NL2002778C2 - TILTABLE CARRYING DEVICE FOR SOLAR PANELS. - Google Patents

Description

Tiltable carrying device for solar panels

The invention relates to a support device for elements intended for receiving and / or reflecting and / or focusing solar radiation, for example 5 solar cells, solar collectors, mirrors, lenses and the like, comprising a main frame of longitudinal beams extending parallel to each other and transversely to the longitudinal beams extending transverse beams, auxiliary frames rotatably mounted on the main frame for the elements, as well as a support structure which engages two of the horizontal beams.

Such a carrying device is known, such as from EP-A-1988344, and is positioned in such a way relative to the sun that as much of the solar radiation as possible can be usefully used for generating electric current or heat. The auxiliary frames can thereby follow the course of the sun during the day, so that the sun's rays have the greatest possible effect.

15 Depending on the season, the sun is more or less far above the horizon.

This is taken into account by placing the frame in an inclined position with respect to the earth's surface.

The energy generated by solar radiation must be able to compete to some extent with traditional forms of energy generation, such as by means of hydrocarbons, nuclear energy and hydropower. In that connection, the efficiency of the total installation by means of which energy is obtained from solar radiation is important. This efficiency depends primarily on the energy efficiency of the energy converters, such as solar cells. In addition, the efficiency of the device is determined by the orientation of the energy converters relative to the sun. The extent to which they always remain oriented in the correct position with respect to the sun, that is to say the position in which they can absorb or reflect as much sunlight as possible or reflect or focus, is to a large extent a determining factor for the optimum operation of solar cells and the like.

It must therefore be possible to move the energy converters around 30 different axes of rotation. In connection with the realization of these possibilities of movement, carrying devices have already been proposed, all of which, however, are rather complicated or have a heavy design. Because such carrying devices are arranged in the open air, they must be able to withstand all kinds of weather influences that cause high loads. For example, wind load and 2 snow load and the like. Therefore, it is inevitable that the support devices must meet certain requirements with regard to strength and rigidity. The requirement of stiffness is also important because the desired orientation with respect to the sun may not be influenced by the wind load that acts on the carrying device.

5 That is why it is unavoidable to invest in a supporting structure that meets these requirements, but at the same time these investments have an impact on the financial return that can be achieved with solar energy. Capital-intensive investments have a major influence on this, and therefore not only the costs of the energy converters themselves are important, but also the costs of the support device.

The object of the invention is therefore to provide a carrying device which, on the one hand, meets the requirements cited above with regard to adjustability, strength and stiffness, but which is also attractive from a financial point of view. This object is achieved in that the support construction comprises at least one set of legs, one end of which is attached to a longitudinal beam and the other end of which is supported with respect to a surface, the ends of the extreme legs of the set attached to the longitudinal beam are spaced apart from one another by a greater distance than the ends of said extreme legs supported with respect to the ground, and the ends of the legs are pivotable according to a pivot axis that is parallel to the longitudinal direction of the longitudinal members.

The support of the main frame by means of several legs has several advantages. First of all, such legs can be designed in an economic manner, for example in the form of hollow rods which can be mass-produced to the desired length. The attachments of legs designed as hollow rods can easily be obtained by forming the ends 25 into securing lips. , or by fitting attachment fittings at the ends. Other options include solid bars, half-timbered posts and the like. By causing the legs to engage regularly on the main frame, this can be favorably supported such that the main frame can be of relatively light design.

Furthermore, the ends supported with respect to the substrate can essentially lie against each other, such that they can be supported at one and the same point relative to a substrate. Alternatively, the ends of the legs may cooperate with a separate mounting element, such as a mounting block. The respective ends are clamped, for example, against such a fixing block which in turn is supported on the substrate. In particular, the substrate can be formed by a horizontal or sloping piece of land, but it is also possible to select a vertically oriented substrate in the form of, for example, a wall or wall of a building. The number of support points on that surface can therefore remain limited, which also entails cost benefits. A particularly strong support can be obtained if the ends supported with respect to the substrate are essentially pressed in the direction towards each other or are clamped, possibly with the aforementioned fixing element interposed.

The fixings between the legs and the base and the main frame can be made in different ways. According to a first possibility, these attachments can be rigid, such that a very rigid and relatively light construction is obtained. However, it is not necessary to rigorously carry out all confirmations. In particular, certain fixings can also be designed as rotations permitting, such that the internal stresses in the structure can be limited or omitted. In addition, it is possible to make all confirmations as rotations permitting confirmations. In particular, the ends of the legs can herein be hinged according to a hinge axis that is parallel to the longitudinal direction of the longitudinal members. If a separate fastening element is used, it can be hingedly attached to the substrate while the ends of the legs themselves are rigidly attached to the fastening element.

In the latter embodiments, the main frame can be made tiltable, such that the height of the sun can be taken into account. In that case, each longitudinal beam can be hingedly supported with respect to the ground according to a hinge axis parallel to the longitudinal direction of the longitudinal beams. In addition thereto, operating means can also be provided for influencing the angular position of the main frame around a rotation axis parallel to the longitudinal direction of the longitudinal beams. However, it is also possible to omit operating means, such that from time to time the main frame can be adjusted and can be blocked in the desired adjusted position by suitable blocking means.

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The operating means can be designed in many different ways; the operating means may preferably comprise an elongated operating element which is movable back and forth in its longitudinal direction and extends transversely to the longitudinal direction of the longitudinal members, to which operating element the legs are attached. The operating element can for instance be designed as a pull cable or as a double pull cable for moving the sets of legs back and forth. The operating element is preferably a rod which is slidably supported in the longitudinal direction, for example in longitudinal guides, to which rod a clamp is attached which is connected via a hinge to the ends of the legs situated at a smaller distance from each other. By means of such a rod the sets of legs can be moved in both directions.

The support structure can comprise at least two sets of legs next to each other and a corresponding number of operating elements next to each other, each set of legs being attached to a respective operating element.

The device according to the invention as described above can be combined with arbitrary numbers of further devices, depending on the desired capacity that is being sought. The invention therefore also relates to an assembly comprising at least two devices which are located one behind the other such that the longitudinal direction of their longitudinal beams is oriented parallel, and the operating element extends transversely to said at least two devices such that of both devices the smaller spaced ends of the legs are in each case attached to the operating element.

The invention further relates to an arrangement, comprising a carrying device as described above, as well as elements intended for processing or using solar energy, such as receiving or reflecting or focusing solar radiation, for example solar cells, solar collectors, mirrors and the like, which elements are mounted on the auxiliary frames. Such arrangements can also be combined with several at the same time into an assembly that can be operated in common.

The invention will be described in more detail below with reference to an exemplary embodiment shown in the figures.

Figure 1 shows a perspective view of a carrying device obliquely from the front and from above.

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Figure 2 shows a perspective view of an assembly of several carrying devices one behind the other, obliquely from behind and from above.

Figure 3 shows a rear view of a carrying device.

Figure 4 shows a cross section of a carrying device.

Figure 5 shows the detail according to V of Figure 4 on a larger scale.

Figure 6 shows the detail of Figure 5 in perspective.

Figure 7 shows the detail VII of Figure 4.

Figure 8 shows the carrying devices according to the view of Figure 2 in the adjusted state.

Figure 9 shows the carrying devices according to the view of Figure 4 in the adjusted state.

The device shown in Figs. 1-3 has a main frame 1 consisting of the side members 2 and the cross members 3 which connect the side members to each other. Furthermore, the strut 14 is attached to the side members 2. This strut 14 is oriented obliquely 15, such that the main frame 1 is shear-stiff in the plane defined by the longitudinal and transverse beams. On the main frame f the auxiliary frames 5 are supported in the bearing blocks 24 with pivot bearings 6 as shown in figures 5 and 6. These auxiliary frames each consist of a support 7 with arms 8 arranged regularly spread thereon, the panels 9 are mounted on these arms, in this case with photovoltaic cells. By means of the adjusting device, the adjusting rod 10 of which is shown in Figures 1-4, the auxiliary frames 5 with the panels can be rotated in an oblique position around the axis of the carriers 7, depending on the position of the sun.

The main frame 1 is supported on a base by means of the girders 11. The low-lying longitudinal girder 2 is supported pivotably on the girders 11 via nodes 4 to be described later. The high-lying longitudinal beam 2 is supported by means of the rods 12 and 13. Certain of these rods 13 are oriented perpendicularly to the longitudinal beams 2 in the rear view of Fig. 3, the other rods 12 vary obliquely. The rods 12, 13 have flattened attachment lips 23 at both ends (Figs. 5, 6). The lower end of the rods 12,13 is rotatably attached to the operating rod 28 by means of hinge 27 and clamp 31. 29 consist of a bracket 33, in which diabolo-shaped guide rollers 32 are rotatably received one above the other, 6 being supported movably between the operating rod 28. The driving device 30 makes it possible to move the operating rod 28 back and forth, as will be further explained below.

Each of the rods 12,13 is pivotally attached to the high-lying longitudinal beam 2 by a node 4 as shown on a larger scale in figures 5 and 6. The nodes 4 each consist of two fitting pieces 15, 16, between which a longitudinal beam 2 is clamped by means of a bolt connection 17. The fitting pieces have ridges 18 between which the longitudinal beam 2, designed as a C-profile, is held captive. Furthermore, they have mounting flanges 19 to which in each case a flattened mounting lip 23 of the rods 20 is attached. These two rods 20 together form the cross member 3. The lower fitting piece 16 furthermore has a support flange 21 to which the securing lip 23 of the rod 12, 13 is attached by means of the hinge 25.

The upper fitting piece 15 has an upright bracket 22 on which the pivot bearing 6 is mounted. The carriers 7 and thus the auxiliary frames 5 with panels 9 are thus mounted at a certain height above the main frame 1, such that rotations thereof are possible around the axis of the carriers 7.

The low-lying longitudinal beam 2 is also supported by such a node 14 on a pole 11, the supporting flange 21 then being directly attached thereto by means of hinge 26 without the intervention of a rod. Furthermore, the lower ends of the obliquely upwardly extending rods 12 are attached to those nodes 4. The lower end of the slanted strut 14 is also attached to one of those nodes.

By moving the aforementioned operating rod 28 back and forth, the lower node 4 where the rods 12, 13 meet also is shifted back and forth. Depending on the position of those nodes 4, the tilt of the main frame 1 can be influenced, as will be explained below with reference to Figures 8 and 9.

The connection between the longitudinal beams 2 and the carriers 7 is always made with such nodes 4. At some of those nodes 4, however, the mounting flanges 19 remain unused because the sleepers 3 and rods 20 are missing there. Also, the support flanges 21 are not always used: some of the nodes 4 on the low-lying longitudinal girder 2 only function as a connection 7 between the carriers 7 and the longitudinal girder 2. Nevertheless, for every connection between main frame 1, auxiliary frames 5 and rods 12,13 14 and 20, one and the same node 14 are used, which considerably simplifies construction and makes it more economical.

In figures 8 and 9, the carrying devices of the assembly are adjusted by moving the operating rod 28 to the left, as seen in figures 4 and 9. The supporting devices have thereby moved over to the position shown in Figures 2 and 4 to the flatter position of Figures 8 and 9. In that flatter position, the solar cells and the like are better directed with respect to a high standing sun 10 (seasonal influence). The auxiliary frames 3 are also rotated around the carrier 7, such that the sun can be followed during the day.

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List of reference marks 1. Main frame 2. Longer girder 5 3. Cross girder 4. Node 5. Auxiliary frame 6. Pivot bearing 7. Carrier 10 8. Arm 9. Panel 10. Adjustment rod 11. Sturdy 12. Rod 15 13. Rod 14. Strut 15. Fitting piece 16. Fitting piece 17. Bolt connection 20 18. Ledge fitting piece 19. Fixing flange 20. Cross beam 21. Clamping flanges 22. Spacer 25 23. Fixing lip 24. Bearing block 25. Hinge axis 26. Hinge 27. Hinge axis 30 28. Control rod 29. Guide rod 30 Guide rod drive 31. Clamp on control rod 9 32. Guide roller 33. Bracket 5

Claims (15)

1. Supporting device for elements (9) intended for receiving and / or reflecting and / or focusing solar radiation, for example solar cells, solar collectors, mirrors, lenses and the like, comprising a main frame (1) of longitudinal beams (2) parallel to each other extending side by side and transversely extending transversely to the longitudinal girders (3), auxiliary frames (5) pivotally arranged on the main frame (1) for the elements (9), as well as a support structure (11-14) which engages two of the horizontal girders , characterized in that the support structure comprises at least one set of legs (12, 13), one end of which is each attached to a longitudinal girder (2) and the other end of which is supported relative to a base, the longitudinal girder (2) attached ends (23) of the extreme legs (12) of the set are spaced apart from each other by a distance greater than the ends (23) of said extreme legs 15 (12), and the ends (23) of the legs (12, 13) are pivotable according to a pivot axis (25, 27) that is parallel to the longitudinal direction of the side members (2). 2. Device as claimed in claim 1, wherein the ends (23) supported with respect to the substrate lie essentially against each other and / or against a fastening element 20. Device as claimed in claim 1 or 2, wherein the ends (23) supported with respect to the substrate are essentially held in the direction towards each other or are clamped. 25 Device as claimed in any of the foregoing claims, wherein the ends (23) attached to the longitudinal beam (2) are regularly distributed at approximately equal distances from each other. Device as claimed in any of the foregoing claims, wherein the legs comprise hollow rods (12, 13). Device as claimed in claim 5, wherein the ends of the rods (12,13) comprise fixing lips (23) which are oriented at an angle with respect to the longitudinal direction of the respective hollow rod which is related to the position of said hollow rod between the substrate and the side member. 5 Device as claimed in any of the foregoing claims, wherein each longitudinal beam (2) is hingedly supported with respect to the ground according to a hinge axis (25, 26) parallel to the longitudinal direction of the longitudinal beams (2). Device as claimed in any of the foregoing claims, wherein operating means (28-30) are provided for influencing the angular position of the main frame (1) about an axis of rotation parallel to the longitudinal direction of the side members (2). 9. Device as claimed in claim 8 when dependent on claim 7, wherein the operating means comprise an elongated operating element (28) which is movable back and forth in its longitudinal direction and extends transversely to the longitudinal direction of the longitudinal members (2), to which operating element (28 ) the legs (12, 13) are hinged. Device as claimed in claim 9, wherein the operating element comprises a rod (28) which is slidably supported in the longitudinal direction, for example in guides (29), to which rod (28) a clamp (31) is attached which is connected via a hinge (27) is connected to the ends (23) of the legs (12,13) supported on the substrate and located at a smaller distance from each other. 25 Device as claimed in any of the foregoing claims, wherein the axis of rotation of the auxiliary frames (5) is directed transversely to the longitudinal direction of the longitudinal beams (2). 12. Device as claimed in any of the foregoing claims, wherein the legs (12, 13) of each set extend obliquely towards each other from the longitudinal beam to which that set is attached. Device according to any one of the preceding claims, wherein the support structure comprises at least two sets of legs (12, 13) next to each other and a corresponding number of operating elements (28) next to each other and each set of legs is attached to a respective operating element. 5 An assembly comprising at least two devices according to claim 9 or 10 which are located one behind the other such that the longitudinal direction of their longitudinal beams (2) is parallel, and the operating element (28) extends transversely to said at least two devices such that of both devices, the ends (23) of the legs (12, 13) located at a smaller distance from each other are attached to the operating element (28) in each case. 15. Arrangement, comprising a carrying device according to any of claims 1-13 and elements (9) intended for processing solar energy, such as for recording and / or reflecting and / or focusing solar radiation, for example solar cells, solar collectors, mirrors, lenses and the like, which elements are arranged on the auxiliary frames (5).