CZ20127U1 - Supporting structure of photovoltaic devices for hard surfaces - Google Patents

Abstract

The supporting structure for photovoltaic devices for stiffened surfaces, for flat roofs advantageously, consists of metal beams. The supporting beam (1), inclined at an angle of 10 to 45° with respect to the horizontal plane is fastened to the leg (4) in the higher located rear part of said beam. The lower situated front part of the supporting beam (1) is fastened to the front grip (7). The supporting beam (1) is adapted for fastening of at least one assembling beam (5) and/or of a solar panel (6). The whole supporting structure is fastened to a stiffened surface directly and/or by means of an auxiliary frame. The supporting structure is joined to at least one side- adjacent supporting structure by means of at least one assembling beam (5) and/or of one front transverse girder (2) and/or at least one rear transverse girder (3) and/or at least one auxiliary brace (8).

Description

Supporting structure of photovoltaic systems for hard surfaces

Technical field

The technical solution relates to a supporting structure for solar panels and falls within the field of mounting or supporting devices for solar panels.

BACKGROUND OF THE INVENTION

Supporting structures for solar panels are known in many variants and designs. So far, however, load-bearing structures are mainly used in unpaved terrain. Such structures, preferably mounted on drill bases, are known, for example, from CZ 19145 or CZ 19663. The support structures described herein consist of a basic triangular structure built on two legs and differ from each other by the angle of position and the shape of the basic triangular structure. Instead of installing them on drilling bases, these structures can be installed on anchors fixed to the paved surface. Such hard surfaces are mostly unused airports and concrete areas in old industrial sites. However, the application of these structures to paved surfaces is not very advantageous for their unnecessarily robust and thus costly construction. The robustness and heavier weight of these structures may be a problem when installed on roofs of buildings.

These deficiencies are solved by a lightweight structure according to the proposed technical solution, which can be used on hard surfaces, especially on flat roofs.

The essence of the technical solution

The essence of the technical solution is to create a stable load-bearing structure using a minimum of structural parts. Since the described load-bearing structure is also advantageously useful for installation on roofs, the low weight of such a structure is also important.

The bearing profile is situated obliquely to the horizontal in the structure, taking into account the intended geographical area of application of the structure and the height of the Sun above the horizon in this area. The bearing profile is inclined in the range of 10 ° to 45 ° with respect to the horizontal, for Central Europe inclinations of around 25 ° are used. The support profile is attached to the leg in its rear, above-facing part. In its front, lower part, the support profile is attached to the front grip.

The support profile is adapted to attach at least one mounting profile and / or solar panel. In practice, as a rule, the support profile has at its upper edge a plurality of holes which are used for rectifying the mounting profile and / or solar panel. It is also possible to consider a variant of one elongated hole instead of several circular holes. Although such a variant is more difficult to manufacture, it provides the possibility of more accurate rectification of the mounting profile and / or solar panel. Furthermore, it is possible to mount the mounting profile and / or the solar panel to the support profile, for example by means of a conventional U-clamp, and the like. As an assembly profile, an aluminum prefabricated profile, open at its upper edge, is generally used.

The support structure is connected to at least one adjacent support structure. The connection of the load-bearing structures is usually made by one front cross member connected to the front anchorages of the structures, and one rear cross member connected to the legs of the structures. Furthermore, the individual load-bearing structures can be connected to each other by means of a mounting profile and / or a solar panel or an auxiliary reinforcement. The auxiliary reinforcement is used to reinforce structures against side effects, so-called bracing. The auxiliary reinforcement is usually in the form of a cross, it can be made, for example, of metal profiles or steel cables. In the case of a series consisting of a plurality of load-bearing structures, the auxiliary reinforcement is generally situated between the extreme pairs of load-bearing structures at the beginning and at the end of the row. Other auxiliary reinforcements are then usually used in every second gap between the structures. The joining of load-bearing structures in a repeated combination also seems to be advantageous:

-1 EN 20127 U1 supporting structure - front cross member and rear cross member - supporting structure - auxiliary reinforcement - supporting structure - front cross member and rear cross member - supporting structure ... On this series are mounted mounting profiles with fitted solar panels and / or here placed solar panels directly.

The entire supporting structure can be firmly attached to the paved surface directly or via a subframe. Fastening can be solved directly by using common fasteners (eg screws and so-called chemical anchors) at the bottom of the front anchor and foot. If the structures are connected to each other by the front cross member and the rear cross member, it is also possible to attach these cross members to the reinforced surface on which the supporting structures are fixed. Attachment via subframe is used especially in case of installation of load-bearing structures on flat roofs with trapezoidal surface, when it is necessary to distribute the weight of the load-bearing structures to prevent deformation and damage of the trapezoids. If the load-bearing capacity of the roof permits, it is possible to attach the load-bearing structures to the concrete blocks placed on the roof. This ensures sufficient resistance of the supporting structures to the weather conditions.

The front grip can alternatively have the shape of a foot, respectively. the front anchorage can be supplemented with a foot. Such a solution is used when the load-bearing profile is required to be placed above the roof covering.

Another variant is to adjust the angle of the supporting profile for winter and summer.

In this case, the support profile is secured to the front anchorage by means of a pin with a horizontal axis of rotation perpendicular to the support profile. The leg located at the rear of the structure is in this case adjustable in length and / or the leg is replaceable. It is advisable to select the leg attachment to the support profile as sliding, which ensures the verticality of the leg when the inclination of the support profile changes.

If the structure is designed for larger, respectively. heavier solar panels, one or more bottom stiffeners may be used between the support profile and the foot to provide sufficient load-bearing capacity. The lower reinforcement is used even if the structure is made of insufficiently thick profiles, or if its use is planned in areas with strong weathering.

For the purposes described above, the construction can be completed with at least one additional leg. The additional legs may be connected to the other legs of the structure and / or with each other.

BRIEF DESCRIPTION OF THE DRAWINGS

An exemplary embodiment of the proposed solution is described with reference to the drawings, in which: Fig. 1 is a side view of a basic structure; Fig. 2 is a front view of a series of four connected supporting structures; Fig. 3 is a side view of an adjustable structure with length; Fig. 4 - front view of two structures connected by crossbars and auxiliary reinforcement, fig. 5 - side view of supporting structure with additional foot and lower reinforcement.

Examples

Example 1

According to the proposed technical solution, a series of four load-bearing structures was made. Each support structure has a support profile 1 situated at an angle to the horizontal, in this case at an angle of 25 °. The lower part of the foot 4 is welded to the rear cross member 3. The front, lower part of the support profile 1 is fixed to the front grip 7, and this connection is also designed as a screw. The front grip 7 is welded to the front crossbeam 2. The front crossbeam 2 and the rear crossbeam 3 connect the individual structures to each other and at the same time serve to attach them to the substrate, in this case formed by concrete blocks.

The support profile 1 has circular holes formed at its upper edge for attaching two mounting profiles 5. These circular holes are in two series of four holes, one series of holes located closer to the front of the support profile 1 and the other series of holes closer to the rear Supporting profile L Each series of holes serves to fix one mounting profile 5 and its rectification. A photovoltaic solar panel 6 is attached to the mounting profiles 5.

Between the second and third supporting structures of this series, an auxiliary reinforcement 8 is used, in this case formed of two metal profiles, situated and connected in the shape of a cross. By using the auxiliary reinforcement 8, at this point a number of supporting structures are sufficiently strengthened, so it is not necessary to use a front cross member 2 and a rear cross member 3 here.

The solution described is evident from Fig. 1 and Fig. 2.

Example 2

According to the proposed technical solution, two load-bearing structures were made. Both support structures have a support profile 1 adjustable in relation to the horizontal, in this case between 20 ° and 30 °. The rear, upwardly facing portion of the support profile 1 of each structure is attached to the length adjustable leg 4. In this case, the connection of the support profile 1 and the leg 4 is slidable. The lower part of the leg 4 is welded to the rear cross member 3. The front, lower part of the support profile 1 is fixed to the front bracket 7, this connection being made by means of a pin 9 with a horizontal axis of rotation perpendicular to the support profile 1. The front cross member 2 and the rear cross member 3 connect the two structures to each other and at the same time serve to attach them to the substrate, in this case formed by concrete blocks.

The support profile 1 has circular holes formed at its upper edge for attaching two mounting profiles 5. These circular holes are in two series of four holes, one series of holes located closer to the front of the support profile 1 and the other series of holes closer to the rear Supporting profile L Each series of holes serves to fix one mounting profile 5 and its rectification. A photovoltaic solar panel 6 is attached to the mounting profiles 5.

Between the two structures an auxiliary reinforcement 8 is used, in this case consisting of two metal profiles situated and connected in the shape of a cross.

By this variant solution of the supporting structure, the inclination of the supporting profile 1 with respect to the horizontal is adjustable. This is advantageous in view of the different height of the Sun above the horizon in winter and summer months.

The solution described is evident from Fig. 3 and Fig. 4.

Example 3

According to the proposed technical solution, two load-bearing structures were made. Both supporting structures have a supporting profile 1 situated obliquely to the horizontal, in this case at an angle of 25 °. The rear, upwardly facing portion of the support profile 1 is attached to one, vertically situated leg 4. In this case, the connection is made as a screw connection. The lower part of the leg 4 is welded to the rear cross member 3. The front, lower part of the support profile 1 is fixed to the front grip 7, and this connection is also designed as a screw. The front grip 7 is welded to the front crossbeam 2. The front crossbeam 2 and the rear crossbeam 3 connect the individual structures to each other and at the same time serve to attach them to the substrate, in this case formed by concrete blocks.

In order to ensure greater load-bearing capacity, each structure is complemented by one additional leg 11 and one lower stiffener 10, which are situated below the support profile 1. The additional legs 11 of both structures are connected to each other by a cross beam attached to the substrate.

The support profile 1 has circular holes formed at its upper edge for attaching two mounting profiles 5. These circular holes are in two series of four holes, one series of holes located closer to the front of the support profile 1 and the other series of holes closer to the rear Supporting profile L Each series of holes serves to fix one mounting profile 5 and its rectification. A photovoltaic solar panel 6 is attached to the mounting profiles 5.

Between the two structures an auxiliary reinforcement 8 is used, in this case consisting of two metal profiles situated and connected in the shape of a cross.

The solution described is evident from Figs. 4 and 5.

Claims (6)

PROTECTION REQUIREMENTS Supporting structure of photovoltaic systems for paved surfaces, preferably for flat roofs, consisting of metal profiles, characterized in that the support profile (1), which is inclined at an angle of 10 ° to 45 ° to the horizontal, is in its rear, the aforementioned part being attached to the foot (4), and the front, the downwardly facing part of the support profile (1) is fixed to the front grip (7), and further that the support profile (1) is adapted to attach at least one mounting profile (5); and / or of the solar panel (6), wherein the entire support structure is attached to the paved surface directly and / or through the subframe and at the same time the support structure is connected to the at least one laterally adjacent support structure by at least one mounting profile (5) and / or at least one a front cross member (2) and / or at least one rear cross member (3) and / or at least one auxiliary reinforcement (8). Supported structure of photovoltaic systems for hard surfaces according to claim 1, characterized in that the front bracket (7) is shaped as a foot (4). Supporting structure of photovoltaic systems for hard surfaces according to claims 1 and 2, characterized in that the support profile (1) is attached to the front bracket (7) by a pin (9) with a horizontal axis of rotation that is perpendicular to the support profile (1). 1), and that at the same time the leg (4) located at the rear of the support structure is adjustable in length and / or the leg (4) is replaceable. Supporting structure of photovoltaic systems for reinforced surfaces according to claims 1 to 3, characterized in that the foot (4) is slidably attached to the support profile (1). Supporting structure of photovoltaic systems for hard surfaces according to claims 1 to 4, characterized in that in the space below the foot profile (1) the support structure has at least one lower reinforcement (10). Supporting structure of photovoltaic systems for paved surfaces according to claims 1 to 5, characterized in that the support profile (1) is supported by an additional foot (11).