensional point of view, it is possible to define a minimum thickness of the spacer 18 which is greater than 10 mm, in particular it includes between 10 mm and 100 mm, even more particularly between 10 mm and 50 mm.

As visible from the exploded view of figure 1, the window 1 also comprises a second glass 4 substantially equal to the first glass 3 and arranged in opposition to the latter with respect to the spacer 18; in particular, the spacer 18 is interposed between the first and the second glass 3, 4 in such a way as to distance the latter to define a housing space 5 (see Figure 3).

The first glass 3 is engaged to the first surface 18a of the frame 18 while the second glass 4 is engaged to the second surface 18b of the frame 18. The minimum distance between the first and the second glass 3, 4 is the thickness of the spacer 18; this distance is, as described above, greater than 10 mm, in particular it comprises between 10 mm and 100 mm, even more particularly between 10 mm and 50 mm. The first glass 3, second glass 4 and frame 18 assembly substantially defines a double glazing.

As can be seen from the accompanying figures, the window 1 further comprises at least one photovoltaic thin film or thin film 6 configured to produce electrical energy to be transmitted to one or more users. The photovoltaic thin film 6 has, but is not limited to, an amorphous technology or with microcrystalline silicon technology and is arranged inside the housing compartment 5 (inside the double glazing). The film 6 includes at least two electrical connectors 7 configured to contact at least one conductor 8, external to said housing compartment 5, to establish an electrical connection between the thin photovoltaic film 6 and at least one user.

The amount of power generated by the film 6 depends on various factors, the most influential are the exposure surface (linked to the extension of the film 6 whose maximum limit depends on the size of the window 1), the transparency, the angle and coordinates of exposure to the sun. Other minor factors can affect the efficiency of film 6 such as: exposure to aggressive atmospheric agents, bad coupling of the inverter or bad coupling of the electrical contacts.

The transparency of the film 6 (consequently of the window 1) can vary with more discretion with respect to the dimensions; the reference parameters are, in addition to the aesthetic aspect, the layout of the individual cells deposited on the thin photovoltaic film 6 and the desired temperature factor. The layout is decided on the basis of the size of the glass and the optimization of the covered surface (the latter depends on the fixtures used and the structure that contains the double glazing).

As far as the temperature is concerned, it is influenced by transparency: the more transparent the film 6, the lower the temperature on its surface with the same exposure to the sun. The temperature is also affected by the presence or absence of inert gas inside the double glazing. In fact, the housing compartment 5 renders the chamber inert in two different ways, with argon if the exposure surface is extended or with vacuum (therefore with the total absence of gas) for smaller surfaces. The vacuuming of the double glazing or the insertion of inert gas inside the chamber guarantees the quality of the photovoltaic film 6 which will not be attacked by atmospheric agents thus avoiding corrosion effects on the deposited surface.

The presence of the gas allows the surface temperature of the film 6 to be distributed, albeit in a mild way, over the entire structure of the double-glazing unit, maintaining a temperature between 30 ° C and 40 ° C, in particular around 37 ° C. If the surface of exposure is limited, the same effect is obtained even without the presence of inert gas inside the chamber.

The angle and coordinates of exposure to the sun affect the power generated and obviously affect the maximum temperature of the film surface 6.

The photovoltaic thin film 6 is bonded to the first and / or second glass 3, 4 and in cohesion with at least one of the latter to at least partially cover an extension surface of the glass.

In the accompanying figures, a condition in which there is only one photovoltaic film 6 in cohesion with the second glass 4 has been represented, in particular, a condition in which the photovoltaic film 6 is in cohesion with the entire surface of the second glass 4.

Alternatively, the window 1 can comprise a photovoltaic film 6 which contacts both the first glass 3 and the second glass 4 to define, according to a cross section of the window 1, a substantially sinusoidal pattern (condition not illustrated in the accompanying figures).

In a further embodiment, not shown in the accompanying figures, the window 1 can comprise at least one thin photovoltaic film 6 in cohesion with each glass of the window and arranged inside a housing compartment 5. As regards the dimensional aspect, the thin photovoltaic film 6 has a thickness, measured transversely to a prevailing development plane of the film 6 itself, between 700 nm and 5000 nm, in particular between 800 nm and 2000 nm, even more particularly between 1100 nm and 1400 nm.

As will be better described below, the photovoltaic thin film 6 does not represent a standard photovoltaic module which is made through a lamination process, but it is represented by a photovoltaic thin film 6 applied to the first and / or second glass.

In fact, the window 1 according to the invention uses a simple glass (first and / or second glass 3 and 4) as front glass with deposition of a photovoltaic thin film or thin film 6; the front and / or rear glass are not standard photovoltaic panels (laminated panel).

Obviously, the possibility of making windows having several housing compartments 5 (for example using triple or quadruple glazing) and engaging, of each of said compartments, at least one thin photovoltaic film 6 is not excluded.

As previously described, the photovoltaic film 6 comprises at least one pair of electrical connectors 7: the photovoltaic thin film 6 is configured to generate direct current at the ends of said electrical connectors 7. The electrical connectors 7 pass through the housing compartment 5 (double glazing) so that this current can be brought out of the housing compartment 5 to power one or more users.

In the embodiment illustrated (see Figure 1), the electrical connectors 7 emerge, in a non-limiting way and in a condition of use of the window 1, along an upper transverse edge of the photovoltaic module 6.

The contacts are purposely built to house a contact strip connected to the photovoltaic film 6 and which is applied by means of a special glue which guarantees its adherence and conductivity over time. To ensure safety and durability of the film 6, at least part of the contact strip, in particular the entire contour of the double glazing, is covered with a covering element, such as a fire-retardant, water-repellent, anti-drying silica paste. This covering element, in a preferential embodiment of the window, covers the entire perimeter of the thin photovoltaic film 6 ensuring complete perimeter coverage of the double-glazing unit (no exposed parts).

The covering element was used in a material with low migratory value which prevents the passage of contaminants towards the thin film 6, ensuring its functionality over time.

As can be seen for example from Figures 1 and 2, the assembly defined as the double glazing is engaged inside a support frame 2 counter-shaped to said double glazing in order to cover the latter perimeter. The frame 2 has a thickness at least equal to or greater than the maximum distance between the two glasses 3, 4, in particular the maximum distance of the double glazing, so as to completely cover the perimeter of the latter.

Advantageously, the frame 2 comprises a first and a second portion 2a, 2b which can be assembled (see for example Figure 2). The first portion 2a defines, in a non-limiting way, the containment body of the double glazing while the second portion 2b defines, in a non-limiting way, a closing element configured to allow the constraint of the double glazing within the first portion 2a.

As clearly visible from Figure 2, the frame has a groove 20 defined inside the thickness of the frame 2, in particular of the first portion 2a, and extending from the conductors 8 connected to the photovoltaic film 6 to an exit area 9 of the window 1 ( shown in figure 2).

In a preferential but non-limiting embodiment illustrated in Figure 2, the conductors 8, respectively connected to the pair of electrical connectors 7 of the film 6, have terminal portions for electrical connection close to each other; in the embodiment of Figure 2, the terminal portions of electrical connection, in a condition of use of the window 1, converge at the centerline of the upper transverse edge of the window. Inside the groove there is an inverter 10 configured to connect to the conductors 8, in particular to the electrical connectors 7 of at least a photovoltaic thin film 6, to receive the continuous electric current generated by the latter; the inverter 10 is configured to convert the direct current arriving from said thin photovoltaic film 6 into alternating current.

Inverter 10 includes at least one pair of output contacts 11 electrically connected to inverter 10; these contacts 11 are able to transfer the alternating current output from said inverter 10 from the latter to the output area of the window 1, then electrically connect the inverter 10 to at least one user and / or a storage unit external to the window 1.

In the preferred embodiment, for example visible in Figure 2, the groove 20 ends, in a non-limiting way, at a longitudinal edge of the window 1; in this way the direct current carried by the connectors 8 at the center line of the upper transverse edge of the frame 2 is transformed into alternating current and sent to a longitudinal edge of the frame 2 itself.

The inverter 10 is in fact integrated with the film 6 and guarantees maximum power transfer from the film 6 to the power line (user / s), controls the dynamic parameters of the film 6 (for example shading, voltage / current variation, temperature variation ), makes the film 6 independent and functional, it can allow, thanks to an integrated Wi-Fi device, the use and control of window 1.

Advantageously, on the groove 20 in correspondence with a seat in which the inverter 10 is engaged, the frame 2 has been provided with a removable plate. The removable plate allows, in the condition of replacement or maintenance of the inverter, a simple and quick intervention. The inverter 10 is configured to support multiple photovoltaic films 6 electrically connected to each other in parallel or in series.

The fact of integrating the inverter 10 inside the frame 2 allows the window 1 the direct input of electricity into the power line, energy obtained from sunlight; thanks to inverter 10 each window 1 is self-sufficient,

To allow the transmission of the electric current generated by the photovoltaic film 6, the output contacts must establish an electrical connection with the utilities arranged outside the window. The structure of the electrical connection varies according to the type of window 1 housed inside the frame or window frame 14 of the built-in wall infrastructure.

A first related embodiment and windows, can be identified by windows of the type comprising at least one hinged door, at a lateral edge of an opening defined on the infrastructure: in this way the windows can rotate with respect to the infrastructure. More in detail, the sash is configured to rotate on a plane which, when the window is used, has a horizontal development. This type of windows includes, at a longitudinal edge, an engagement element 17, such as for example a pin, capable of binding with an engagement element 15 of the infrastructure, such as a seat. In fact, the commitment elements 15, 17 are designed to define a hinge type constraint between the infrastructure window.

On this first type of window 1 described, there are contact means 21, arranged on the same edge of the window 1 on which the engagement element 17 is present. In particular, there are contact means 21 emerging from the frame 2 on the edge of the window hinged to the infrastructure (see the schematic in figure 4).

In a preferential embodiment illustrated in Figure 4, the contact means 21 comprise at least a pair of seats or pins electrically connected with the terminal ends of the output contacts 11 and which are adapted to abut respectively with a pair of pins or locations defined by means of contact 22 of. The coupling between pins and seats of the respective contact means 21 and 22 is able to define an electrical connection between said contact and a hinge-type constraint similar to that defined between the engagement elements of frame 2 and infrastructure (the means of contact 21, fit together with the contact means of the frame 14 following the coupling of the frame 2 of the window with said frame 14). In this condition, even during the opening and handling of the window 1, the pins inserted inside the respective seats can define an electrical connection between the photovoltaic film 6 of the window and the utilities.

The material of the contact means 21 is a particular composite which, in addition to guaranteeing mechanical performance, has a very low electrical resistance which supports currents ranging from 5 Ampere to 20 Ampere, in particular between 10 Ampere and 15 Ampere. Said contact means have a covering element in external plastic material (polymer) suitable for wrapping the contact means and ensuring their electrical insulation towards the outside.

A second related embodiment and windows, can be identified by sliding windows (not shown in the accompanying figures) comprising at least one sliding door within an opening defined on the infrastructure. This type of windows includes, at the transverse edges (in the condition of use of the window at the lower and upper edge), an engagement element 17 designed to be constrained within an infrastructure guide. In fact, the commitment elements are designed to define a shoe type constraint between window 1 and infrastructure.

On this second type of window described, there are contact means 21, arranged on the same transverse edge of the window 1 on which the engagement element 17 is present.

In a preferential embodiment illustrated in Figure 4, the contact means 21 comprise a pair of contacts or a seat electrically connected to the terminal ends of the output contacts 11 and which are adapted to abut respectively with a seat or pair of contacts defined by means of contact 22 of the infrastructure. The coupling between the pair of contacts and the seat of the respective contact means 21 and 22 is designed to define an electrical connection with sliding contacts. In this condition, even during the opening (sliding) of the sash, the sliding contacts are able to define an electrical connection between the photovoltaic film 6 of the window and the utilities.

PHOTOVOLTAIC KIT

The present invention also relates to a photovoltaic kit 13 comprising a frame or window frame 14 designed to be stably constrained within a recess of an infrastructure and designed to define the perimeter of said recess.

The frame 14 includes at least one engagement element 15 arranged at at least one side edge of the frame 14 and at least a pair of contact means 22 arranged on the same side on which the engagement element 15 is arranged.

The kit 13 also comprises at least one window 1 which, as previously described, has at least one engagement element 17 able to cooperate with the engagement element 15 of the frame 14 in such a way that the window 1 is movably constrained in correspondence with at least one edge of the frame 15 (longitudinal edge in the case of a hinged sash window while on the transverse edges in the case of a sliding sash window).

The electrical connectors 7 of the photovoltaic thin film 6 of the window 1 are electrically connected to the contact means 22 of the frame 14.

In particular, the output contacts 11 of the inverter 10 are electrically connected with the contact means 22 of the frame 14 to receive the alternating current output from said inverter 10.

REALIZATION PROCEDURE

The present invention also relates to a method for manufacturing the window 1 which provides for the provision of at least a first and a second glass sheet. The process provides for a step of applying at least one layer of said photovoltaic thin film or thin film 6 on said first and / or second glass plate.

After the application phase of the thin film 6, the first and second slabs are cut to size to define respectively said first and second glass 3, 4.

Subsequently, there is an assembly phase of the double glazing: coupling of the first and second glazing with interposition of the spacer (definition of the housing compartment 5). The double glazing assembly is isolated thanks to the application of the covering element perimeter to the double glazing in such a way as to protect the electrical connectors 7 and isolate the housing compartment 5 from the external environment.

Following the formation of the double glazing, the conductors 8 are applied in such a way that the latter are connected to the electrical connectors of the photovoltaic film 6.

Following the preparation of the double glazing and the application of the covering element, the construction process involves the application of frame 2 around said double glazing. In particular, it provides for the insertion of the double glazing assembly within the perimeter defined by portion 2a. Once the double glazing is housed, the procedure involves inserting the inverter 10 and the output contacts 11 inside the groove 20 of the frame 2. Subsequently, both the second portion 2b of the frame 2 engages with the first portion 2a in such a way to lock said inverter 10 and said output contacts 11 to the frame and allow their protection.

ADVANTAGES OF THE FOUND

The present invention has the following advantages. In particular, the fact of not using a thin film 6 as a photovoltaic device allows the realization of different sizes since the glass, not being a standard photovoltaic panel (laminated panel), can be cut into different sizes and shapes.

In addition to being able to easily manage different dimensions, the fact of not using a standard photovoltaic module as front and / or rear glass allows to minimize the overall weight of the window which is slightly higher than the weight of the frame 2 and glass assembly. room.

This technology also allows you to control the color, i.e. the transparency of the photovoltaic film 6.

The efficient structure of the window allows to maximize the electrical energy production of the film 6. The fact that it is not tied to the size of standard photovoltaic panels, that it is able to control the temperature (overheating) of the double glazing (insertion of inert gas and control of transparency of the window) guarantees the production of electricity to the thin film 6 even with low energy sources such as by means of artificial light.

Furthermore, due to the way the window 1 object of the present invention is structured, it allows the production of electrical energy from both sides of exposure, that is by direct irradiation towards the first glass and / or towards the second glass (production of energy by irradiation both of the internal side on the outside of the window).

As regards the contact means 21, the latter thus configured allow the window 1 all the degrees of constraint of the normal windows (which is not possible with windows using standard photovoltaic modules), i.e. the window 1 can be opened totally or partially. The electric wire is not stressed during the movement of the window 1 this allows it to resist for a long time without wear problems or the risk of breakage. The contact means 21 also allow the opening of tilting windows 1.

The coating of the contact means 21 in plastic material makes said means 21 water resistant, resistant up to temperatures of 120 ° C, completely mobile and electrically insulating.

LEGEND

1 Window

2 Frame

2nd First portion

2b Second portion

3 First glass

4 Second glass

5 Storage compartment

6 Photovoltaic thin film or thin film

7 Electrical connectors

8 Conductor

9 Exit area

10 Inverter

11 Output contacts

13 Photovoltaic kit

14 Frame or window frame

15 Engagement element of the frame 14 17 Engagement element of the window 1

18 Spacer

20 Groove

21 Window Contact Means

22 Contact means of the frame or window frame

Claims (10)

CLAIMS 1. Window (1) comprising: > at least one frame (2) defining a closed external profile, > at least a first glass (3) perimeter engaged to the frame (2) inside the closed external profile of the latter, > at least a second glass (4) perimeter engaged to the frame (2) inside the closed external profile and spaced from said first glass (3), said frame (2), said first glass (3) and said second glass (4) defining a housing compartment (5) with a substantially closed volume, characterized in that said window (1) comprises at least one thin photovoltaic film (6) arranged inside the housing compartment (5), said photovoltaic thin film (6) comprising at least two electrical connectors (7) configured to contact at least one conductor (8) external to said housing compartment (5) to establish an electrical connection between said thin photovoltaic film (6) and at least one user. 2. Window according to claim 1, wherein said photovoltaic thin film (6) is bonded to said first and / or second glass (3; 4). Window according to any one of the preceding claims, in which the photovoltaic thin film (6) is in cohesion with said first or second glass (3; 4) and at least partially covers an extension surface of the glass. 4. Window according to any one of the preceding claims, in which said photovoltaic thin film (6) has a thickness, measured transversely to a prevailing development plane of the film (6) itself, comprised between 700 nm and 5000 nm, in particular between 800 nm and 2000 nm, even more particularly between 1100 nm and 1400 nm, and in which the distance between the first and the second glass (3; 4) is greater than 10 mm, in particular between 10 mm and 50 mm. Window according to any one of the preceding claims, in which said photovoltaic thin film (6) is configured to generate a direct current at the ends of the electrical connectors (7), said window (1) comprising at least one inverter (10) engaged to the frame (2) and configured to connect to the electrical connectors (7) of at least one photovoltaic thin film (6) to receive the direct electric current generated by the latter, said inverter (10) being configured to convert the direct current arriving from said photovoltaic thin film (6) in alternating current. 6. Window according to the preceding claim, in which said window (1) comprises at least one pair of output contacts (11) electrically connected to the inverter (10) and engaged to the frame (2), said output contacts (11) ) being configured to electrically connect the inverter (10) to at least one user and / or a storage unit external to said window (1). Window according to the preceding claim, wherein the housing compartment (5) defines a closed volume under vacuum or containing at least one inert gas. 8. Photovoltaic kit (13) comprising: > at least one frame (14) able to be stably constrained inside a recess of an infrastructure and able to define the perimeter of said recess, the frame (14) comprises at least one engagement element (15) arranged in correspondence of at least one side edge of the frame (14) and at least one pair of contact means (22) arranged on the same side on which said engagement element (15) is arranged, > at least one window (1), according to any one of the preceding claims, comprising at least one engagement element (17) adapted to cooperate with the engagement element (15) of the frame (14) so that the window (1) is movably constrained in correspondence with at least one edge of said frame (15), the electrical connectors (7) of the photovoltaic thin film (6) of the window (1) being electrically connected to the electrical connectors (16) of the frame (14). 9. Process for manufacturing a window (1), according to any one of claims 1 to 8, comprising the following steps:> preparing at least said first and second glass (3; 4); > applying the photovoltaic thin film (6) to at least a portion of said first and / or second glass (3; 4); > engage the first glass (3), the second glass (4) and the spacer (18) to define a double glazing which delimits said housing compartment inside which there is the thin photovoltaic film (6); > cover the perimeter of the double-glazed unit with the frame (2). 10. Process according to the preceding claim, in which the stage of preparation of the first and second glass (3; 4) comprises a sub-stage of preparation of a first and second glass pane, subsequently said sub-stage provides for the cutting of said plates to define respectively said first and second glass (3; 4), the step of applying the photovoltaic wire (6) is performed before or after the step of cutting said sheets.