ITPN20110025A1 - MODULAR SOLAR COLLECTOR WITH SOLAR-DUAL ENERGY DEVICE AND CONSEQUENTLY PREFERRED TO TRANSFORMATION INTO PHOTOVOLTAIC ENERGY. - Google Patents

Description

Patent application for industrial invention entitled:

"MODULAR SOLAR COLLECTOR WITH DEVICE WITH DOUBLE COLLECTION OF SOLAR ENERGY AND CONSEQUENTLY PREFERRED ITS TRANSFORMATION INTO PHOTOVOLTAIC ENERGY"

The present invention relates to a modular solar collector with double capture of the solar rays for their preferred conversion into photovoltaic energy. Said modular collector being provided with a plurality of concave mirrors, reflecting the solar rays which concentrate them on a second corresponding plurality of elements for receiving and absorbing the concentrated solar radiation, placed at a suitable distance from the reflecting elements described above and which, at in turn, they are equipped with elements for receiving and transforming solar energy into photovoltaic energy, i.e. of photovoltaic cells. Above said elements for absorbing concentrated solar radiation, other elements defined as photovoltaic cells will be placed which will be directly affected by the sun's rays in order to exploit the shaded area of the reflection elements and to further optimize the exploitation of solar energy.

The collector is modular and can, if properly assembled, create solar panels of desired sizes and shapes.

The various types of modular and non-modular solar collectors are commonly known in the state of the art, they always have limitations in practical use, not least in the exploitation of solar radiation, in fact the existing solar collectors are able to collect, capture and transform only a small part of the solar energy contained in the rays incident on the collectors forming the existing and known solar panels.

Do not dwell further in the discussion and even less in the description of the collectors constituting the known solar panels as the average technician is able to know them and to recognize the limitations and constructive, use and transformative defects that are also still inherent in the state of the art. known.

The purpose of the present invention is to obviate the drawbacks, limitations and all, or at least in large part, the problems existing in the state of the art. In order to better understand the characteristics and advantages obtainable with the present invention, all by way of non-limiting example only is described below with reference to the attached figures in which:

- Figure 1 is a perspective view of the basic element constituting the modular solar collector and includes the two elements, i.e. the element of reflection and concentration of solar rays and the element of reception of the same;

Figure 2 is a front view of a detail of the "section" of the basic components constituting the basic element of Figure 1;

- Figure 3 is a schematic view of how the solar rays are concentrated by the specular concentration element on the receptive element and how the receptive element is hit on both of its major sides;

Figure 4 is an example of a solar panel consisting of the basic modular collectors of Figure 1.

It should be noted that the common details will be recalled with the same numerical references.

With particular reference to figures 1 and 2, the basic element 1 constituting the modular solar collector will be described, i.e. it (1) will primarily have a basically rectangular plan, while its transverse longitudinal section will denote a plurality of concave specular elements 11, of reflection and concentration, preferably with circular concavity, they (11) will be longitudinally proximal to each other. The basic modular element 1 will also have, in its lower part, i.e. below the parts defined as concave elements 11, the lateral longitudinal channels 13, proximal to the outside of said modular base element 1, and further longitudinal channels 14 placed, centrally and always below, between a concave specular element 11 and the other .

It should be noted that above the basic modular element 1 and precisely longitudinally centrally with respect to the single plurality of concave specular reflecting elements 11 there will be placed receptor elements 2 corresponding to the front of the concavity 11. These receptor elements 2 will have two opposite surfaces 20 and 21 on which elements defined as photovoltaic cells 200 and 210 will be positioned, adhered.

Clearly, the upper and lower "wings" of the basic modular element 1 will be shaped for known uses and applications and therefore useless to describe, just think that the upper and lower "wings" will house the sealing glass and lower they will be coupled to any positioning systems, housing and lower insulation of said modular base elements 1 on a larger solar panel.

Once the conformation, briefly described, of the basic modular element 1 has been defined, with reference to Figure 3, we will describe how the solar rays impact against the reflection element 11 and, consequently concentrated, will be reflected on the side 20 of the 'collection element 2, no less like the rays, which will not impact the reflection element 11, because covered by the collection element 2, will directly impact on the collection surface 21 of the element 2 itself, opposite to that 20 of the same element indicated above.

Precisely, we will briefly describe how the direct uptake and by reflection and concentration of the solar rays takes place, is repeated, with particular reference to figure 3 in which:

- In a first case, solar rays R, coming from the sun, will impact against the upper surface 21 of the collection element 2 on which photovoltaic cells 210 will be placed which will transform part of the energy due to the solar electromagnetic radiation into photovoltaic energy, i.e. electric;

- in a second case the solar rays R will impact against the reflection and concentration surfaces 11 of the element 1, where they will concentrate, reflecting and discharging their energy against the surface 21, equipped with photovoltaic cells 210, of the 'catchment element 2.

Clearly part of the electromagnetic radiation will not turn into electricity, so it will go into thermal energy and for this reason "thermal bridges" will be provided for the dissipation of heat from the elements 2 in order to maintain their optimal temperature for the photovoltaic operation. , nevertheless the heat thus disposed can be used in the ways described in other rights of simultaneous presentation.

Clearly at the top the module thus described, or the manifold defined as the complete basic modular element 1, will be closed at the top with a suitable transparent means which will seal all the chamber present between said transparent means and the upper part of the said basic modular element 1 which will be then filled with appropriate gas. Below said modular base element 1 will be applied insulators and means for coupling to the final solar panel shown in figure 4, i.e. a plurality of modular base elements 1 will be placed in parallel and in cascade on a suitable support 3 which will house them. and which can be applied to sun tracking systems as shown in figure 4, or to roofs of houses or other types of uses.

It is emphasized that the details described are shown in a preferred embodiment and only by way of non-limiting example.

It is therefore well understood that different variants can be applied to the object of the present invention without however departing from the scope of what has been described up to now and claimed hereinafter with reference to the attached drawings and therefore from the scope of this industrial patent.

Claims (1)

CLAIMS 1) Modular solar collector with double solar energy capture device and consequent preferred transformation into photovoltaic energy consisting of a basic modular element (1) equipped with a plurality of elements (11) for reflection and concentration of solar rays and a corresponding plurality of elements (2), for capturing the solar rays, arranged proximal to said reflection elements (11) characterized by the fact that the solar rays R, a first case coming directly from the sun, will impact against the upper surface (21) of the capture element (2) on which photovoltaic cells will be placed that will transform part of the energy due to solar electromagnetic radiation into photovoltaic energy, i.e. electricity and in a second case the solar rays R will impact against the reflection and concentration surfaces (11) of the element (1), where they will concentrate going to reflect and discharge their energy against the surface (20), of the collection element 2, provided with respective photovoltaic cells (200).