ITTO20100324A1 - SOLAR COLLECTOR - Google Patents

Description

DESCRIPTION of the industrial invention entitled:

â € œSolar collectorâ €

TEXT OF THE DESCRIPTION

The present invention is directed to a solar collector comprising:

- at least one collector element including a transparent portion and a reflecting portion, wherein said at least one collector element is deformable from a substantially flat shape to a substantially tubular shape,

- support means arranged to receive a solar absorber device, e

- at least one element having a shape that can be positioned in the at least one collector element or at at least one of the ends of the at least one collector element to maintain the substantially tubular shape.

Description of the prior art

In the field of transforming solar energy into thermal or electrical energy, different types of devices are known which use different technologies. In particular, one of these typologies is that of the so-called concentration systems, which includes devices based on the laws of optics without images and which exploit reflective surfaces capable of concentrating energy in a predetermined region of space, for example in correspondence to a focal line of a reflector having a parabolic or generally curved profile. These devices have a series of advantageous characteristics, first of all the wide variety of structures that can be used for their construction. This is of particular importance if you want to have a foldable or otherwise collapsible solar collector. Such solar collectors are illustrated in a plurality of documents such as, for example, US 4,051,834. This document illustrates a transportable solar collector having a linear solar absorber on which the energy of the light radiation coming from the sun is concentrated and having a structure of polymeric material that can be inflated and deflated in order to allow a rapid deployment and collapse of the structure to transport it from one place to another.

A collapsible device as well but of a completely different structure is illustrated in WO 2004/065861 A1. This document illustrating a concentrating portable solar collector comprising a plurality of panels and collapsible structures that can be assembled to form a closed container inside which containers for liquids to be heated and having the shape of a parabolic reflector can be inserted.

However, the devices described above have a series of drawbacks. In particular, the solar collector illustrated in US 4,051,834 requires, due to its inflatable structure, compressors and / or pressurized gas cylinders for its deployment, which makes it objectively inconvenient to use it in situations where it is required the smallest possible footprint, for example in the field of camping equipment.

The manifold described in the document WO 2004/065861 A1 has the undoubted drawback of requiring a complete assembly of the structure, which can considerably lengthen the deployment times in the event that an array of manifolds is to be installed.

Purpose of the invention

The object of the present invention is to overcome the problems of the known art previously described. In particular, the object of the present invention is to provide a single or otherwise composed solar collector that can be easily transported and deployed in the field in a simple way, without requiring assembly or additional equipment.

Summary of the invention

The object of the present invention is achieved by a solar collector having the characteristics forming the subject of the following claims, which form an integral part of the technical teaching administered herein in relation to the invention.

In particular, the purpose is achieved by a solar collector having the characteristics listed at the beginning of this description in which, moreover, the at least one shaped element is integral with said at least one collector element and is foldable towards the the interior of the at least one collector element when said at least one collector element assumes the substantially tubular shape.

Brief description of the drawings

The invention will now be described with reference to the attached drawings, given purely by way of indicative example in which:

- figure 1 is a perspective view of a solar collector according to the present invention,

- figure 2 is a perspective view of a component of the solar collector of figure 1, in combination with a solar absorber device,

- figure 3 is a perspective view corresponding to figure 2 but illustrating a different configuration, - figure 4 is an enlarged view according to arrow IV of figure 1,

- figure 5 is a view corresponding to figure 4 but illustrating a possible variant embodiment,

Figure 6 consists of six portions, indicated by the letters A, B, C, D, E, F illustrating a sequence of deployment of the solar collector according to the present invention and of a single collector element, in which Figure 6F illustrates also a connectable solar absorber of the type which can be coupled with the solar collector according to the present invention,

- figure 7 is a perspective view of a further embodiment of a solar absorber device which can be coupled to the solar collector according to the present invention,

- figure 8 is a view according to arrow VIII of figure 5,

- figure 9 is a perspective view corresponding to figure 6F but relative to the solar absorber of figure 7,

Figure 10 illustrates a second embodiment of a solar collector according to the present invention,

- figures 11 to 13 schematically illustrate different instants of an unfolding sequence of the solar collector of figure 10, in which figure 12 is also a view according to arrow XII of figure 11, - figure 14 illustrates a variant of the solar collector of figure 1,

- figure 15 illustrates a variant of the solar collector of figure 10,

- figure 16 illustrates a further variant of the solar collector of figure 1 in a first configuration, - figure 17 corresponds to figure 16 but refers to a second configuration, and

- figure 18 is a perspective view according to arrow XVIII of figure 17.

Detailed description of the invention

In Figure 1, 1 indicates a solar collector according to the present invention. The solar collector 1 comprises one or more collector elements 2, each made of transparent polymeric material. Each collector element 2 is preferably made with a pair of sheets of polymeric material 2A, 2B joined along longitudinal seams 3 which define joining edges 3A. Each collector element 2 is deformable and includes a transparent portion 4, associated with the sheet 2A and an internally reflective portion 6, associated with the sheet 2B and made, preferably, by means of a sheet or a sheet of reflective material deposited inside each collector element 2 on the sheet of polymeric material 2B associated with the portion 6, so as to give it the property of reflecting light.

Alternatively, it is possible to deposit a layer of reflective material on the sheet associated with the internally reflective portion 6.

With reference to Figures 1 to 3, support means are fixed to the transparent portion 4 and are designed to accommodate a solar absorber device 8. Said support means comprise a sheath 10 having a hollow section defining a channel 12 inside which the € ™ solar absorber 8. The sheath 10 is fixed to the sheet 2A associated with the transparent portion 4 by means of a deformable longitudinal flap 14 and is made, like the latter, of transparent polymeric material.

Each collector element 2 further comprises, at opposite ends thereof, form elements including a first and a second folding flap 16, 18 integral with it. At each end there are therefore two pairs of fins comprising a fin 16 and a fin 18.

Each fin 16, 18 is configured as an extension in the longitudinal direction, respectively, of the sheets of polymeric material constituting the transparent portion 4 and the internally reflecting portion 6 and has a substantially almond shape. In the present description, the term "almond shape" is intended to designate a geometric figure whose edges are two incident curves in two distinct points, in which they define respective cusps, and with facing concavities.

By virtue of this, each fin 16, 18 comprises pairs of respective cusp ends 16A, 18A (figure 3), a respective free edge 16B, 18B and is articulated with respect to the corresponding portion 4 or 6 along a respective bending line 16C , 18C symmetrical with respect to the corresponding free edge with reference to an axis passing through the aforementioned cusp ends 16A, 18A.

The shape of each fin is therefore defined by the cusp ends 16A, 18A, by the free edges 16B, 18B and by the fold lines 16C, 18C.

Each fin 16, 18 comprises a respective rectangular opening 20, 21; the openings 20, 21 are identical to each other but have different positions relative to the respective fin 16, 18. In particular, the opening 20 is arranged near the folding line 16C, while the opening 21 is arranged near the free edge 18C.

Each collector element 2 can be connected to an adjacent collector element by means of the connection between the respective joining edges 3A.

By way of example and with reference to Figures 4, 5, the flaps 3A can be connected to each other by means of buttons 22 inserted in slots 24 or snap buttons 26.

In advantageous variants, the use of VELCRO® or any joining means equivalent to those mentioned is foreseen.

The solar absorber 8 which can be used in combination with the solar collector 1 is shown here in two distinct variants. A first variant is illustrated in figures 6F: the solar absorber 8 comprises a support profile 30 on which two arrays of photovoltaic cells 32 are fixed, on opposite sides, connected to each other by electrical connections 34. Alternatively, the device solar absorber can include a single array of photovoltaic cells.

A second variant of the solar absorber device is illustrated in figures 7, 8, 9.

In this embodiment, the solar absorber device 8 comprises a support profile 36 having a substantially "I" section comprising two end channels 38, 40 and a central flange 42. The channels 38, 40 are capable of containing water or other fluid , while the platform 42 carries two arrays of photovoltaic cells 44 fixed on opposite sides of it and connected to each other by means of electrical connections 46.

Alternatively, the solar absorber device can only comprise an array of photovoltaic cells

The operation of the solar collector 1 is as follows.

Each of the collector elements 2 is deformable from a substantially flat shape, corresponding to a collapsed configuration, to a substantially tubular shape, corresponding to an unfolded configuration. Figures 6A, B, C, D, E, F illustrate a sequence of deployment of the solar collector 1. Each of Figures 6C to 6E comprises an interrupted perspective view of part of the solar collector 1 or of a single collector element and a corresponding section obtained along respective traces C-C, D-D, E-E.

Figure 6A shows the solar collector 1 in a collapsed and folded configuration. In this configuration, each collector element 2 is substantially flattened and the internally reflective portion 6 and the transparent portion 4 are in a condition of minimum distance, separated only by the sheath 10 arranged between them.

The sheath 10 can assume any orientation inside the collector element 2 thanks to the deformability of the longitudinal flap 14. In particular, it can assume an orientation such that it substantially adapts to the flattening of the collector element 2 .

The collapsed collector elements 2 are arranged in a stacked configuration by means of a substantially U-shaped folding of the respective joining edges 3A.

To start the deployment of the solar collector 1 it is necessary to bring the collector elements 2 from the stacked configuration of Figure 6A to a partially deployed configuration illustrated in Figure 6B. In this configuration, the collector elements 2 are arranged side by side but each collector element is still in a collapsed configuration, identically to what is illustrated in Figure 6A.

With reference to Figure 6C, the deployment of each collector element 2 takes place by exerting a transverse force T on the longitudinal sides of each of them, in particular in correspondence with the joining edges 3A.

The application of the force T on the collector elements 2 causes an outward hunching of the transparent portion 4 and of the internally reflective portion 6 such that each collector element 2 assumes a pseudo-tubular shape with a substantially almond-shaped section (Figure 6D). In the present description, the term â € œexternalâ € means to indicate the portion of space that is not included between portions 4 and 6 of the collector element 2. Consequently, the term â € œinteriorâ € intends to designate the spatial region between the portions 4 and 6, i.e. comprised between the sheets of polymeric material with which each collector element 2 is made.

Furthermore, as it derives from the previous description, any direction parallel to the direction of development of the edges 3 (and similarly of the sheath 10) and in general parallel to the portions 4, 6, whatever their configuration (flattened or hunched).

It should also be noted that the sheath 10 moves spontaneously towards a position similar to that illustrated in Figures 1 to 3 thanks to the flexibility of the longitudinal flap 14.

With reference to figure 6E, continuing in the application of the force T on each collector element 2, this assumes a tubular shape which is per se unstable, since its stability is compromised by the elastic return of the portions 4, 6 which tend to return in a configuration substantially similar to that illustrated in Figure 6C.

When the manifold element 2 assumes the tubular shape illustrated in figure 6E, for this to be maintained it is necessary to fold the fins 18, 16 towards the inside of the manifold element 2 in sequence. flap 18 is folded before flap 16 but it is possible to reverse the order with the same result.

The folding takes place along the respective folding lines 16A and 18A and has an amplitude substantially equal to a right angle.

It is evident that, since the fold lines 16A and 18A have a curvilinear development, following the folding each fin will assume a shape substantially hunched towards the inside of the collector element 2. In this way, each of the fins 16, 18 thus hunched it has a stiffness capable of counteracting the elastic return effect of the portions 4, 6 which thus allows to maintain the tubular shape of the collector element 2.

Furthermore, following the folding, the openings 20 and 21, thanks to their previously described arrangement, are aligned to form a single opening.

With reference to figure 6F, when the deployment operations of each collector element 2 have been completed, it is possible to insert a solar absorber device 8 inside each of the channels 12. For this purpose, the absorber 8 It is first inserted through the openings 20 and 21 which are aligned with each other when the fins 16, 18 are bent, and then into the channel 12. It should be noted that the openings 20 and 21 support the ends of the solar absorber 8, also guaranteeing in this way the positioning of the sheath 10 with respect thereto.

Alternatively, it is possible to reverse the operations illustrated in figures 6E and 6F, with the same result.

The manifold 1 is then placed on a support structure or on the ground, so that the portion 6 is in contact with it. When the solar radiation affects the transparent portions 4 of the solar collector 1, it is refracted and directed towards the internally reflective portion 6, which, in turn, concentrates a large part of the reflected rays on the solar absorber device 8. In this way, in the case of use of the solar absorber device 8 in figure 6F, it is possible to convert the energy associated with solar radiation into electrical energy, which can be exploited on site thanks to the arrangement offered by the electrical connections 34.

In this situation, moreover, it is preferable to provide ventilation holes on the fins 16, 18 in order to lower the temperatures inside the collector element 2. These ventilation holes can also be conveniently covered with a filter fabric to prevent the intrusion of dust or other agents, while maintaining the ability to dispose of the heat captured inside the collector element 2.

If, on the other hand, the solar absorber described in figures 7 to 9 is used, the energy associated with solar radiation is partly transformed into electricity thanks to the photovoltaic cells 44, and partly used for heating the fluid flowing in the channels 38, 40.

In this way, there is the simultaneous production of electricity and hot fluid. Clearly, in combination with the solar collector 1 it is necessary to have means for the circulation of the fluid in the channels 38, 40 as well as means for storing possibly transformed electrical energy. These means are of a known type and within the reach of those skilled in the art and will not be described here.

With reference to figures 10 to 13, an advantageous variant of the solar collector 1 is indicated with the reference number 100. The solar collector 100 comprises a plurality of collector elements 102. Each collector element 102 made by joining two longitudinal sheets of transparent polymeric material 102A, 102B along junction lines 103. Adjacent manifold elements 2 are connected by junction flaps 103A fixed thereon, for example but not exclusively by heat sealing. The junction edges 103 A can be connected together in the same way as illustrated in figures 4, 5 for the solar collector 1.

Each sheet 102A, 102B comprises a respective transparent portion 104A, 104B and a respective internally reflective portion 106A, 106B. The union of the portions 104A, 106A of the sheet 102A with the portions 104B, 106B of the sheet 102B creates a transparent portion 104 and an internally reflective portion 106 functionally analogous to the portions 4, 6. The internally reflective portions 106A, 106B are preferably made by depositing a layer of reflective material on the sheets 102A and 102B, so as to give the portion 106 the property of reflecting light.

Each collector element 102 also comprises support means arranged to receive the solar absorber 8.

Such support means include a sheath 110 having a channel 112 arranged to receive the solar absorber device 8. The sheath 110 is constrained to the internally reflective portion 106 by means of a deformable longitudinal flap 114 arranged along the corresponding junction line 103.

At opposite ends of each collector element 102 are formed respective fins 116, 118 having an almond shape with cusp ends 116A, 118A and integral, respectively, with the sheet 102A and the sheet 102B.

Each folding flap 116, 118 comprises a respective free edge 116B, 118B and is articulated with respect to the corresponding sheet 102A, 102B along a respective folding line 116C, 118C symmetrical with respect to the corresponding free edge with reference to an axis passing through the aforementioned ends cusp 116A, 118A. In particular, portions 106A, 106B are associated with portions of folding lines 116C, 118C which approximate a parabolic profile, while portions 104A, 104B are associated with portions of folding lines 116C, 118C which approximate a circular profile.

Each fin 116, 118 comprises a respective rectangular opening 120, 121 identical to each other and arranged on the center line of the fins along an axis passing through the cusp ends 116A, 118A.

The operation of the solar collector 100 is as follows.

With reference to Figures 10, 11, each collector element 102 is deformable from a substantially flat shape, corresponding to a collapsed configuration, to a substantially tubular shape, corresponding to an unfolded configuration. Figures 11 to 13 illustrate part of an unfolding sequence, which takes place in a completely analogous manner to that described for the solar collector l, in which the application of a force T (Figure 12) oriented transversely on the lines is foreseen of junction 103 of each collector element 102.

This force T causes an outward hunching of the portions 104A, 106A and 104B, 106B which gives the collector element 2 a substantially tubular shape.

This shape is maintained, as previously described, by bending the fins 116, 118 towards the inside of the collector element 102 or by or alternatively by applying a traction action acting in the opposite direction to the forces of figure 11, exercised by means of suitable tie-rod elements, anchored on suitable support or broadly to the ground.

In an improved variant these tie rods cross the tubular part and are loose when said chamber is in the collapsed configuration, while they are tense when the tubular chamber is unfolded or the set of chambers are unfolded. In this situation, the stretched tie rod can usefully help to support and keep in position the sheath that contains the absorber.

The bending takes place sequentially and the position of the openings 120, 121 is such that they are aligned when bending is completed.

However, since the sheath 110 is bound to the portion 106, which similarly to the portion 6 is prepared for contact with the ground or with the support structure, it is preferable to insert the solar absorber 8 (whether in the embodiment illustrated in Figures 2, 3, 6F or in the embodiment illustrated in Figures 7 to 9) in the channel 112 after the folding of the fins, with the sheath 110 hanging from the top and the cylindrical surface facing downwards, then overturning to bring the parabolic surface down.

Or, in the variant with tie wire described above, said wire bound to the sheath helps to position it and maintain the positioning.

Furthermore, as previously described, it should be observed that the shape given to the collector element 2 by means of the fins 116, 118 approximates that of a parabolic reflector, in which the internally reflecting portion 106 assumes a shape which substantially approximates that of a parabola, while the portion 104 assumes a shape which substantially approximates that of a semicircle.

Similarly to the solar collector 1, the openings 120, 121 support the solar absorber device 8 and also contribute to the correct positioning of the sheath 110 when each collector element 102 is in an unfolded position.

Advantageous variants of the solar collectors 1, 100 are illustrated in figures 14, 15. These variants are indicated, respectively, with the numbers 1â € ™ and 100â € ™. The components of the solar collector 1â € ™ which are identical to those of the solar collector 1 are indicated with the same reference number. The solar collector 1â € ™ comprises, applied on the transparent portion 4, at least one linear diverging Fresnel lens oriented longitudinally is globally indicated with L. The Fresnel lens L is suitable to increase the angle of acceptance of the incident solar radiation for each collector element 2.

Similarly, the solar collector 100â € ™, whose components identical to those of the solar collector 100 are indicated with the same reference number, comprises, applied in correspondence with the transparent portion 104, at least one linear divergent and longitudinally oriented Fresnel lens indicated globally with Lâ € ™. The function of the L lens is identical to that of the L lens.

A further advantageous variant of the collector 1 is illustrated in figures 16, 17, 18. The collector 1 comprises a filiform element 50, for example a rope of natural fibers, a metal wire or of polymeric material, which crosses transversely the ™ collector element 2 and exits from it through two openings 52 (figs. 16, 18) obtained on sheets 2A, 2B.

The filiform element 50 is preferably provided, at one end, with a reported head 53 and with an abutment element 53A, while the other end is free. A sleeve 54 fits over element 50 and is freely movable relative to it.

With reference to figures 16, 17, the filiform element 50 is designed to vary the geometry of the collector element 2 from the flattened shape to the substantially tubular shape previously described.

Starting from a condition, illustrated in figure 16, in which the collector element 2 is collapsed and is in the substantially flat form previously described, it is possible to exert a traction force on the filiform element 50 keeping the collector element 2.

The thread-like element 50 drags the head 53 and the abutment element 53A against the junction edge 3A adjacent to them, while the opposite edge 3A is kept stationary by means of a manual action exerted by a user. By continuing to apply a traction force on the filiform element 50, and having both edges 3A of the collector element bound (by means of the head 53 and the abutment element 53A on one side and by the hand of the User on the other) to move only in one direction which causes them to approach each other, a hunching of the sheets 2A, 2B is produced which gives the manifold element 2 the substantially tubular shape previously described.

The length of the sleeve 54 is chosen so as to be equal to a maximum transverse dimension of the collector element 2 when it assumes the substantially tubular shape, substantially corresponding to the distance between the cusp ends 16A (or 18A).

In this way, upon reaching the aforementioned condition, a further action on the filiform element 50 does not cause any further hunching of the sheets 2A, 2B since the sleeve 54 is in contact with the sheets 2A, 2B and prevents them from becoming further movement. Naturally, in order for the shape imposed on the collector element 2 to be maintained, it is necessary to bend the fins 16, 18 as previously described.

Clearly, the overall dimensions of the sheath 10 must be chosen in such a way as not to interfere with the filiform element 50 and with the sleeve 54. It should also be noted that the filiform element 50 can pass through an arbitrary number of collector elements 2 , which allows to realize a manifold 1 with a wire deployment system, in which a sleeve 54 is inserted inside each manifold element. Preferably, in this case several parallel thread-like elements 50 can pass through the manifold 1, thus making the unfolding action uniform over the entire length of the individual collector elements 2. the presence of the openings 52 also allows the normal overlapping of the edges 3A of adjacent collector elements, thus making it possible to join them with the modalities described with reference to figures 7, 8.

The solar collectors 1, 100 according to the invention have a series of advantages. First of all, the solar collectors 1, 100 are intrinsically light as they are made of polymeric material, which facilitates their portability. Furthermore, their collapsibility makes them suitable for transport even in small cars or private vehicles, and in any case does not require the use of industrial vehicles such as vans or the like.

Since both are made of sheets of polymeric material joined together along longitudinal edges, the production process necessary for their realization is well known, consolidated and low cost. Therefore they combine low cost with the possibility of transforming the energy associated with solar radiation into electrical energy or of exploiting it for heating a fluid, ultimately constituting a source of renewable and low-cost energy for a plurality of different activities, therein. including outdoor sports and / or camping activities.

Naturally, the details of construction and the embodiments may be widely varied with respect to what has been described and illustrated purely by way of example, without thereby departing from the scope of protection of the present invention, as defined by the attached claims.

For example, it is particularly advantageous to integrate the solar absorber device 8 and the sheath 10, 110. It is possible to replace the sheath 10, 110, as a support means for the solar absorber device, with an extruded element of polymeric material. A plurality of photovoltaic cells drowned inside the extruded element of polymeric material (or simply carried by it), together with the necessary electrical connections, therefore constitutes a solar absorber device.

In this way the solar absorber device is integrated with its own support means and there is no need to provide the openings 20, 21, 120, 121: in this way the deployment of the solar collectors 1, 1â € ™, 100, 100â € ™ would be further simplified.

Nevertheless, as an alternative to the photovoltaic or thermal-photovoltaic type absorber 8 described here, it is possible to use a normal solar thermal absorber, that is, of the type comprising a tubular body capable of containing water or other fluid.

Claims (12)

CLAIMS 1. Solar collector (1, 100; 1â € ™, 100â € ™) comprising: - at least one collector element (2,102) including a transparent portion (4, 104) and an internally reflective portion (6, 106), called at least a collector element (2, 102) being deformable from a substantially flat shape to a substantially tubular shape, - support means (10, 110) arranged to receive a solar absorber device (8), e - at least one shaped element (16, 18; 116, 118) which can be positioned at each opposite end of said at least one collector element (2, 102) to maintain said substantially tubular shape, the solar collector (1, 100; 1â € ™, 100â € ™) being characterized by the fact that said at least one element of shape (16, 18; 116, 118) is integral with said at least one collector element (2, 102) and it is foldable towards the inside of said at least one collector element (2, 102) when said at least one collector element (2, 102) assumes said substantially tubular shape. 2. Solar collector (1, 100; 1â € ™, 100â € ™) according to claim 1, characterized by the fact that said at least one shaped element is a fin (16, 18; 116, 118) articulated with respect to said element manifold (2, 102) by a fold line (16C, 18C; 116C, 118C). 3. Solar collector (1, 100; 1â € ™, 100â € ™) according to claim 1, characterized in that said support means comprise a sheath (10, 110) including a channel (12) arranged to receive an absorber device solar panel (8), said sheath (10) being fixed to said collector element (2, 102) by means of a deformable longitudinal flap (14). 4. Solar collector (1, 100; 1â € ™, 100â € ™) according to claim 2, characterized in that said at least one collector element (2, 102) comprises two fins (16, 18; 116, 118) at each opposite end, each of said fins comprising a rectangular opening (20, 21; 120, 121). 5. Solar collector (1, 100; 1â € ™, 100â € ™) according to claim 4, characterized in that each of said fins (16, 18, 116, 118) has a substantially almond shape comprising two respective cusp-shaped ends (16A, 18A; 116A, 118A) and a respective freeboard (16B, 18B; 116B, 118B). 6. Solar collector (1, 100; 1â € ™, 100â € ™) according to claim 3, characterized in that it comprises a solar absorber device (8) including a support profile (30, 36) and at least one array of cells photovoltaic (32, 44) arranged on it. 7. Solar collector (1, 100; 1â € ™, 100â € ™) according to claim 6, characterized in that said support profile (30, 36) comprises a pair of channels (38, 40) capable of containing water or other fluid. 8. Solar collector (1, 100; 1â € ™, 100â € ™) according to claim 1, characterized in that said at least one collector element (2, 102) is made by means of a pair of sheets of transparent polymeric material (2A , 2B; 102A, 102B) joined along longitudinal junction lines (3, 103), said at least one collector element (2, 102) comprising respective joining edges (3A, 103A) prepared for connection (24, 25; 26) to joining edges (3A, 103A) analogous to an analogous collector element (2, 102). 9. Solar collector (1, 100; 1â € ™, 100â € ™) according to claim 1, characterized in that said support means comprise an extruded element of polymeric material and in that it comprises a solar absorber device, in which said solar absorber device comprises a plurality of photovoltaic cells carried by said extruded element of polymeric material. 10. Solar collector (1â € ™, 100â € ™) according to claim 1, characterized in that it comprises at least one linear and diverging Fresnel lens (L, Lâ € ™) applied on said transparent portion (4, 104). 11. Solar collector (1) according to claim 1, characterized in that it comprises a filiform element (50) passing through at least one collector element (2) and arranged to vary the geometry of said at least one collector element (2) from said shape substantially flat to said substantially tubular shape. Solar collector (1) according to claim 11, characterized in that it comprises a sleeve (54) fitted on said filiform element (50), said sleeve (54) having a length substantially equal to the transversal dimensions of said at least one collector element ( 2) when said collector element (2) assumes said substantially tubular shape.