ITTV20120137A1 - INTEGRATED MULTIFUNCTIONAL SOLAR SYSTEM FOR ENERGY PRODUCTION - Google Patents

Description

DESCRIPTION OF INDUSTRIAL INVENTION

entitled "Multifunctional integrated solar system for energy production"

The present invention relates to a multifunctional integrated solar system for the production of energy

Photovoltaic modules for the production of electricity are known, both traditional and specifically designed to integrate into the roof, such as photovoltaic tiles; modules for the exclusive production of thermal energy, simply called solar modules, are also known; they generally consist of panels to be exposed to solar radiation, which invest an absorbing surface that is in contact with a coil crossed by a heat-carrying fluid, heating it. There are also hybrid solutions, where the same surface is used to convert solar radiation into electricity, exploiting the photovoltaic effect, and to obtain thermal energy deriving from bodies - such as pipes or coils - present on the back of the surface in charge of photovoltaic conversion. .

Moreover, there are also many products at the state of the art for the integration on the roof of the various technological solutions, which prevent rainwater and bad weather from reaching the roof of the building, allowing to avoid the use of waterproofing systems for protect does itself.

In all the above cases, the fixing system used is mostly traditional, that is provided with simple aluminum profiles that act as a guide and support for closing the brackets, using screws and / or bolts.

The purpose of the present invention is to realize a multifunctional solar system characterized by uniformity of fixing solutions between the various technologies and, at the same time, by an assembly and industrial production facilitated by the use of a reduced number of multifunctional components, allowing a great saving from the logistics and production point of view.

Another purpose of the present invention is to realize a very versatile system in terms of technology used, but which allows a high scalability and modularity, while maintaining total integration in the roof, in particular if used in residential buildings, without the need to waterproof the roof. building itself.

The invention also allows to solve typical criticalities of the various technologies, integrating them in an effective and harmonious way with the structure and with the fixing system.

The described invention is particularly advantageous as regards the thermal application, as it allows the use of different technological solutions both for traditional use and in combination with photovoltaics in hybrid systems; an example can be the use of simple aluminum tubes, extruded profiles and rollbond type plates.

These objects and others that will result from the following description are achieved, according to the invention, thanks to a multifunction solar system 1 (FIG. 1) made up of a pair of extruded frames 2 and a pair of head elements 3 (shorter than the previous ones and placed at their ends), which constitute a perimeter within which a glazed body 4 is positioned, or transparent at least partially to solar radiation, in the case of use of technology for obtaining thermal energy, or a photovoltaic laminate 5 if the purpose is to produce electricity. Furthermore, the presence of an extruded shaped profile 6 is provided which acts as a guide and support for fixing the various solutions to the roof.

The system is also characterized by the presence of the aforementioned head elements 3, which in addition to being part of the seat for positioning the glass body 4 or the photovoltaic laminate 5, allow an advantageous and rapid locking with the extruded profile 6 and are hollow at the in order to be able to house electric cables or hydraulic pipes according to the purpose of use of the invention. It is also foreseen the presence of at least one pair of multifunctional accessories 7 housed on the inside of the extruded frames which, used together with the different elements for the conversion of solar radiation, allow the rapid assembly / production of one of the possible photovoltaic, thermal or hybrid configurations. expected.

The present invention is further clarified hereinafter in some of its preferred embodiments reported for purely illustrative and non-limiting purposes with reference to the attached tables of perspective drawings, in which:

FIG.1 shows the invention in a configuration for the exclusive production of photovoltaic electricity, in an exploded view; FIG.2 shows the exploded detail of a multifunctional accessory 7, consisting of base 8 and cap 9;

FIG.3 shows the head element 3 in front view;

FIG.4 shows the head element 3, overturned with respect to the previous figure, with its lower 11 and upper 12 cover, in exploded mode and seen from inside the multifunction solar system;

Figure 5 shows the multifunction solar system 1 and a subsequent head element 3 before the assembly of a through top cover 13 which allows to maintain the impermeability of the cover;

FIG. 6 shows the head element 3 after positioning on the extruded profile 6, first positioning of the locking clip 10, FIG. 7 shows the multifunction solar system with fixing on profile 6 horizontally, without covering the element 3 ;

FIG.8 shows the multifunction solar system from the inside, in a hybrid configuration with horizontal fixing;

FIG.9 shows the invention in a close-up manner, highlighting the coupling area between frames 2 of adjacent systems;

Figure 10 shows the invention with two extruded covers 15 in the pre-assembly position

FIG. 11 shows a pusher 32

Figure 12 shows a pair of tubes 47 held in position by pusher 32, metal bar 37 and multifunctional accessory 7;

- FIG. 13 shows a thermal configuration of the invention, made with an aluminum extrusion held in position by pusher 32, metal bar 37 and multifunctional accessories 7;

- Figures 14, 15 and 16 show the invention in a thermal configuration with a safety system against excessive heat.

- FIG.17 shows the invention in a hybrid configuration with a safety system against excessive heat;

- FIG. 18 shows the invention in the variant with nozzle for cleaning the upper glazed surface;

FIG.19 shows a cover for the head element 3 with integrated protection curtain.

As can be seen from the figures, the system according to the invention consists of at least one pair of extruded frames2, preferably produced in aluminum, which determine the longer sides of the invention, and have lateral protrusions 25 (FIG. 9) suitably shaped in such a way that from the adjacent positioning of several multifunctional solar systems a barrier is formed to prevent bad weather (and in particular rain and snow) from having access to the roof of the building where the system is installed; thanks to this peculiarity, the roof itself does not require waterproofing, constituting an aesthetic and economic advantage for the user. To obtain the protection and integration described above, it is necessary that the opposite frames 2 have different protrusions 25 and that the positioning of the multifunctional solar systems takes place in an appropriate manner, starting in such a way that the element presenting the frame with the protrusion concave towards the the top is installed before its adjacent with the same downwards. Furthermore, the frames are shaped in such a way as to offer a coupling seat14, useful for the positioning of an additional sealing element (optional) for waterproofing, such as an extruded gasket, or for the mechanical bond with covers 15 (FIG.10) which have hook-like projections 26, and which can have multiple functions; for example, if combined with a photovoltaic system, they can be partially transparent to sunlight and colored in order to hide the view of the cells from the outside for aesthetic purposes; alternatively, if used with a solar system for thermal energy, they can be non-transparent to radiation and constitute a screen to be applied manually, which protects the surface that acts as an absorber if the system is not used, preserving its integrity and avoiding the achievement of potentially dangerous temperatures and pressures of the heat transfer fluid, such as in case of stagnation.

The extruded frames 2 are spaced apart by using a pair of short head elements 3 (FIG. 3) which, as a whole, determine a perimeter which represents the maximum size of the multifunction system and which allow the mechanical engagement of the roof. glass window 4 (or photovoltaic laminate 5, depending on the desired function), inside the seat 52 (FIGS. 4 and 9). These short head elements 3 have a plurality of protrusions with hooked ends 16, which allow multiple fixing possibilities with the extruded sections 6, both in vertical configuration (FIG. 6) - i.e. when several multifunction systems are positioned along their length. - that it is horizontal (FIG.7), in the case that several systems are adjacent and contiguous to each other and preferably coupled according to the indications given to maintain the waterproofing of the roof. Furthermore, there are openings 17, with the side open in the opposite direction to the cavity in charge of the glass, which allow the insertion of the absorber elements described below and the advantageous passage of the pipes from the area of absorption of solar radiation to that of distribution 18, obtained in the internal cavity of the short elements.

The head elements 3 (F1G.4), substantially consisting of a hollow parallelepiped body inside, have, in addition to the lower open side 18 for suitable passage of pipes and solar cables, the two partially open short sides 19, with the aim of allowing the electrical or hydraulic connection of several adjacent heads; furthermore, there are a plurality of projections and openings 21 specially made for the rapid locking of lower 11 or upper 12 (or, alternatively, 13) covering components which have hook projections 22, suitable for mechanical bonding with the previous ones; furthermore, in the lower end of the long side opposite to the presence of the extruded frames, further ribs 23, placed orthogonal to the plane from which they derive, which have a hole 24 and are effective for securing the system to the extruded profiles 6, also by means of the use of screws and special nuts, These ribs23, are positioned asymmetrically to the longitudinal axis of the invention, to allow the opposite positioning (visible in FIG. 5) of head elements 3,

The pairs of frames 2 and head elements 3 can be mutually constrained and centered by angular elements inserted in the cavities 51 (FIGS. 4 and 9) and blocked by internal punching as is usually used for the construction of photovoltaic modules, or simply fixed with screws which engage the lateral ends of the head elements 3 with the extruded frames.

In order to further secure the multifunction systems to the profiles 6. clips 10 can be positioned (FIG. 6), made of plastic material and with the shape corresponding to the upper side of the profile 6 itself, which have at least one cylindrical protrusion 27 and are made in such a way as to be able to couple with the hole 24 present in the protrusion 23, constituting a stop for the longitudinal locking of the system. everything is facilitated by the presence of an inclination 28 in the protrusion of the head elements which facilitates the insertion by sliding of the system towards the clip itself (FIGS. 3 and 6). Moreover, these clips can have projections 29 useful for partially locking hydraulic pipes or electric wires, and for this reason they can also be used in other positions of the extruded section, without necessarily constituting a stop for multifunction systems.

As said, the invention is characterized by a quick and versatile fastening system; this is possible thanks to the use of extruded profiles 6 which allow locking with the head elements thanks to the protruding appendages 16. Furthermore, it is possible that the extruded profile 6 is suitably shaped so as to be able to house cables and pipes inside it. service, in order to make the installation work as tidy as ever.

The multifunction solar system is, in its simplest application, a photovoltaic module of reduced dimensions and does not require any further accessory (FIG. 1): in the other possible uses, it is necessary to use pairs of multifunctional accessories 7 (FIG. 2), made up of base 8 and cap 9, which allow multiple functions. The base 8, preferably made of plastic material suitable for high temperature uses (such as solar thermal), such as polyamide with glass fiber charge, is composed of a pair of protrusions 31 made in such a way as to be able to have a slight bending during the assembly inside the extruded frame 2, thanks to the presence of an appropriate preformed curvature, and by a centering and locking pin 33, useful for engagement with a hole 34 (FIG. 1 3) always with the aforementioned frame 2. moreover , is shaped in such a way as to have two hook-like projections 35, useful for locking the absorbers for solar thermal; finally, there are concave seats 36 open on two sides, suitable for containing and locking cylindrical metal bars 37, also thanks to the aid of the cap 9, as shown in FIG. 13.

The cap 9, also produced in plastic material suitable for use, is constrained to the base 8 by means of hooks 38 and relative grips in the base, and has protruding ribs 39 necessary for locking the cylindrical metal bars 37: in this way, after the positioning of the bases 8 in the frames 2 (at least one pair in a corresponding opposite position), it is possible to position the bars 37 and close everything with the caps 9, obtaining the various functions described below. Depending on the desired use, also in combination with other accessories, the bars 37 can be placed in a central or off-axis position: if the position is off the axis, in the corresponding multifunctional accessory placed in the opposing extruded frame, the use of the seat opposite to the axis of the accessory, for obvious reasons of alignment.

The aforementioned metal bars 37 are useful for various applications, such as the locking and positioning of the various systems for absorbing thermal energy; in combination with them, the use of pushers 32 (FIG. 11) is useful, which in turn allow multiple applications. In fact, thanks to the presence of pairs of interrupted cylindrical seats 39 opposite each other, of the pressure plane 40, and of seats 42 and to the appropriate use of the metal bars 37 positioned in the various uses, they allow to keep the pipes blocked or in a pressure position. / or plates in hybrid systems (FIGS. 12, 13 and 17) or in thermal systems.

In the event that the multifunction solar system is used as a hybrid (as illustrated in FIG. 13), it will not be necessary to close the bottom of the same as the main objective is to produce more electricity by reducing the temperature and recovering the resulting thermal energy with storage systems; in the event that the system provides a safety mechanism for the removal of the pipes containing the heat transfer fluid from the rear of the absorbing surface, there will be a support element 43 (fixed to the system with screws thanks to the holes 50 - FIG. 13 and 17 - present on the cap 9 of the multifunctional accessory 7) useful for positioning any electromagnets 44 (or other motion transfer system, such as linear cylinders), fixed with the aid of fixing accessories, such as screws 45.

In the case in which the invention is realized as a solar thermal system, and therefore a! only for the purpose of absorbing heat through the surface 46 and transferring it to the heat-carrying fluid contained in the pipes 47 (FIG. 14, 15 and 16), there is also a bottom 48 (fixed in the same way as the support 43 described above) useful for maintaining the heat of the heat transfer fluid and block the insulating material which can be interposed between the bottom 48 itself and the area of the surface of the absorber 46-tubes for heat transfer fluid 47.

The use as solar thermal provides for the possibility of having a safety system, obtainable thanks to the use of an extruded profile 49, placed under the bottom 48 which is kept in a back position by the cylindrical springs 51 thanks to the presence of the locked ring nuts 52 through the nuts 53 and 54, in case of need (excessive heat detected by thermocouples or other temperature detection systems), an electromagnet or linear cylinder is activated which, acting on the extruded profile 49, transmits its motion to the tubes 47, moving them away, thanks to the ferrules 52, from the surface 46 of the absorber.

The invention also makes it possible to keep the upper surface of the glazed body 4 or, depending on the use, of the photovoltaic laminate 5 clean, thanks to the presence of upper washing nozzles 55 (FIG. 18), which allow washing (by gravity) the aforementioned surfaces helping to increase the total yield of the solar system. Equally advantageously, the nozzles 55 can be used in combination with the photovoltaic system to reduce the surface temperature, with considerable advantages in terms of production, thanks to the inverse proportionality that regulates the energy produced and the temperature of the module: the final goal is the same as the hybrid modules (reduce the temperature) but in this case it is obtained in a simpler and more immediate way by running water, preferably rainwater and certainly free of limestone inside, to avoid opacification of the absorbing surface.

A further application solution is schematically illustrated in FIGS. 19 where, by applying a special upper cover that integrates a roll-up cover - similar to a curtain that protects homes from solar radiation - which allows, in the event of an emergency or excessive temperature condition in the heat transfer fluid, to cover at least partially the surface exposed to solar radiation.

Claims (9)

CLAIMS 1. Integrated multifunctional solar system for the production of energy consisting of (FIGS. 1 and 9) a pair of extruded frames 2 highlighting the protrusions 25 for the waterproofing of the underlying roof, by a pair of head elements 3 mechanically linked to the previous ones , characterized by the fact of having at least one pair of hook-like projections 16 for rapid locking with profiles 6 (FIG. 6) and of including at least one pair of multifunctional accessories 7 (FIG, 2), consisting of base 8 and cap 9 positioned inside the extruded frames 2. 2. Integrated multifunctional solar system for energy production according to claim 1 characterized in that the frames 2 have seats 14 useful for the mechanical engagement of optional gaskets or extruded covers 15 (FIG. 10). 3. Integrated multifunctional solar system for the production of energy according to claim 1, characterized in that in the head element 3 there is a protruding rib 23 useful for the mechanical engagement of the multifunctional system with extruded profiles 6 (FIG. 6) and the plastic clips 10. 4. Integrated multifunctional solar system for the production of energy according to claim 1 characterized in that the head elements 3 have openings 17 (FIG, 4) useful for the passage of hydraulic pipes and / or cables towards the open lower part 18. 5. Integrated multifunctional solar system for the production of energy according to claims 1 and 2 characterized in that between the elements belonging to the same row (and therefore fixed to the same profile 6 vertically, according to the description and FIGS. 5 and 6) there is a through cover 13 useful for maintaining the waterproofing of the underlying cover. 6. Integrated multifunctional solar system for the production of energy according to claims 1 and 2 characterized that the terminal elements of the row have a terminal cover mechanically linked to the head element 3 (FIG. 1). 7. Integrated multifunctional solar system for the production of energy according to claims 1, 2 and 3 characterized in that there is at least one bar 37 blocked by means of a pair of multifunctional accessories 7 (FIG. 13). 8. Integrated multifunctional solar system for the production of energy according to claims 1, 2,3 and 7 characterized in that together with the pair of multifunctional accessories 7 and the bar 37 there is at least one pusher 32 (FIG. 13). 9. Integrated multifunctional solar system for the production of energy according to claims 1, 2 and 3 characterized by the fact that the absorbers 46 (FIG. 13) have shapes which allow the quick locking of the multifunctional accessories 7 with the hooks 35.