ITMI20120534A1 - SOLAR PANEL AND METHOD FOR REALIZING SUCH SOLAR PANEL - Google Patents

Description

DESCRIPTION

of the patent for industrial invention entitled:

"SOLAR PANEL AND METHOD FOR REALIZING THIS SOLAR PANEL"

The present invention relates to a solar panel and to a method for making said solar panel.

Known solar panels comprise an absorber element, configured to absorb solar radiation, and a plurality of conduits thermally coupled to the absorber element in which circulates the water which is heated following the heat exchange with the absorber element.

In recent years, the solar panel industry has focused on reducing the production costs of solar panels.

In accordance with this trend, the object of the present invention is to provide a solar panel which is efficient and which, at the same time, has production costs lower than the production costs of known types of solar panels.

In accordance with this purpose, the present invention relates to a solar panel comprising:

at least one absorber element, which has a substantially flat shape and is configured so as to absorb, at least in part, solar radiation;

at least one duct thermally coupled, at least in part, to the absorber element;

at least one casing, which houses at least the absorber element and the duct; the casing being provided with a substantially quadrangular bottom wall, two side walls, two end walls and a covering wall;

the solar panel being characterized in that at least the bottom wall of the casing is defined by a first wall and a second wall separated by a cavity.

A further object of the present invention is to provide a method for making a solar panel that is simple, quick and economical.

In accordance with these purposes, the present invention relates to a main method of making a solar panel; the solar panel being provided with at least a first absorber element, which has a substantially flat shape and is configured so as to absorb, at least in part, solar radiation; at least one duct thermally coupled, at least in part, to the absorber element; and with at least one casing, which houses at least the first absorber element and the duct and is provided with a substantially quadrangular bottom wall, two side walls, two end walls and a covering wall;

the method comprising the step of making the envelope; the step of making the casing comprising the step of making at least the bottom wall of the casing in such a way that the bottom wall is defined by a first wall and a second wall separated by an interspace.

Further characteristics and advantages of the present invention will appear clear from the following description of a non-limiting example of its implementation, with reference to the figures of the annexed drawings, in which:

Figure 1 is a perspective view, with parts in section and parts removed for clarity, of a solar panel according to the present invention;

Figure 2 is a perspective view, with parts in section and parts removed for clarity, of a first detail of the solar panel of Figure 1;

Figure 3 is a sectional view, with parts removed for clarity, of a second detail of the panel of Figure 1.

In Figure 1, the reference number 1 indicates a solar panel, which is configured to absorb solar radiation and transfer solar energy to a collection fluid. In use, the solar panel 1 is connected to a heating system and / or to a system for supplying domestic hot water (not illustrated for simplicity in the attached figures).

Preferably, several solar panels 1 are used coupled to each other and connected to the same system. The number of solar panels 1 to be used is determined according to the heating needs and the average intensity of the solar radiation.

The solar panel 1 according to the present invention extends along an axis A and comprises an inlet manifold 2, an outlet manifold 3, a plurality of ducts 4, an absorber element 5 thermally coupled to the ducts 4 and a casing 6.

In the non-limiting example described and illustrated here, the solar panel 1 has a width (intended as the dimension in the direction orthogonal to the axis A) less than the length (intended as the dimension in the direction parallel to the axis A). A solar panel 1 having a width less than the length is normally defined in the sector as a "vertical structure" panel.

A not illustrated variant of the solar panel according to the present invention provides that the solar panel has a "horizontal structure" and has a length less than its width.

The inlet manifold 2 and the outlet manifold 3 are, at least in part, housed inside the casing 6. The ducts 4 and the absorber element 5 are entirely housed inside the casing 6.

The envelope 6 is preferably made in such a way as to define an adiabatic environment in order to minimize the dispersion of heat towards the outside of the solar panel 1.

With reference to Figure 2, the casing 6 has a preferably flat rectangular shape. In particular, the casing 6 comprises a bottom wall 7, two side walls 8, two end walls 9 and a covering wall 10 (visible in Figures 1 and 3).

Preferably, the bottom wall 7, the side walls 8 and the end walls 9 are made in one piece.

With reference to Figure 3, the bottom wall 7, the side walls 8 and the end walls 9 define a shell 11. The shell 11 comprises a first wall 12 and a second wall 13 separated by an interspace 15.

The shell 11 further comprises a plurality of reinforcing elements 16.

The first wall 12 and the second wall 13 face and are substantially arranged parallel.

In the non-limiting example described and illustrated here, the first wall 12 faces the inside of the casing 6, while the second wall 13 faces the outside of the casing 6.

Preferably the first wall 12 and the second wall 13 are made of polymeric material.

The interspace 15 is arranged between the first wall 12 and the second wall 13 and preferably contains air.

A not illustrated variant of the present invention provides that the interspace 15 contains a thermally insulating material, such as for example expanded polyurethane, expanded polystyrene, etc.

The reinforcing elements 16 extend between the first wall 12 and the second wall 13 and contribute to conferring structural rigidity to the shell 11.

In the non-limiting example described and illustrated here, the reinforcing elements 16 comprise first reinforcing elements 16a and second reinforcing elements 16b. The first reinforcing elements 16a are arranged along the bottom wall 7, are made in one piece with the first wall 12 and are substantially defined by recesses made in the first wall 12. In particular, along the bottom wall 7 the reinforcing elements 16a they have a substantially truncated cone shape.

Preferably, the reinforcing elements 16a arranged along the bottom wall 7 are fixed to the second wall 13, for example by means of an adhesive material.

With reference to Figures 2 and 3, the second reinforcing elements 16b are arranged along the side walls 8 and along the end walls 9 and are substantially defined by recesses made in the second wall 13. In particular, along the side walls 8 and along the end walls 9 the reinforcing elements 16b are substantially parallelepiped-shaped. The particular shape of the reinforcing elements 16b along the side walls 8 and along the end walls 9 favors the use of the reinforcing elements 16b as gripping elements for lifting and transporting the solar panel 1 by an operator.

Preferably, the reinforcing elements 16b arranged along the side walls 8 and along the end walls 9 are fixed to the first wall 12, for example by means of an adhesive material.

Preferably, the shell 11 is made of polymeric material by means of the blow molding technique.

This technique involves blowing compressed air into a preform positioned inside a hollow mold, so that the preform swells and assumes the shape of the internal walls of the mold. The object thus obtained is then cooled and the mold is opened for the removal of the finished object.

The preform can be produced in situ through an extruder coupled to the blow molding machine.

The preform is a substantially tubular shaped element made of polymeric material in the semi-solid state.

Preferably, the mold used to make the shell 11 is configured in such a way that at the end of the blowing phase, the shell 1 comprises the first wall 12, the second wall 13, the plurality of reinforcing elements 16 as described above. and the interspace 14.

If the dimensions of the shell 11 are greater than the maximum dimensions achievable by the blowing systems available, the method of manufacturing the solar panel 1 provides for the creation of two half-shells 17, substantially identical and capable of being coupled together so as to form the shell the as highlighted by the dotted line represented in figure 2.

A variant of the present invention provides that the shell 11 is made by means of a rotational molding technique, which provides for the rotation of the mold around two axes: a primary axis, with a fixed direction, and a secondary axis, with a variable direction.

The mold is at the same time heated in such a way that the polymer melts and adheres (thanks to the rotation) to all the internal surfaces of the mold, covering them. Then the material is cooled and the mold is opened, in order to eject the finished product.

The covering wall 9 is made of a material transparent to solar radiation to allow solar radiation to affect the absorber element 5 housed inside the casing 6.

Preferably, the covering wall 10 is made of glass.

Preferably, the covering wall 10 is internally coated with a layer made of a material transparent to the solar radiations which directly affect the covering wall 10 and not transparent to the solar radiations reflected by the absorber element 5.

Preferably, the covering wall 10 is glued to the shell 11.

With reference to Figure 1, the inlet manifold 2 is substantially a duct arranged in an internal portion 20 of the casing 6 in proximity to one of the end walls 9, and has a portion 21 housed inside the casing 6 and two end portions 22a 22b, which are arranged externally to the casing 6 in correspondence with the side walls 8 and pass through two respective holes 23 made in the side walls 8.

Preferably, the portion 21 of the inlet manifold 2 inside the casing 6 extends in a direction orthogonal to the axis A for the entire width of the casing 6 from one side wall 8 to the other side wall 8.

In use, the inlet manifold 2 has an end portion 22a in communication with a collection fluid supply circuit (not shown for simplicity) and an end portion 22b closed or, alternatively, connected to an end portion of the inlet manifold of another solar panel (not shown for simplicity).

The outlet manifold 3 is substantially a duct arranged in an internal portion 23 of the casing 6 in proximity to the end wall 8 opposite the end wall 8 next to the inlet manifold 2, and has a portion 24 arranged inside the casing 6 and two end portions 25a and 25b, which are arranged externally to the casing 6 in correspondence with the side walls 8 and pass through two respective holes 27 made in the side walls 8.

Preferably, the portion 24 of the outlet manifold 3 inside the casing 6 extends in a direction orthogonal to the axis A for the entire width of the casing 6 from one side wall 8 to the other side wall 8.

In use, the outlet manifold 3 has an end portion 25a in communication with a delivery circuit for the heated collection fluid (not shown for simplicity) and an end portion 25b closed or, alternatively, connected to an end portion the output collector of another solar panel (not shown for simplicity).

The ducts 4 extend between the inlet manifold 2 and the outlet manifold 3 and are crossed by the collection fluid.

Preferably, the ducts 4 extend parallel to the axis A.

In particular, each duct 4 has a first end 28a connected to the inlet manifold 2 and a second end 28b connected to the outlet manifold 3.

In this way, the inlet manifold 2, the outlet manifold 3 and the ducts 4 define a hydraulic circuit inside which the collection fluid flows. In use, the collection fluid heats up in the passage from the inlet manifold 2 to the outlet manifold 3 thanks to the transfer of heat determined by the thermal coupling between the absorber element 5 and the ducts 4.

Advantageously, the solar panel 1 according to the present invention comprises a casing 6, which is made in a simple and economical way and, at the same time, is capable of ensuring adequate thermal insulation from the external environment.

Adequate thermal insulation is guaranteed by the particular double-walled structure separated by a cavity filled with air or with insulating material. This solution avoids having to apply further layers of insulating material (for example glass wool) on the back wall and simplifies and speeds up the assembly operations of the solar panel.

Moreover, the use of polymeric material for the construction of the shell guarantees low production costs and allows the use of molding techniques of polymeric material, such as blow molding or rotational molding.

Blow molding and rotational molding make it possible to easily obtain hollow objects with thin thicknesses, and are at the same time particularly convenient from an economic point of view thanks to the low costs of manufacturing the mold and the molding process.

In conventional panels, on the other hand, the casing is normally made by coupling metal extrusions. This entails higher costs associated with the use of more expensive raw materials and high-cost production processes.

Finally, the plastic materials used to make the envelope 6 are able to withstand the action of atmospheric agents, including the most harmful such as UV rays, hail and snow.

Finally, it is evident that modifications and variations can be made to the solar panel described here without departing from the scope of the attached claims.

Claims (14)

CLAIMS 1. Solar panel (1) comprising: - at least one absorber element (5), which has a substantially flat shape and is configured so as to absorb, at least in part, solar radiation; - at least one duct (4) thermally coupled, at least in part, to the absorber element (5); - at least one casing (6), which houses at least the absorber element (5) and the duct (4); the casing (6) being provided with a bottom wall (7), two side walls (8), two end walls (9) and a covering wall (10); the solar panel (1) being characterized by the fact that at least the bottom wall (7) of the envelope (6) is defined by a first wall (12) and by a second wall (13) separated by an interspace (15) . 2. Panel according to claim 1, wherein also the side walls (8) and the end walls (9) of the casing (6) are defined by respective portions of the first wall (12) and the second wall (13) separated by 'interspace (15). 3. Panel according to claim 1, wherein the first wall (12) and the second wall (13) are facing and substantially parallel. Panel according to any one of the preceding claims, wherein the casing (6) is provided with a plurality of reinforcing elements (16a; 16b) which extend between the first wall (12) and the second wall (13) . 5. Panel according to claim 4, wherein first reinforcing elements (16a) have a substantially frusto-conical shape. 6. Panel according to claim 4, wherein second reinforcing elements (16b) are substantially parallelepiped-shaped. Panel according to any one of the preceding claims, in which the interspace (15) contains air. Panel according to any one of the preceding claims, wherein the interspace (15) contains a thermally insulating material. Panel according to any one of the preceding claims, wherein the interspace (15) contains expanded polyurethane or expanded polystyrene. 10. Panel according to any one of the preceding claims, in which the first wall (12) and the second wall (13) are made of polymeric material. 11. Panel according to any one of the preceding claims, wherein the first wall (12) and the second wall (13) are made by means of a blow molding technique or a rotational printing technique. 12. Method for making a solar panel (1); the solar panel (1) being provided with at least one absorber element (5), which has a substantially flat shape and is configured so as to absorb, at least in part, solar radiation; of at least one duct (4) thermally coupled, at least in part, to the absorber element (5); and at least one casing (6), which houses at least the absorber element (5) and the duct (4) and is provided with a bottom wall (7), two side walls (8), two end walls (9) and a covering wall (10); the method comprising the step of making the envelope (6); the step of making the casing (6) comprising the step of making at least the bottom wall (7) of the casing (6) in such a way that the bottom wall (7) is defined by a first wall (12) and a second wall (13) separated by an interspace (15). Method according to claim 12, wherein the step of making the envelope (6) comprises the step of making at least the bottom wall (7) by means of a blow molding technique of polymeric material or by means of a rotational molding technique of polymeric material. Method according to claim 12 or 13, wherein the step of making the casing (6) comprises the step of making one piece the bottom wall (7), the side walls (8) and the end walls (9) of the casing (6) so that the bottom wall (7), the side walls (8) and the end walls (9) are defined by the first wall (12) and the second wall (13) separated by a interspace (15).