NL2034357B1 - Support structure for placing solar panels on a flat surface - Google Patents

Abstract

The invention relates to an assembly for a support structure for placing solar panels on a flat surface, a support structure, a solar panel structure and a method for placing solar panels on a flat surface. 5 The assembly comprises a number of pedestals for placement on the flat surface. Each pedestal comprises one or more uprights. For each upright, a bolt is provided for coupling to an upper end of the upright, a coupling element and a nut fitting on the bolt for clamping the coupling element onto the bolt. The coupling element comprises a coupling part with an opening for inserting the bolt through this opening, and a click part rotatably attached to the coupling part and adapted to form a click connection with a support rail. Fig. 2

Description

Support structure for placing solar panels on a flat surface

The invention relates to a support structure for placing solar panels on a flat surface. The invention also relates to an assembly for such a support structure. Furthermore, the invention relates to a solar panel structure and a method for placing solar panels on a flat surface.

Solar panels can be placed on a flat surface, such as a flat roof or directly on the ground surface. It is known to place pedestals on the flat surface, at some distance from each other, and then rest the solar panels on them. The edges of the solar panels are clamped to the top of the pedestals, by means of a clamp plate that is provided on the top of the solar panels and is secured in the pedestal with a bolt. However, it is necessary for the pedestals to be accurately aligned, because the edges of the solar panels must always rest exactly on the pedestals. This alignment is labor-intensive. A further disadvantage of this known support structure is that the attachment is not particularly sturdy, since the clamps are relatively small and only grip the edge of the solar panels, which means that there is a risk that the clamps will come loose and the solar panels will be damaged.

An object of the invention is to reduce the above disadvantages, or at least to offer an alternative. In particular, the invention aims to make it possible for a solar panel to be placed on a flat surface relatively easily and quickly.

This object is achieved by the assembly according to claim 1.

The assembly comprises a number of pedestals for placement on the flat surface, wherein each pedestal comprises one or more uprights. The assembly further comprises, for each upright, a bolt for coupling to an upper end of the upright, a coupling element for coupling a support rail to the upright, and a nut fitting on the bolt for clamping the coupling element onto the bolt. Each coupling element comprises a coupling part with an opening for inserting the bolt through this opening, and a snap-on part rotatably attached to the coupling part and adapted to form a snap-on connection with a support rail.

By means of the click connection (also known as: snap connection), support rails can be attached to the pedestals relatively easily and quickly. When such support rails are placed, they form a relatively large supporting surface for solar panels, which benefits the strength of the construction. Furthermore, it is not necessary to set the distance between the pedestals precisely. After all, the solar panels do not have to be placed exactly with their edge on the pedestals, as in conventional support structures. The entire length of the rails can serve as a supporting surface for the solar panels. This allows a solar panel to be placed relatively quickly and easily.

Because the click part is rotatable in relation to the coupling part, the pedestals do not have to be placed exactly parallel to each other. A certain degree of tilt in relation to each other can be compensated for because the click part is rotatable. Because the pedestals do not have to be placed exactly parallel, the installation time is reduced.

If the nut is not yet tightened, the coupling element can also be rotated around the bolt. This provides a further possibility for correcting non-fully aligned uprights, in addition to the rotation of the click part relative to the coupling part described above. After the desired position relative to the bolt has been set, the nut can be tightened to fix the coupling element in this position.

A further advantage of the click connection is that no special tools or parts are required. This also simplifies and speeds up the installation of solar panels.

For example, the bolt has a diameter of at least 10 mm (M10). For example, the bolt is made of stainless steel (RVS).

The bolt is preferably a bolt with a bolt head, more preferably a bolt head with a flange. The coupling element is in that case clamped between the bolt head of the bolt and the nut. This ensures a particularly firm attachment of the coupling element.

Preferably, each click part is designed to form a click connection that locks a carrier rail in the two directions perpendicular to its length, but allows sliding in the length direction of the carrier rail. This simplifies installation.

Preferably, each pedestal comprises at least two uprights. The pedestals comprise, for example, an elongated base for placement on the subsoil, to which the uprights, which are at some distance from each other, are connected. Preferably, the elongated base and the uprights are manufactured as a single unit, more preferably as a single part cast from concrete.

In one embodiment, each upright includes a screw hole at its upper end for screwing the bolt into.

In a further embodiment, the assembly comprises, for each bolt, at least one additional nut that can be screwed onto the bolt to secure the bolt in the screw hole.

For example, the assembly includes a lock nut or a nut in combination with a lock washer.

In particular, the at least one additional nut comprises two flange nuts for screwing the flange nuts onto the bolt with their flanges against each other. The flanges are preferably provided with serrations. These flanges with serrations ensure good locking of the bolt in the screw hole.

In one embodiment, the pedestals comprise concrete. This provides relatively heavy pedestals, so that the structure is firmly placed on the ground and can withstand gusts of wind. Preferably, each pedestal has a weight of 15 - 35 kilograms, although lighter or heavier pedestals are also possible.

In a further embodiment, the pedestals comprise concrete and each upright comprises a screw hole at its upper end for screwing the bolt into it, the screw hole being formed by a screw sleeve cast into the concrete.

In a further embodiment, the nut for clamping the coupling element is a flange nut, preferably provided with serrations. This ensures a particularly firm attachment.

In one embodiment, each pedestal comprises at least two uprights that differ in height for supporting a solar panel at an angle to the flat surface. Preferably, the upper surfaces of the at least two uprights are also at the said angle to the flat surface and these upper surfaces lie in the same plane.

The screw hole of each upright preferably extends perpendicularly (perpendicularly) to the upper surface of the upright. This creates an angle of the coupling elements and thus an angle of the support rails and a solar panel placed on them.

In one embodiment, the diameter of the opening in the coupling member is equal to the outer diameter of the bolt, so that the coupling member, when mounted on the bolt, extends perpendicular to the bolt.

Alternatively, the diameter of the opening in the coupling part is larger than the outer diameter of the bolt or the opening is designed as a slot. In the state in which the coupling element is not yet clamped to the bolt, there is then some play so that the coupling element can be tilted and/or displaced relative to the bolt. However, it is preferable to fix the coupling element in that case as well so that it extends perpendicularly (perpendicularly) to the bolt.

In one embodiment, the assembly also comprises support rails that can be connected to the click part of the coupling elements.

The invention further relates to a supporting structure for placing solar panels on a flat surface according to claim 13.

In particular, this supporting structure is constructed with the components of the assembly according to the invention. For example, in the above-described embodiments of the assembly in which the uprights comprise a screw hole, the bolt is inserted through the opening of the coupling part and screwed into the screw hole. In a further embodiment, at least one additional nut is provided on the bolt, whereby this at least one additional nut is screwed against the upright to secure the bolt in the screw hole.

Preferably, the coupling element is clamped to the bolt in such a way that the coupling element extends perpendicular to the bolt.

The invention also relates to a solar panel construction according to claim 15.

Finally, the invention relates to a method for placing solar panels on a flat surface according to claim 16. In one embodiment, the step of coupling the support rails to the pedestals comprises turning the rotatable click parts to place the support rails parallel to each other.

For example, before the step of clamping the coupling member to the bolt with the nut, the method includes the step of rotating the coupling member about the bolt to set the desired position of the coupling member relative to the bolt.

Further advantages, details and effects of the invention are explained below with reference to the figures, which show embodiments of the invention. — Figure 1 shows schematically a perspective view of a solar panel construction according to an embodiment of the invention; — Figure 2 shows an exploded view of a cross-section of an assembly according to an embodiment of the invention; — Figure 3 shows in a schematic top view a supporting structure according to an embodiment of the invention; and — Figure 4 shows an exploded view of a cross-section of an assembly according to an alternative embodiment of the invention.

Figure 1 schematically shows a solar panel construction 2. The construction 2 comprises two pedestals 4, 6 which are placed at a distance from each other on a flat surface 8. The pedestals 4, 6 each comprise an elongated base 10 which rests on the surface 8 and two uprights 12, 14 connected thereto which extend vertically from the base 10. The elongated base 10 and the uprights 12, 14 are manufactured as a single unit from concrete. The upper end of the uprights 12, 14 is each coupled to a support rail 16, 18. One or more solar panels 20 are placed on the support rails 16, 18. In figure 1 the one or more solar panels 20 are schematically shown as a single element, according to the invention however more than one solar panel can also be placed on the support rails 16, 18. The one or more solar panels 20 are attached to the support rails using means known to those skilled in the art, such as clamps that can be attached to the rails.

The upright 12 is higher than upright 14, so that the one or more solar panels 20 are placed at an angle, for example an angle of 20 to 50 degrees. The upper surfaces 22, 24 of uprights 12 and 14 show the same angle and lie in each other's extension. In other words, the upper surfaces of uprights 12, 14 lie in the same plane. 5 Figure 2 shows in detail how the support rail 16 is coupled to upright 12 of base 4. The support rails 16, 18 are coupled in the same way to upright 14 of base 4 and uprights 12, 14 of base 6. The upright 12 comprises a cast-in screw sleeve 24, which extends perpendicularly to the upper surface 22. A stainless steel

M10 bolt 26 fits into screw hole 24. Bolt 26 has a bolt head 28 which includes a flange 30 on the side facing the threaded end of bolt 26.

A coupling element 32 is provided which comprises a coupling part 34 and a snap-on part 36 rotatably attached to the coupling part 34. The snap-on part 36 is rotatable about an axis 38 which extends through an opening in the underside of the snap-on part 36. Optionally, the coupling part 34 is provided on its upper side with one or more cams (not shown) which limit the rotation of the snap-on part 36.

The coupling member 34 includes an opening 40 through which the bolt 26 fits. In the example of Figure 2, the diameter of the opening is larger than the outer diameter of bolt 26. Furthermore, an upper ring 42 is provided which has an opening 44 whose diameter corresponds to the outer diameter of bolt 26, and a lower ring 46 with an opening 48 whose diameter also corresponds to the outer diameter of bolt 26. In use, the coupling element 32 is attached to the bolt 26 by inserting the bolt 26 successively through opening 44 of the upper ring 42, opening 40 of the coupling member 34 and opening 48 of the lower ring 46, after which the coupling member 32 is clamped by screwing a flange nut 50 onto the bolt 26. This clamps the coupling part 32 and the rings 42, 46 between the flange nut 50 and the bolt head 28. The flange of the flange nut 50 has serrations (not shown) for a particularly solid attachment.

Because the opening 40 is larger than the outer diameter of the bolt 26, the coupling element 32 has some freedom of movement as long as the flange nut 50 has not yet been tightened.

Preferably, the coupling element is clamped in the position shown in which the coupling part 34 extends perpendicularly to the bolt 26. As a result, the bottom side of click part 36 also extends perpendicularly to bolt 26. When a support rail 16 is clicked into the click part 36, an upper surface 51 thereof - on which a solar panel is placed - will also extend perpendicularly to the longitudinal direction of bolt 26.

Two more flange nuts 52, 54 are provided for securing the bolt 26 in the threaded sleeve 24 of the upright 12. The flanges of these flange nuts 52, 54 have serrations (not shown). Flange nuts 52, 54 are screwed onto the bolt 26 with their flanges facing each other. After the bolt 26 has been screwed into the threaded sleeve 24, flange nut 54 is screwed against the top 22 of the upright 12 and then flange nut 52 is screwed against flange nut 54. The serrations of the flange nuts 52, 54 engage each other, so that the bolt 26 is secured in the threaded sleeve 24.

Figure 3 shows a schematic top view of the solar panel construction of figure 1, without solar panel. Figure 3 illustrates a situation in which the pedestals are not placed parallel to each other. In figure 3, pedestal 6 is drawn at a relatively large angle with respect to pedestal 4 for illustration, although in practice smaller angles will often occur. In any case, the support rails 16, 18 can also be attached parallel to each other to the uprights with such a non-parallel placement, because the click part 36 is rotatable with respect to the coupling part 34. In addition, an additional degree of freedom is obtained because, when the flange nut 50 has not yet been tightened, the coupling element 32 can rotate as a whole around bolt 26, and then be fixed in the desired position by tightening the flange nut 50. It is also clear from Figure 3 that the distance d between the pedestals 4, 6 does not have to be measured accurately, because the support rails 16, 18 can also be coupled with a larger or smaller distance between the pedestals 4, 6 for carrying solar panels 20.

Figure 4 shows a variation on the embodiment of figure 2. Parts that are the same as in figure 2 are provided with the same reference numeral and are not discussed in detail again. A difference compared to figure 2 is that a different type of coupling element 132 is used. This coupling element 132 has a coupling part 134 with a U-shaped cross-section. The legs of the U-shape form reinforcing ribs. The top side of coupling part 134 is substantially flat. At its end, coupling part 134 comprises a click part 136. Click part 136 corresponds to click part 36 from figure 2. Click part 136 is rotatably attached to coupling part 134 by means of shaft 138.

The coupling part 134 has an opening 140 with a diameter equal to the outer diameter of the bolt 26. In contrast to figure 2, no rings 42, 46 are provided in this case. Optionally, however, a ring, such as a lock ring, can also be provided for this variant between the bolt head 28 and coupling part 134 and/or between flange nut 50 and coupling part 134. These optional rings are designed, for example, as flat rings.

The invention is not limited to the above-described embodiments and examples. The rights sought are determined by the following claims.

Several variations are possible within the scope of the claims.

As described, in some embodiments the pedestals are made of concrete, to provide a certain weight, for example 15-35 kg. Alternatively or additionally, the pedestal may comprise one or more recesses for receiving weighting material, such as bricks, gravel or sand. This allows additional weight to be added to the pedestal, thus providing a solid construction that is resistant to gusts of wind.

As described, the bolt for coupling to an upper end of the upright is preferably a bolt with a bolt head. Alternatively, a stud bolt (also called threaded end) can be used, which can even be integrated with the upright. In that case, however, an additional nut must be provided for clamping the coupling element. In addition, the fastening is less firm than with a bolt with a bolt head.

That is why the inventors prefer to use a bolt with a bolt head instead of a stud bolt.

Figure 4 shows a coupling element 132 with a coupling part 134 with a U-shaped cross-section. Alternatively, the coupling part 132 is designed as a plate-shaped coupling part, that is, without the reinforcing ribs. For example, the plate-shaped coupling part is designed as a metal plate, for example of stainless steel. For example, such a plate-shaped coupling part has a thickness of 2-5 mm.

Claims (17)

CONCLUSIONS 1. An assembly for a support structure for placing solar panels (20) on a flat surface (8), comprising: a plurality of pedestals (4, 6) for placement on the flat surface (8), wherein each pedestal comprises one or more uprights (12, 14); and for each upright (12, 14): a bolt (26) for coupling to an upper end of the upright (12, 14); a coupling element (32, 132) for coupling a support rail (16, 18) to the upright (12, 14), the coupling element (32, 132) comprising a coupling part (34, 134) with an opening (40, 140) for inserting the bolt (26) through this opening (40, 140), and a snap-fit part (36, 136) rotatably attached to the coupling part (34, 134) and adapted to form a snap-fit connection with a support rail (16, 18); and a nut (50) fitting onto the bolt (26) for clamping the coupling element (32) onto the bolt (26). 2. Assembly according to any one of the preceding claims, wherein each upright (12, 14) comprises at its upper end a screw hole (24) for screwing the bolt {26) therein. 3. The assembly of claim 2, further comprising, for each bolt (26), at least one additional nut (52, 54) screwable onto the bolt (26) for securing the bolt (26) in the threaded hole (24). 4. Assembly according to claim 3, wherein the at least one additional nut comprises two flange nuts (52, 54) for screwing the flange nuts (52, 54) onto the bolt (26) with their flanges against each other, the flanges preferably being provided with serrations. 5. Assembly according to any one of the preceding claims, wherein the bases (4, 6) comprise concrete. 6. Assembly according to claim 5, in combination with one or more of claims 2-4, in which each upright (12, 14) comprises a screw sleeve (24) which is cast into the concrete and thus forms the screw hole. 7. Assembly according to one or more of the preceding claims, wherein the nut for clamping the coupling element (32, 132) onto the bolt (26) is a flange nut (50), preferably provided with teeth. 8. Assembly according to one or more of the preceding claims, wherein each pedestal (4, 6) comprises at least two uprights (12, 14) which differ in height for supporting a solar panel (20) at an angle to the flat surface (8). 9. Assembly according to claim 8, wherein the upper surfaces (22, 24) of the at least two uprights (12, 14) of each pedestal (4, 6) are also at said angle relative to the flat surface (8) and lie in the same plane. 10. An assembly as claimed in claim 9 in combination with any one or more of claims 2 to 4 or 6, wherein the screw hole (24) of each upright (12, 14) extends perpendicular to the top surface (22, 24) of the upright (12, 14). An assembly according to any preceding claim, wherein the diameter of the opening (140) in the coupling member is equal to the outer diameter of the bolt (26), such that the coupling member (132), when mounted on the bolt (26), extends perpendicular to the bolt (26). 12. Assembly according to any one of the preceding claims, which also comprises support rails (16, 18) which can be coupled to the click part (26, 126) of the coupling elements (32, 132). 13. A support structure for placing solar panels (20) on a flat surface (8), comprising: a plurality of pedestals (4, 6) spaced apart on the flat surface (8), each pedestal (4, 6) comprising one or more uprights (12, 14); and for each upright (12, 14): a bolt (26) coupled to an upper end of the upright (12, 14); a coupling element (32, 132) for coupling a support rail (16, 18) to the upright (12, 14), the coupling element (32, 132) comprising a coupling part (34, 134) with an opening (40, 140) through which the bolt (26) extends, and a snap-in part (36, 136) rotatably attached to the coupling part (34, 134) and adapted to form a snap-in connection with a support rail (16, 18); and a nut (50) screwed onto the bolt (26) clamping the coupling element (32, 132) to the bolt (26), the support structure further comprising support rails (16, 18) each connected to the snap-in parts (36, 136) of the coupling elements (32, 132) of at least two of the pedestals (4, 6) by means of the snap-in connection, so that the support rails (16, 18) form a framework for supporting solar panels. 14. A support structure as claimed in claim 13, wherein the coupling element (32, 132) extends perpendicular to the bolt (26). 15. Solar panel structure (2), comprising the supporting structure according to the preceding claim and at least one solar panel (20) mounted on the supporting rails (16, 18). 16. Method for placing solar panels (20) on a flat surface (8), comprising: providing an assembly according to any of claims 1-12; placing the pedestals (4, 6) on the flat surface (8), at some distance from each other; and for each upright (12, 14): inserting the bolt (26) through the opening (40, 140) of the coupling part (34, 134); clamping the coupling element (32, 132) onto the bolt (26) with the nut (50) fitting onto the bolt (26); coupling the bolt (26) to the upper end of the upright (12, 14), the method further comprising: coupling support rails (16, 18) to the pedestals (4, 6) to form a framework for supporting solar panels (20), wherein each support rail (16, 18) is coupled to one of the uprights (12) of a first pedestal and one of the uprights (14) of a second pedestal by forming a snap connection with the rotatable snap parts (36, 136) of the coupling elements (32, 132) coupled to the respective uprights (12, 14); and securing at least one solar panel (20) to the support rails (16, 18). 17. The method of claim 16, the step of coupling the support rails (16, 18) to the pedestals (4, 6) comprising rotating the rotatable snap-in members (36, 136) to position the support rails (16, 18) in parallel.