ITVR20110067A1 - SUPPORT STRUCTURE FOR SOLAR COLLECTORS - Google Patents

Description

DESCRIPTION

attached to a patent application for INDUSTRIAL INVENTION entitled:

SUPPORT STRUCTURE FOR SOLAR COLLECTORS

DESCRIPTION

The present invention relates to a support structure for solar collectors. In particular, this structure is suitable for supporting both photovoltaic solar collectors for the production of electricity and solar thermal collectors for water heating. In addition, the support structure can be installed both on the ground and on the roofs of buildings.

Support structures for solar collectors are currently known comprising a base body which can be supported or fixed to a surface (for example to the roof of a building, to the ground, etc.).

Furthermore, the support structure comprises a support body fixed to the base body and defining a fixed mounting plane at which the solar collector can be mounted. In other words, the support body is fixed relative to the base body.

Usually, the mounting plane is inclined according to a fixed angle (normally between 25 ° and 45 *) with respect to a horizontal plane so as to be on average, during the solar year, orthogonal with respect to the direction of propagation of solar radiation . In other words, the mounting plane is oriented so that in some periods of the year it is orthogonal to the direction of propagation of solar radiation and in other periods of the year it is inclined but not orthogonal to the direction of propagation of solar radiation.

However, this known technique has some drawbacks.

These drawbacks are related to the fact that the declination of the sun varies, in the place of installation of the support structure, during the calendar year. Where the term "declination" means the central angle subtended by an arc of the celestial meridian between the celestial equator and the parallel passing through that place.

In other words, the height of the sun with respect to the horizon, in the place of installation of the support structure, varies during the calendar year,

Consequently, the absorption of solar radiation by the collector mounted on the support structure varies over the course of the year according to the declination of the sun.

In fact, since the mounting surface is fixed with respect to the horizontal, there are periods of the year in which the absorption of radiation is less than the absorption in other periods of the year. In particular, the absorption of the solar collector is maximum when the mounting surface is orthogonal to the propagation of solar rays.

Therefore, the performance of a solar system connected to this collector varies according to the declination of the sun and therefore in some periods of the year it will be higher or lower than in other periods of the year.

Furthermore, other drawbacks are related to the fact that the support body must be adapted according to the latitude of the place where it is to be installed. In fact, the declination of the sun is a function of the latitude of the place considered.

Therefore, it is necessary to produce specific support structures with support surfaces with specific orientations depending on the latitude of the place of installation.

In this situation, the object of the present invention is to provide a support structure for solar collectors which remedies the aforementioned drawbacks. It is in particular the object of the present invention to create a support structure for solar collectors that optimizes the absorption of solar radiation during the solar year.

Another object of the present invention is to provide a support structure for solar collectors which is easily adaptable to any latitude.

The indicated aims are substantially achieved by a support structure according to what is described in the attached claims.

Further characteristics and advantages of the present invention will become more apparent from the detailed description of some preferred, but not exclusive, embodiments of a support structure illustrated in the accompanying drawings, in which:

Figure 1 shows, in side view, the support structure object of the present invention in a first operative position;

Figure 2 shows, in side view, the support structure illustrated in Figure 1 in a second operative position;

Figure 3 shows, in side view, an enlarged detail of the support structure illustrated in Figure 1;

- Figure 4 shows, in top view, the support structure illustrated in Figure 1;

Figure 5 shows, in front view, the support structure illustrated in Figure 1, with some parts in section;

Figure 6 shows, in front view, an alternative embodiment of the support structure of Figure 5;

figure 7 shows, in side view, a support kit according to the present invention; And

figure 8 shows, in side view, an enlarged detail of the support kit of figure 7.

With reference to the aforementioned figures, the reference number 1 globally indicates a support structure 1 according to the present invention. In particular, the support structure 1 for solar collectors 100 comprises a base body 2 which can be associated with a support surface and a support body 3 connected to the base body 2.

As can be seen in Figure 5, the base body 2 comprises two bars 4 spaced apart, each extending longitudinally between its own first end 4a, in use in contact with the supporting surface, and its own second end 4b opposite the first end and next to the support body 3. Preferably, the bars 4 are arranged vertically and are anchored, at the first ends 4a, to the support surface. In other words, the first ends 4a of the bars 4 are embedded in the ground, or in the roof of a building.

Preferably, each bar 4 is an “I” shaped section (commonly also referred to as a double “T” shaped section) and comprises a central part 5 interposed between two lateral wings 6 protruding therefrom. In figure 5 it is possible to see only one of the two wings 6 as the representation is sectioned along a vertical plane.

As regards the support body 3, it comprises a quadrilateral-shaped frame 7. This quadrilateral-shaped frame 7 defines a mounting plane on which at least one solar collector 100 can be mounted.

The frame 7 also extends along a first direction between its own first side 7a and its own second side 7b and along a second direction transversal to the first direction between its own third side 7c and its own fourth side 7d.

Preferably, the frame 7 comprises three side members 8 and two cross members 9. The side members 8 are arranged substantially parallel to each other, and the two cross members 9 are arranged orthogonally to the side members 8 and parallel to each other.

In other words, the longitudinal members 8 extend parallel to the first direction, while the cross members 9 extend parallel to the second direction. Furthermore, each cross member 9 defines respectively the third side 7c and the fourth side 7d, while a first side member 8 defines the first side 7a and a second side member 8 defines the second side 7b. The third longitudinal member 8 is arranged centrally to the support body 3 and is positioned between the first and second longitudinal member 8.

Preferably, the third side member 8 is equidistant from the first side member 8 and from the second side member 8.

As can be seen in Figures 1 and 2, during use the solar collector 100 is connected to the longitudinal members 8 and faces the sky. In other words, the mounting plane is the plane substantially tangent, in at least one point, to each side member 8.

Furthermore, the support structure 1 comprises adjustment means 10 operatively interposed between the support body 3 and the base body 2 to orient the mounting plane with respect to the base body 2 in a plurality of predefined positions.

In other words, the support body 3 is movable with respect to the base body 2 which is fixed.

In particular, the support body 3 is movable in a plurality of predefined configurations, each corresponding to a respective position of the mounting plane.

Even more specifically, each predefined position corresponds to a predefined inclination of the mounting plane with respect to a horizontal plane. In other words, each predefined configuration of the support body 3 corresponds to a respective inclination of the mounting plane positioned in a predefined position.

In the embodiment illustrated, for example, in Figure 1, the support body 3 is rotatably mounted on the base body 2 to rotate around an axis of rotation R so as to define said predefined positions of the mounting plane.

In other words, the body is supported rotates with respect to the base body 2 so as to incline the mounting plane in each of the predefined positions. In other words, each predefined position corresponds to a predefined inclination of the mounting surface.

Preferably, the axis of rotation R is horizontal and each predefined position corresponds to a predefined angle between the mounting plane and the horizontal plane.

In figure 1 it is possible to see the support body 3 in a first predefined configuration corresponding to a respective first predefined position of the mounting plane. In figure 2 it is possible to see the support body 3 in a second predefined configuration corresponding to a respective second predefined position of the assembly plane. Preferably, the assembly plane can be oriented in at least four distinct positions each associated with a respective season of the year . Advantageously, it is possible to orient the mounting surface, and therefore the collector, in a predefined position according to the season of the year of interest.

As you can see in figure 5, the rotation axis R is parallel to the mounting plane and preferably the rotation axis R is parallel to the second direction. Furthermore, the rotation axis R is arranged between the first side 7a and the second side 7b and is equidistant from them and positioned in correspondence with the third longitudinal member 8. In other words, the rotation axis R is substantially centered with respect to the plane assembly so as to define a tilting movement of the assembly plane with respect to the rotation axis R.

In other words, during the rotation of the support body 3 the first side 7a and the second side 7b move vertically in opposite directions according to the direction of rotation.

Preferably, as can be seen in Figure 7, the adjustment means 10 comprise a rotatable coupling 11 interposed between the base body 2 and the support body 3 to make the support body 3 rotate with respect to the base body 2. This coupling swivel 11 comprises a receiving portion 11 a connected to the base body 2 and shaped like a "V" so as to define an insertion area A. The swivel coupling 11 also comprises a rotation portion 11 b connected to the support body 3 and rotatably inserted in the insertion area A of the receiving portion 11 a to rotate around the axis of rotation R. In other words, the rotating portion 11 b is rotatably mounted on the receiving portion 11 a. In detail, the receiving portion 11 a comprises two fins 12 at least partially spaced apart to define the insertion area A between them. Furthermore, each fin 12 has a rotation hole 13. More precisely, the two rotation holes 13 are aligned with each other,

In addition, the rotation portion 11 b has a further hole 14 aligned with the two rotation holes 13 along the rotation axis R.

The swivel coupling 11 also includes a rotation pin 15 inserted inside the rotation holes 13 and the additional hole 14 to rotate the support body 3 with respect to the base body 2.

Note that the rotation pin 15 develops along part of the rotation axis R.

Furthermore, the adjustment means 10 comprise an activation member 16 for the rotation of the support body 3 mounted on the base body 2 and movable by a user. In addition, the adjustment means 10 comprise a transmission member 17 operatively connected between the activation member 16 and the support body 3 to move the support body 3.

Preferably, the activation member 16 comprises a pinion 18 rotatably mounted on the base body 2. In particular, the pinion 18 is rotatably mounted on at least one bar 4 of the base body 2 in proximity to the support body 3.

As can be seen in Figure 5, the adjustment means 10 comprise two pinions 18 (schematically represented in Figure 5) spaced apart and each associated with a respective bar 4. Furthermore, the adjustment means 10 comprise a shaft 19 extending at least between the two pinions 18 and on which shaft 19 the two pinions 18 themselves are keyed. The shaft 19 extends longitudinally along its own main development axis and is rotatably mounted on the base body 2.

In particular, the shaft 19 is rotatable with respect to its main development axis to rotate the pinions 18. Preferably, the main development axis of the shaft 19 is substantially parallel to the rotation axis R. In figure 7 it is possible to note that the shaft 19 comprises a protruding portion 20 which protrudes from the base body 2. In other words, the protruding portion 20 is defined by an extension of the shaft 19 itself beyond at least one support bar 4.

Furthermore, the adjustment means 10 comprise at least a support 21 connected to the base body 2 to support the shaft 19. In other words, the shaft 19 is mounted in support on the support 21 so as to rotate on it.

Preferably, the support 21 has a through hole in which the shaft 19 is rotatably inserted. In the embodiment illustrated in figure 5 there are two supports 21 each connected to a respective bar 4. The through holes of the support are aligned with each other along the 'main development axis of the shaft 19.

Furthermore, the transmission member 17 (part of the adjustment means 10) comprises at least a rack 22 connected to the support body 3 and meshed with the pinion 18 (Figure 3).

In particular, the rack 22 has an extension between its first end 22a and its second end 22b. At least one of the ends of the rack 22 is connected to the support body 3 to move it.

Preferably, both ends of the rack 22 are connected to the support body 3 so that the rack 22 is integral with the support body 3 itself. In detail, the rack 22 is connected to a crosspiece 9.

Furthermore, the rack 22 is, at least in part, shaped in an arc of circumference having as its center the rotation axis R. In addition, each end 22a, 22b of the rack 22 is equidistant from the rotation axis R. In other words, the rotation axis R is positioned centrally with respect to the ends 22a, 22b of the rack 22.

In particular, the rack 22 comprises an arch-shaped part 23 interposed between the two ends 22a, 22b. Even more particularly, the arc-shaped part 23 is spaced from the supporting body 3. Specifically, the arc-shaped part 23 of the rack 22 develops in correspondence with a pinion 18. It should be noted that the rack 22 has a toothed side 24 meshed with this pinion 18.

Furthermore, the rack 22 comprises two side portions 25 each extending from the arch-shaped part 23 to a respective end of the rack 22.

As can be seen in Figure 5, the adjustment means 10 comprise two racks 22 each positioned in correspondence with a respective bar 4 and meshed with a respective pinion 18. In this way, by rotating the shaft 19, the pinions 18 rotate which act on the racks 22 making the support body 3 move in the predefined configurations.

Furthermore, the support structure 1 comprises stop means 26 operatively interposed between the rack 22 and the base body 2 to lock the support body 3 at each of said predefined positions. In other words, the stop means 26 lock the support body 3 in each of its own predefined configurations.

In particular, the support structure 1 has a plurality of first holes 27 positioned along the extension of the rack 22 at each of the predefined positions (Figure 3). Furthermore, the support structure 1 has at least a second hole 28 arranged on the base body 2 in correspondence with the rack 22 and aligned with a first hole 27 when the support body 3 is in correspondence with each of the predefined positions. Finally, the support structure 1 comprises at least one locking pin (not shown in the attached figures) which can be inserted between a first hole 27 and a second hole 28 to lock the support body 3 at a predefined position. It should be noted that the first holes 27, the second hole 28 and the locking pin are part of the stop means 26. Preferably the first holes 27 are arranged on the arch-shaped part 23 of the rack 22 and along the toothed side 24.

Precisely, the distance between the first holes 27 along the rack 22 corresponds to the angular difference between one position and another of the mounting plane. In detail, the angle generated by the half-lines passing through two respective first holes 27 and having a vertex on the rotation axis R defines the angular difference between two positions of the mounting plane.

In the embodiment illustrated in Figure 1, each first hole 27 is elongated along a direction transverse to the mounting plane. Advantageously, the elongated holes allow to tolerate small positioning errors (during assembly) of the rack 22 with respect to the supporting body 3.

In fact, during the assembly of the rack 22 on the support body 3, it is possible that the rack 22 is in a position closest to the mounting plane or closest to the base body 2. In this case, the first holes 27 undergo a consequent translation along a direction orthogonal to the mounting plane and therefore may no longer be aligned with the second hole 28.

In this situation, the presence of the first elongated holes 27 ensures their alignment with the second hole 28.

Furthermore, the base structure comprises a ring 29 connected to the base body 2 in which the rack 22 is inserted. Even more particularly, this ring 29 is connected to a bar 4 (Figure 5).

In addition, this ring 29 has the second hole 28. In particular, the second hole 28 is spaced from the bar 4 on which the ring 29 is connected so as to facilitate the insertion of the pin of the second hole 28. In other words, the rack 22 is interposed between the second hole 28 and the bar 4 to which the ring 29 is connected. In other words, the rack 22, in correspondence with the second hole 28, is surrounded by the ring 29 and the bar 4.

Furthermore, in an alternative embodiment illustrated in Figure 6, the support structure 1 comprises a plurality of base bodies 2 side by side and a plurality of support bodies 3 each connected to a respective base body 2. In particular, the base bodies 2 are side by side along the axis of rotation R so that a bar 4 of a base body 2 is adjacent to a bar 4 of another base body 2 consecutive to the first.

Preferably, in this alternative embodiment, two adjacent bars 4 are constituted by a single bar 4.

Furthermore, the support bodies 3 are joined to form a single support body 3 mounted on the base bodies 2. In other words, the longitudinal members 8 extend for the entire length of the support structure 1. Furthermore, the cross members 9 are preferably in a number equal to the bars 4, where the adjacent bars 4 are counted as a single bar 4 (as described above). Furthermore, in this alternative embodiment, the adjustment means 10 comprise a plurality of pinions 18 and a plurality of racks 22 each associated with a respective pinion 18 to form a pinion-rack pair. In particular, each pinion-rack pair is arranged in correspondence with each bar 4 where the adjacent bars 4 are counted as a single bar 4 (as described above). In addition, the adjustment means 10 comprise a single shaft 30 extending along the longitudinal development axis at each base body 2 on which the pinions 18 are keyed (Figure 6).

The present invention also relates to a support kit 31 for solar collectors 100 comprising at least a support structure 1 of the type previously described and also comprising a maneuvering tool 32 connectable to the activation member 16 to move it.

In particular, the maneuvering tool 32 can be connected to the protruding portion 20 of the shaft 19 to make it rotate around its development axis (Figures 7 and 8).

Preferably, the maneuvering tool 32 comprises a gear reducer 33 connectable to the shaft 19. This reducer 33 is of a known type and therefore will not be described further below.

The reducer 33 comprises a first portion 34 which can be coupled to the shaft 19 and a second portion 35 which can be reversibly coupled to drive means 36. The reducer 33 operatively connects the second portion 35 to the first portion 34.

These actuation means 36 are part of the maneuvering tool 32 and can be reversibly coupled to the reducer 33 in correspondence with the second portion 35. Furthermore, the actuation means 36 comprise, in a first variant, motorized means for rotating, once coupled to the reducer 33, the shaft 19. Preferably, these motorized means comprise a drill. In a second embodiment variant, the drive means comprise a manual crank to rotate, once the crank is coupled to the reducer 33, the shaft 19.

As far as the operation of the support structure 1 is concerned, it derives directly from what has been previously described.

In particular, the support structure 1 is fixed to the ground or to the roof of a building to support a solar collector 100.

The support body 3 is positioned in one of the predefined positions depending on the period of the year of interest in order to make the absorption of solar radiation independent of the solar declination.

For operation, it is necessary to position the support body 3 in a first predefined configuration so that the mounting surface is in a corresponding predefined position. In this predefined position, the mounting plane is substantially orthogonal to the direction of propagation of solar radiation in a given period of the year. After positioning the support body 3 in a predefined configuration, it is necessary to lock the support body 3 in this configuration. To do this, the stop means 26 are used. In other words, the locking pin is inserted between a first hole 27 (the one corresponding to the chosen configuration) and the second hole 28.

Following the variation in the height of the sun over time, it is necessary to position the support body 3 in a second configuration corresponding to a second hole 28 made on the rack 22. Therefore, it is necessary to release the locking pin from the first hole 27 and from the second hole 28, move the support structure towards the first hole 27 of interest and constrain, by means of the locking pin, the support structure to the base structure.

To move the support body 3, it is necessary to act on the shaft 19 which, by rotating the pin meshed with the rack 22, rotates the support body 3.

To act on the shaft 19, the reducer 33, which can be connected to the drill, is used. The present invention achieves the intended purposes.

In particular, the support structure for solar collectors optimizes the absorption of solar radiation during the calendar year. In fact, the rotation of the support body allows the mounting plane to be oriented orthogonally to the direction of propagation of solar radiation. In this way, the absorption of solar radiation is independent of the declination of the sun.

Furthermore, the support structure for solar collectors is easily adaptable to any latitude without making substantial constructive modifications. In fact, to adapt the support structure to a certain latitude it is sufficient to orient the mounting plane according to the solar declination of the place.

It should also be noted that the present invention is relatively easy to implement and that even the cost associated with the implementation of the invention is not very high.

Claims (10)

CLAIMS 1. Support structure (1) for solar collectors (100) comprising: a base body (2) associable with a supporting surface; a support body (3) connected to the base body (2) and defining a mounting plane on which at least one solar collector (100) can be mounted; characterized in that it comprises adjustment means (10) operatively interposed between the support body (3) and the base body (2) to orient the mounting plane with respect to the base body (2) in a plurality of predefined positions. Support structure (1) according to claim 1 characterized in that the support body (3) is rotatably mounted on the base body (2) to rotate around a rotation axis (R) so as to define said positions mounting plane defaults. 3. Support structure (1) according to claim 2 characterized in that the adjustment means (10) comprise an activation member (16) for the rotation of the support body (3) mounted on the base body (2) and movable by a user; said adjustment means (10) also comprising a transmission member (17) operatively connected between the activation member (16) and the support body (3) to move the support body (3). 4. Support structure (1) according to claim 3 characterized by the fact that the activation member (16) comprises a pinion (18) rotatably mounted on the base body (2); said transmission member (17) comprising a rack (22) connected to the support body (3) and meshed with the pinion (18). 5. Support structure (1) according to claim 4 characterized by the fact that the rack gear (22) has an extension between two opposite ends (22a), (22b) connected to the support body (3); said rack (22) being, at least in part, shaped in an arc of circumference having the rotation axis (R) as its center. Support structure (1) according to any one of claims 4 to 5 characterized in that the adjustment means (10) comprise at least two pinions (18) and at least two racks (22) each meshed with a respective pinion (18 ); said adjustment means (10) further comprising a shaft (19) extending at least between the two pinions (18); said pinions (18) being keyed on said shaft (19). Support structure (1) according to any one of claims 4 to 6 characterized in that it comprises stop means (26) operatively interposed between the rack (22) and the base body (2) to lock the support body (3) at each of said predefined positions. 8. Support structure (1) according to claim 7 characterized in that it presents a plurality of first holes (27) positioned along the extension of the rack (22) in correspondence with each of said predefined positions, at least a second hole (28 ) arranged on the base body (2) in correspondence with the rack (22) and aligned with a first hole (27) when the support body (3) is in correspondence with each of said predefined positions, and to comprise at least one pin locking device which can be inserted between a first hole (27) and a second hole (28) to lock the support body (3) in correspondence with a predefined position; said first holes (27), said second hole (28) and said locking pin being part of the stop means (26). Support structure (1) according to any one of claims 4 to 8 characterized in that it comprises a plurality of base bodies (2) side by side and a plurality of support bodies (3) each connected to a respective body basic (2); said adjustment means (10) comprising a plurality of pinions (18) and a plurality of racks (22) each associated with a respective pinion (18); said adjustment means (10) further comprising a single shaft (30) extending at each base body (2) on which the pinions are keyed Support kit (31) for solar collectors (100) comprising at least one support structure (1) according to any one of claims 3 to 9 and further comprising a maneuvering tool (32) connectable to the activation member (16 ) to move it.