ITBO20080578A1 - STRUCTURE WITH ADJUSTABLE SOLAR PANELS. - Google Patents

Description

SOLAR PANEL STRUCTURE OF ADJUSTABLE TYPE

DESCRIPTION

The present invention relates to a structure with solar panels of the orientable type.

The exploitation of solar radiation for the production of energy usable by man is currently of particular interest: interest is aroused by the minimum environmental impact that involves the conversion of solar energy as well as by the continuous increase in efficiency. of conversion plants.

The exploitation of solar energy is generally performed with two distinct purposes (rarely coexisting in a single system): the production of heat (generally hot water) obtained from the so-called solar thermal systems and the production of electricity obtained from photovoltaic systems.

A solar thermal system normally consists of a panel that receives solar energy, an exchanger, inside which circulates a fluid used to transfer the thermal energy to a tank used to store the accumulated energy.

A photovoltaic module is a device capable of converting solar energy directly into electrical energy through the photovoltaic effect and is used as an almost pure current generator in a photovoltaic system. It may be aesthetically similar to the solar thermal panel, but it has a profoundly different purpose and function.

Both the systems described can guarantee high yields, especially if the angle of incidence of sunlight on their surface falls within a specific range.

For this reason the installation of the systems is carried out keeping the surfaces suitably oriented: this type of assembly, however, makes the panels more subject to atmospheric agents.

In particular, a large surface, arranged according to ideal inclination angles, will be subjected to very strong mechanical actions and stresses from the wind.

It is possible to resort to systems equipped with servo mechanisms for the commanded orientation of the panels: in this case, if severe weather conditions occur (for example a strong wind) the panels can be reclined to make them less exposed.

It is evident that the space occupied by systems of this type is greater than that of fixed systems (an inclined panel requires a base of smaller dimensions than its total surface): in the face of an advantage in terms of greater resistance towards atmospheric stresses, there will therefore be a worse exploitation of the space available for installation.

In the case of small spaces available for installation, it is also not convenient to install solar systems as the installation costs are not justified by the low overall energy yield.

The main aim of the present invention is to provide an adjustable type solar panel structure with high efficiency and minimum bulk.

Within the scope of this technical task, another object of the present invention is to provide a structure with solar panels of the orientable type suitable for withstanding strong external stresses without suffering damage.

Another object of the present invention is to provide a solar panel structure of the orientable type suitable for delivering good quantities of energy even if arranged on small installation surfaces.

A further object of the present invention is to provide a solar panel structure of the orientable type of low cost, relatively simple to make in practice and safe to apply.

This task and this object are achieved by the present structure with solar panels of the orientable type of the type comprising at least one support element for at least two laminar bodies each having at least one respective solar panel, characterized in that at least one of said laminar bodies it comprises a respective movement member for its retraction in the configuration of juxtaposition to another laminar body, the juxtaposition of the at least two bodies determining an increase in the overall rigidity of the structure.

Further particularities will become clearer and more evident from the detailed description of a preferred, but not exclusive, embodiment of an adjustable type solar panel structure, illustrated as an indication, but not limited to, in the accompanying drawings, in which:

Fig. 1 shows, in top view, a structure with solar panels of the orientable type according to the invention;

Fig. 2 shows, in side view, a structure with solar panels of the orientable type according to the invention;

Fig. 3 represents, in a perspective view from below, a secondary module of a solar panel structure of the orientable type according to the invention;

Fig. 4 is a top perspective view of a secondary module of a solar panel structure of the orientable type according to the invention;

figure 5 represents, in perspective view, the detail V of figure 3;

Figure 6 represents, in perspective view, the detail VI of Figure 3;

fig.7 represents, in perspective view, the detail VII of figure 4;

Fig. 8 represents, in a perspective view from below, a main module of a structure with solar panels of the orientable type according to the invention;

Fig. 9 represents, in a perspective view from above, a main module of a structure with solar panels of the orientable type according to the invention;

Fig. 10 is a perspective view of the carousel and the crown of a structure with solar panels of the orientable type according to the invention;

Fig. 11 represents, in perspective view, the motorized movement joint of a solar panel structure of the orientable type according to the invention.

With particular reference to these figures, the reference numeral 1 generally designates a solar panel structure of the orientable type.

The solar panel structure 1 2 according to the invention comprises at least one support element 3 for at least two laminar bodies 4 and 5 each provided with at least one respective solar panel 2.

At least one of the laminar bodies 4 and 5 (in particular the laminar bodies 5 in the embodiment represented in the attached figures) comprises a respective movement member for its retraction in juxtaposition configuration to another laminar body 5, 4 (in particular the bodies laminar 4 in the embodiment represented in the attached figures).

The juxtaposition of the bodies 4 and 5 determines an increase in the overall rigidity of the structure 1: in fact the whole structure 1, when the bodies 4 and 5 are superimposed, offers less aerodynamic resistance and is therefore less stressed by wind.

The structure 1 comprises at least one main module 6 consisting of at least two laminar bodies 4 arranged in a radial direction with respect to the anchoring portion of the module 6 itself to the support element 3 and at least one secondary module 7 consisting of at least two laminar bodies 5 arranged in radial direction towards the movement member with respect to the support element 3. The main module 6, by the action of at least one respective motor member 8, and each laminar body 5 of the secondary module 7, by the action of the movement member, turn out to be mobile.

The movements they can perform will be defined between an exposed configuration (first limit configuration) in which each laminar body 5 of the secondary module 7 is close to the corresponding laminar body 4 of the main module 6 and its solar panels 2 are hit by solar radiation, and a retracted configuration (second limit configuration) in which each laminar body 5 of the secondary module 7 is juxtaposed to the corresponding laminar body 4 of the main module 6.

Going deeper into the specific characteristics of a particular embodiment solution, it can be noted that the main module 6 comprises a carousel 9 from which at least two support arms 10 branch off for respective fixed laminar bodies 4. In this case the secondary module 7 instead comprises a crown 11 from which at least two support beams 12 branch off for respective mobile laminar bodies 5.

Between the carousel 9 and the crown 11 the aforementioned motor 8 is interposed for the relative rotation of the same (in practice the motor 8, responsible for the rotation of the main module 6 also performs part of the relative movements between the carousel 9 and the crown 11 .

In particular, the carousel 9 supports a star 13 in solidarity with itself, the rotations of the carousel 9 involve similar rotation of the star 13.

Each movable laminar body 5, associated with a respective beam 12 of the crown 11, can slide on guides 14 of the beam 12 itself by the action of a rod 15 hinged, at one end 16, to a portion of the laminar body 5 and, opposite end 17, at a point of the star 13.

The relative rotation of the carousel 9 (integral with the star 13) and of the crown 11 cause a displacement of the anchor point to the star 13 of the rod 15 with consequent retreat of the other end 16 of the rod 15 and therefore of the respective laminar body 5. The relative rotation of the carousel 9 (and therefore also of the star 13 integral with it) with respect to the crown 11 is defined between two limit configurations, an active limit configuration in which each laminar body 5 of the crown 11 is arranged substantially along the bisector of the angle formed by two contiguous laminar bodies 4 of the carousel 6 and a passive limit configuration in which each laminar body 5 of the crown 11 is juxtaposed, and aligned in mutual overlap (aligned on planes placed at different levels in the vertical direction), at a corresponding laminar body 4 of the carousel 9.

The main module 6 is placed above the secondary module 7 and the carousel 9 is superimposed above the crown 11. The star 13 is substantially inside the area delimited by the crown 11 and substantially at the same level.

A motorized joint 18 is interposed between the support element 3 and the assembly consisting of the main module 6 and the secondary module 7 for the orientation of the relative laminar bodies 4 and 5 in conditions of maximum incidence of solar radiation. It should be remembered that the panels 2 have maximum efficiency in correspondence with an incidence of the radiation according to a direction substantially perpendicular to their surface: the orientation allows to better approximate this condition.

The motorized joint 18, according to an embodiment of particular practical and applicative interest, is of the two-axis type; this joint 18 is in fact provided with an actuator 19 for adjusting the angle of inclination of the modules 6 and 7 with respect to the support element 3 and with a rotation unit 20 for adjusting the angle of rotation of the modules 4 and 5 with respect to the longitudinal axis of the support element 3.

In particular, the actuator 19 will be of the hydraulic cylinder type and will be equipped with a unit 21 consisting of a foil provided with a multiplicity of contiguous holes and a respective motion and fixed position sensor, responsible for detecting the position of the foil.

The rotation unit 20 will normally consist of a hydraulic motor with orbiting baffles, for example of the type normally used in the wind field.

According to a particular construction solution in compliance with the technical construction requirements of a plant for the exploitation of solar energy, the actuator 19 for adjusting the angle of inclination operates within an interval of 50 ° upwards starting from the direction identified by the plane orthogonal to the longitudinal axis of the support element 3.

Similarly, the rotation unit 20 for adjusting the rotation angle can preferably operate within an interval between -110 ° and 110 ° starting from a generic rest position, corresponding to a rotation angle of 0 °. . The laminar bodies 4 of the main module 6 and the laminar bodies 5 of the secondary module 7 are arranged, in an exposed configuration, like the petals of a flower with respect to the relative carousel 9 and crown 11.

Faced with a decidedly modest installation space (identified by the space necessary to anchor the support element 3 to the ground), the structure 1 has a large irradiated surface and therefore can guarantee a delivery of energy higher than that of traditional systems (if however, these are effectively applicable on such reduced installation spaces).

Usefully, the structure 1 best withstands atmospheric stresses (wind, snow load and the like) since in passive configuration (in which the laminar bodies 5 are aligned with the laminar bodies 4) its surface is extremely small and only the laminar bodies 4 which are supported by arms 10 which can be made of the desired dimensions and rigidity.

Structure 1 is particularly suitable for the construction of photovoltaic systems, but the possibility of adopting it in thermal or mixed systems is not excluded.

It has thus been seen how the invention achieves the intended aim and objects.

The invention thus conceived is susceptible of numerous modifications and variations, all of which are within the scope of the inventive concept.

Furthermore, all the details can be replaced by other technically equivalent ones.

In the illustrated embodiments, individual characteristics, reported in relation to specific examples, may actually be interchanged with other different characteristics, existing in other embodiments.

Furthermore, it should be noted that everything that in the course of the procedure for obtaining the patent turns out to be already known, is intended not to be claimed and subject to excerpt (disclaimer) from the claims.

In practice, the materials used, as well as the shapes and dimensions, may be any according to requirements without thereby abandoning the scope of the protection of the following claims.

Claims (1)

R I V E N D I C A Z I O N I 1.Structure with solar panels (2) of the orientable type of the type comprising at least one support element (3) for at least two laminar bodies (4, 5) each provided with at least one respective solar panel (2), characterized by the fact that at least one of said laminar bodies (5) comprises a respective movement member for its retraction in juxtaposition configuration to another laminar body (4), the juxtaposition of the at least two bodies (4, 5) determining an increase in overall rigidity of the structure (1). 2. Structure, according to claim 1, characterized in that it comprises at least one main module (6) consisting of at least two laminar bodies (4) arranged in a radial direction with respect to the anchoring portion of the module (6) itself to said support element (3) and at least one secondary module (7) consisting of at least two laminar bodies (5) arranged in a radial direction towards the movement member with respect to said support element (3), the main module (6), by action of at least one respective motor member (8), and each laminar body (5) of said secondary module (7), by the action of said movement member, being movable from an exposed configuration in which each laminar body (5) of the secondary module (7) is close to the corresponding laminar body (4) of the main module (6) and its solar panels (2) are invested by solar radiation, to a retracted configuration in which each laminar body (5) of the secondary module (7 ) It is juxtaposed to the corresponding laminar body (4) of the main module (6). 3. Structure, according to claim 2, characterized in that said main module (6) comprises a carousel (9) from which at least two support arms (10) branch off for respective fixed laminar bodies (4) and said secondary module ( 7) comprises a crown (11) from which at least two support beams (12) branch off for respective mobile laminar bodies (5), between said carousel (9) and said crown (11) at least one said motor member (8) being interposed ) for their relative rotation. 4. Structure, according to claim 3, characterized by the fact that the carousel (9) supports a star (13), in solidarity with itself, the rotations of the carousel (9) involving similar rotation of the star (13). 5. Structure, according to claims 2 and 3, characterized in that each said mobile laminar body (5), associated with a respective beam (12) of said crown (11), is sliding on guides (14) of the beam ( 12) itself by the action of a rod (15) hinged, at one end (16), to a portion of the laminar body (5) and, at the opposite end (17), to a point of said star (13), the rotation of the carousel assembly (9) star (13) with respect to the crown (11) causing a displacement of the anchor point to the star (13) of the rod (15) with consequent retraction of the other end (16) of the rod (15)) and therefore of the respective laminar body (5). 6. Structure, according to claims 2 and 3, characterized in that the relative rotation of said carousel (9), and therefore of the star (13), with respect to said crown (11) is defined between two limit configurations, a configuration active limit in which each laminar body (5) of said crown (11) is arranged substantially along the bisector of the angle formed by two contiguous laminar bodies (4) of said carousel (9) and a passive limit configuration in which each body laminar (5) of said crown (11) is juxtaposed, and aligned in reciprocal superposition, to a corresponding laminar body (4) of said carousel (9). 7. Structure, according to one or more of the preceding claims, characterized in that said main module (6) is placed above said secondary module (7) and said carousel (9) is superimposed above said crown (11) . 8. Structure, according to one or more of the preceding claims, characterized in that a motorized joint (18) is interposed between said support element (3) and the whole of said main module (6) and said secondary module ( 7) for the orientation of the relative laminar bodies (4, 5) in conditions of maximum incidence of solar radiation. 9. Structure, according to claim 8, characterized in that said motorized joint (18) is of the two-axis type, being provided with an actuator (19) for adjusting the angle of inclination of said modules (6, 7 ) with respect to said support element (3) and a rotation unit (20) for adjusting the angle of rotation of the modules (6, 7) with respect to the longitudinal axis of said support element (3). 10. Structure according to claim 9, characterized in that said actuator (19) for adjusting the angle of inclination operates within an interval of 50 ° upwards starting from the direction identified by the plane orthogonal to the longitudinal axis of the support element (3). 11. Structure, according to claim 9, characterized by the fact that said rotation unit (20) for adjusting the rotation angle operates within an interval comprised between -110 ° and 110 ° starting from a generic position of rest, corresponding to a rotation angle of 0 °. 12. Structure according to one or more of the preceding claims, characterized in that the laminar bodies (4) of the said main module (6) and the laminar bodies (5) of the said secondary module (7) are arranged, in an exposed configuration, like the petals of a flower with respect to the relative carousel (9) and crown (11).