CZ2008550A3 - �Fixed as well as positionable load-bearing structure of photovoltaic devices - Google Patents

Abstract

Fixed and positioning support structure of photovoltaic devices, preferably for anchoring to the drilling base (8) and to the fixtures (12) for installation on the reinforced surfaces, consists of a rear leg (5), a front leg (9), a rear strut (4), inclined struts (6) and supporting profile (1). The internal angles in the triangle formed by the supporting profile (1), the inclined brace (6) and the rear brace (4) are 60.degree. with tolerance. + -. The distance between the upper part of the rear strut (4) and the center axis (O) is smaller than the distance between the lower part of the rear strut (4) and the center axis (O). The inclined brace (6) is situated such that the connection of the front leg (9) to the inclined brace (6) is higher than the connection of the inclined strut (6) to the rear leg (5). The connection of the rear leg (5) and / or the front leg (9) to the rest of the structure is sliding or non-moving.

Description

Fixed and positioning supporting structure of photovoltaic systems

Technical field

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

BACKGROUND OF THE INVENTION

Supporting structures for solar panels are known in many variants and designs. Rigid structures generally have two legs which are connected to each other by at least one inclined strut and furthermore generally comprise at least one rear strut and a supporting profile. Longitudinal struts can be attached to the support profile connecting the individual structures to each other, whereby solar panels are then placed on these longitudinal struts. The structures are usually designed only from the static point of view, without significant effort to lighten the structure and save the material used.

Widely used are structures bolted on site from individual pipes or profiles. These individual tubes and / or profiles are joined by means of screw connections and clips. However, this solution is relatively expensive due to the nature of the components used and, moreover, does not necessarily guarantee sufficient stability, for example when using larger solar panels.

For example, a rigid support structure enjoying industrial protection is described in DE20311967U. A metal support structure having a trapezoidal side view is described herein. The solar panels are fastened with screws to the top of the structure, which also rests on spacers. Below these spacers is a plastic base plate which is shaped to have flat areas separated by protruding semicircular portions. Spacers are mounted on these protruding semicircular portions. The plastic base plates may optionally be located below the ground surface and their edges may overlap one another. The disadvantage of this solution is, firstly, the shape of the metal bearing structure itself, which requires a relatively strong material, and secondly, the use of plastic baseplates, for which extensive earthworks are required.

The positioning structures used for different solar panel slopes in summer and winter months are also currently solved in many ways. One of these is described, for example, in DE20319065U. The construction here for several solar panels has as many feet as there are solar panels on the construction. The legs are connected by a horizontally placed pivot axis. Perpendicular to this rotary axis there are several rungs between which solar panels are inserted. The swivel bar then passes under the solar panels approximately halfway through their length. The disadvantage of this solution is the necessity of a large number of feet recessed into the ground, where one foot of the solar panel is one foot.

Another possible solution for the positioning of solar panels are devices adjustable in two axes (horizontal and vertical), so-called tractors. However, these are by their nature solved completely differently from the proposed supporting structure and are therefore not further described in this document.

The proposed technical solution presents a stable load-bearing structure with maximum possible lightening. The structure is primarily designed to be rigid, but during production it can be made positional with minor modifications. All this has a positive impact on the final price of the product. The structure can be used for installation on open areas or roof surfaces.

The essence of the technical solution

The main essence of the technical solution is to use the weakest (and thus the cheapest) parts of the structure in conjunction with maintaining the ideal distribution of angles in the structure, which allows maintaining the necessary load-bearing capacity and stability.

The internal angles in the triangle formed by the support profile, the inclined strut and the rear strut are equal, each of these angles being 60 °, with a tolerance of ± 5 °. This triangle is rotated in the structure such that, when viewed laterally, the upper portion of the rear strut is closer to the median axis than the lower portion of the rear strut. The inclined strut is also situated such that the connection of the front leg with the inclined strut is higher than the connection of the inclined strut to the rear leg. In the support profile there are openings for the placement of clips used for attaching the longitudinal struts connecting the individual structures several meters apart. The solar panels are mounted on these longitudinal struts.

The variant has a U-profile of approx. 60 mm x 40 mm, which has sufficient load-bearing capacity to maintain the weight of the solar panel. At the point of contact with the inclined strut and at the point of contact with the rear strut, the support profile is then always supported by one reinforcement to distribute the point pressure at the contact point over a longer length of the support profile. The designs according to the proposed technical solution are advantageously used in combination with drilling bases (PV 2008-522). In case the drilling bases are located inaccurately in the ground (especially in stony ground) and the distance of their ends would not correspond to the spacing of the legs of the structure, it is possible to use a variant solution of the base where at least one leg is sliding on the inclined strut. In this way it is possible to adjust the spacing of the legs for different distances of the drilling bases or possibly other columns or mounts.

Another variant of the construction is the positioning construction, which can be positioned so that the longitudinal axis of the supporting profile can be continuously adjusted in the range of approximately 30 ° - 50 ° compared to the horizontal, according to the customer's wishes. The positioning construction differs from the solutions described above in attaching the front leg and the rear leg to the rest of the structure. The rear leg is attached to the rest of the structure using a pivot pin. The pivot has its longitudinal axis of rotation situated horizontally, perpendicular to the inclined strut. The front leg is slidably attached to the inclined strut. The sliding attachment can be solved using a conventional screw clamp or with a positioning plate and a glider with a clamping plate. In this case, the positioning plate is rigidly connected to the inclined strut, either from the bottom or top side. The positioning plate is provided with at least two pairs of holes such that the holes are on those two sides of the positioning plate that are parallel to the inclined strut. The front leg is fitted with a glider with a clamping plate at its upper end. The glider has a hemispherical shape on the side cross-section. Below the glider there is a clamping plate with two holes, one on each side. There are screws in both holes in the clamping plate, and the two screws each pass through one pair of holes in the positioning plate. The position of each pair of holes in the positioning plate is selected during manufacture with respect to the predetermined desired inclinations of the support profile (and hence of the solar panel) during the year. If the inclination of the solar panel is required, the screws are removed from a given pair of holes in the positioning plate and, after a change in inclination, the screws are installed in another pair of holes in the positioning plate. The more pairs of holes in the positioning plate, the more positions the support structure can be adjusted. This solution allows a simple and expedient change in inclination, and thanks to the predefined pairs of holes in the positioning plate, it is no longer necessary to measure the newly adjusted inclination, since the angles of possible inclination are already given by the individual pairs of holes in the positioning plate.

Similarly, the front leg is fixed to the remainder of the structure by means of a pivot pin and the rear leg is slidably mounted to the remainder of the structure by means of a screw clamp or by a positioning plate and a glider with a clamping plate.

3 Examples of the invention

Example 1

The supporting structure of photovoltaic systems according to the proposed technical solution is made of aluminum and is designed as positioning. It consists of a rear leg 5, a front leg 9, a rear strut 4, an inclined strut 6 and a support profile 1. In this case, the support profile 1 is made of a closed rectangular profile of 50 mm x 50 mm x 3000 mm. In the support profile 1 there are circular openings for accommodating clips 2 for fastening the longitudinal struts 7. The rear leg 5 is fixed to the rest of the structure by means of a pivot pin 10 whose axis of rotation is horizontal and perpendicular to the inclined strut 6. The inclined strut 6 is slidably mounted relative to the longitudinal axis of the inclined strut

6. The sliding fastening is provided by means of the positioning plate 14 and the glider 15 with the clamping plate. The positioning plate 14 is of rectangular shape and is wound to the inclined strut 6 from the underside, with its longer axis coinciding with the longitudinal axis of the inclined strut 6. Three positioning pairs are formed in the positioning plate 14, each pair to adjust the inclination of the support . The upper end of the front leg 9 is provided with a glider 15 which has a hemispherical shape when viewed from the side and a clamping plate. There are two holes in the clamping plate, one on each side. The actual connection of the front leg 9 to the positioning plate 14 is provided by two screws passing through both holes in the clamping plate and one pair of holes in the positioning plate 14.

The inner part of the tube forming the rear leg 5 and the front leg 9 has a larger diameter than the outer diameter of the upper part of the drilling bases 8 on which the entire support structure rests. Thus, the drill bases 8 are in this case located inside the front leg 9 and the rear leg 5, and are secured against displacement by a plurality of screws passing through the wall of the tube forming the rear leg 5 and the front leg 9. This solution allows the inclination of the support profile 1 (and thus solar panels) with respect to the horizontal.

A series of several load-bearing structures according to the proposed solution is placed side by side in a row, and the individual load-bearing structures are interconnected by several longitudinal struts 7. The solar panels are mounted on the longitudinal struts 7. At least two load-bearing structures in each of these series are tied to each other by a plurality of ropes 11 to increase the crosswind resistance of the entire series (so-called wind bracing).

The solution described is apparent from Figures 3,4,5 and 7.

Example 2

The supporting structure of photovoltaic systems according to the proposed technical solution is made of galvanized steel and it is designed as solid. It consists of a rear leg 5, a front leg 9, a rear strut 4, an inclined strut 6 and a support profile 1. In this case, the support profile 1 is designed as a U-profile with dimensions of 60 mm x 40 mm x 3000 mm. In the support profile 1 there are elongated holes (grooves) for the placement of clips 2 for fastening the longitudinal struts 7. The support profile 1 is supported at the point of contact with the inclined strut 6 and at the point of contact with the rear strut 4. The rear leg 5 and the front leg 9 are firmly attached to the rest of the structure. The whole structure then rests again on two drilling bases 8. Instead of the drilling bases 8, it is also possible to use a grip 12 or a connecting element 13 for fastening the supporting structure to a roof or other paved surface (for example an airfield). The brackets 12 are then attached to the front leg 9 and the rear leg 5 by means of a plurality of bolts, in the same way as the drill bases 8. The connection between the brackets 12 and the roof or other paved surface is generally provided by several bolts passing through through the holes in the lower plate of the fasteners 12. The multi-hole plate-like connector element 13 is fixedly secured to the front leg 9 and the rear leg 5 by means of a weld or other joint. The connection between the connecting element 13 and the roof or other reinforced surface is again provided by means of several screws passing through the holes in the connecting element 13.

A series of several load-bearing structures according to the proposed solution is placed in a row side by side, and the individual load-bearing structures are connected to each other by several longitudinal struts 7. The solar panels are mounted on the longitudinal struts 7. At least two load-bearing structures in each of these series are tied to each other by a plurality of ropes 11 to increase the crosswind resistance of the entire series (so-called wind bracing).

Claims (8)

Patent claims i. Fixed and positioning supporting structure of photovoltaic devices, preferably for anchoring to the drilling base (8) when installed on unpaved surfaces, or for installation on paved surfaces using a bracket (12), wherein the structure consists of a rear foot (5), front foot (9), rear struts (4), inclined struts (6) and support profile (1). characterized in that the internal angles in the triangle formed by the support profile (1), the inclined strut (6) and the rear strut (4) are 60 ° with a tolerance of ± 5 °, and a distance between the upper part of the rear strut (4) and the center the axis (O) is smaller than the distance between the lower part of the rear strut (4) and the center axis (O), and at the same time the inclined strut (6) is situated such that the connection of the front leg (9) with the inclined strut (6) is higher than the connection of the inclined strut (6) to the rear leg (5). Construction according to claim 1, characterized in that the connection of the rear leg (5) and / or the front leg (9) to the remaining part of the structure is displaceable by means of a positioning plate (14) which is fixedly attached to the inclined strut (6). and at its longer opposite sides provided with at least two pairs of apertures; furthermore, at the upper end of the front leg (9) and / or the upper end of the rear leg (5) is a convex-shaped glider (15) provided with a clamping plate with one pair of apertures; the leg (9) and / or the rear leg (5) is connected to the positioning plate (14) by two screws extending through both holes in the clamping plate and one pair of holes in the positioning plate (14). A structure according to claim 1, characterized in that the connection of the rear leg (5) and the front leg (9) to the remaining part of the structure is immovable. 4. Construction according to claims 1 to 3 _{characterized} wherein the support profile (1) is formed into Uprofílu and the point of contact with the rear strut (4) is a supporting beam (1) supported by a reinforcement (3) and also the supporting beam (1) supported by a reinforcement (3) at the point of contact with the inclined strut (6). Construction according to claims 1 to 4 _; characterized in that the inner diameter of the tube forming the rear leg (5) and the front leg (9) is larger than the outer diameter of the drilling base (8). Construction according to claims 1 to 4 _, characterized in that the inner diameter of the drilling base (8) is larger than the outer diameter of the tube forming the rear leg (5) and the front leg (9). Construction according to claims 1 to 6, characterized in that the connection of the rear leg (5) and / or the connection of the front leg (9) to the rest of the structure is formed by a pivot (10) with a horizontal axis of rotation perpendicular to the inclined strut (6). ). Construction according to claims 1 to 7, characterized in that in the version for mounting on roofs and other paved surfaces, the lower end of the front leg (9) and the rear leg (5) is provided with a connecting element (13). wherein between the front leg (9) and the connecting element (13) and further between the rear leg (5) and the connecting element (13) is a weld joint or other joint.