CZ23364U1 - Foldable load-supporting structure of solar system - Google Patents

Description

(54) Utility model name:

Composite supporting structure of the solar system

The Industrial Property Office does not ascertain in the registration procedure whether the subject of the utility model meets the conditions of eligibility for protection pursuant to Section 1 of Act no. No. 478/1992 Coll.

Composite supporting structure of the solar system

Technical field

The technical solution relates to a structural supporting structure of a solar system, which together with fixation elements to which it is detachably attached, forms the supporting part of solar panel systems of solar power plants, etc.

BACKGROUND OF THE INVENTION

A number of solutions for load-bearing structures for solar panels are currently known. E.g. the rigid load-bearing structure according to the German utility model DE 20311967 consists of basic trapezoidal structural elements. The solar panels are fastened by screws to the upper inclined arms of these trapezoidal elements mounted on the spacer elements. Under the spacers there is a plastic base plate which is shaped to have flat areas separated by protruding semicircular portions. The spacers are then mounted on these protruding semicircular elements. 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 support structure itself, which requires relatively robust sub-components, and secondly, the use of plastic base plates, for which relatively extensive earthworks are required for installation.

The positioning supporting structure, which allows the different inclination of the solar panels to be adjusted in the summer and winter months, is the subject of another German utility model DE 20319065. The construction shown here is a separate foot for each solar panel. The individual legs are connected by a horizontally oriented rotary axis, extending below the solar panels approximately half their length. The disadvantage of this solution is the necessity of a large number of feet embedded in the ground given by the aforementioned design principle, with one foot embedded in the ground per panel.

In the context of the two solutions described above, a lightweight support structure according to utility model CZ 19145 appears to be advantageous. This structure consists of a rear leg, a front leg, a rear strut, an inclined strut and a support profile. The internal angles in the triangle formed by the support profile, the inclined strut and the rear strut are 60 ° with a tolerance of ± 5 °, the distance between the upper part of the rear strut and the center axis is less than the distance such that the connection of the front leg with the inclined strut is higher than the connection of the inclined strut with the rear leg. The benefit of this construction is the effort to achieve stiffness by optimum shape solution and not by robustness of individual parts of the structure. However, this effort negatively translates into minimal variability of the structure. E.g. attaching the front leg directly in place by connecting the support profile with the inclined strut complicates very much and in practice almost eliminates the possibility of changing the alignment of the structure depending on uneven terrain.

From the point of view of solving the aforementioned drawbacks of the known constructions, the supporting structure of the solar system according to the utility model CZ 19791 is currently the most perfect. This construction is like a series of previously known supporting constructions formed by an inclined beam which is connected to the front leg. at the same time with the rear leg and which carries the fixation elements of the longitudinal beams of the solar panels. A new element of the solution, however, is that the inclined beam is directly detachably connected to the front leg body in its lower part, while its upper part is detachably connected to the hollow rear leg body by means of a vertical strut. The region of this joint is then further connected by means of an inclined strut to the inclined beam at a point located above the region of the inclined beam to the front leg. The inclined beam can be further fixed by coupling to the inclined strut by means of a central strut. In addition, the inclined beam is made of an open C profile, the front leg and the rear leg being hollow bodies, in particular a tube shape. The inclined strut and the vertical strut and possibly also the central strut are preferably made of hollow profiles. The releasable connection of the inclined beam to the front leg can then advantageously be realized by a support body of an open C profile, in the slot of which an adjustable screw is displaceably displaceable in the direction of the inclined beam orientation. The design according to utility model CZ 19791 states that thanks to the unique connection of the inclined beam directly with

The front foot (except for any reinforcement strut) allows the entire structure to be variably adjusted to eliminate the effects of terrain unevenness. In practice, however, it turns out that even this declared variability may not always be sufficient and even in this construction can be due to uneven terrain difficulties. This is due to the fact that in addition to the dismountable joints of some components of the structure, fixed joints are also used for other components. Another disadvantage of this solution is the fact that the fixed (permanently attached) construction elements must be delivered and transported already in the folded state, which places higher demands on the transport space.

The essence of the technical solution

The structural support structure of the solar system according to the present invention contributes to the elimination of the above-mentioned drawbacks. The construction consists of an inclined beam, which is detachably connected by a rear articulated joint with a rear foot attached to the rear stud and a front articulated joint detachably attached to a front foot attached to the front stud. At the same time, the front articulated joint is detachably connected to the rear stud by means of a length adjustable strut.

The connection of the strut to the rear stud is preferably realized by a removable sleeve.

The inclined beam, the rear leg and the front leg of the composite support structure are preferably formed by hollow sections, the length adjustable strut then by a pair of inserted and length fixable hollow sections.

The upper sections of the inclined beam are then fitted with supporting profiles, preferably with an open C-shaped cross-section.

The hinged joints may advantageously consist of flat openings provided with clips fixed to the lower part of the inclined beam, which are detachably connected to the openings provided with the ends of the front leg and the bolts respectively. hind legs.

The mounting of the rear leg to the rear stud and / or the attachment of the front leg to the front stud is preferably height adjustable.

The main benefit of the supporting structure of the solar system according to the present technical solution is that it is completely designed as a structural structure with the connection of structural elements realized by detachable articulated joints. This enables both maximum variability of the construction setting with the possibility of adaptation to the most demanding terrains and easy and space-saving transport of the structure in a completely unfolded shape with assembly only at the place of installation.

Clarification of drawings

In order to clarify the essence of the technical solution is attached attached drawing, which represents:

Fig. 1 - overall scheme of the structural supporting structure of a solar system according to the technical solution; Fig. 2 - detail of a detachable articulated joint.

Exemplary embodiment

The structural support structure of the solar system in the exemplary embodiment (see Fig. 1) consists of an inclined beam 1, which is detachably connected by a rear hinge 9 to the rear foot 3 attached to the rear stud 6 and to the front hinge 8 detachably connected to the front foot 4 At the same time, the front articulated joint 8 is detachably connected to the rear stud 6 by means of a length adjustable strut 5.

The connection of the strut 5 to the rear stud 6 is realized by a removable sleeve 10.

-2 CZ 23364 Ul

The inclined beam 1, the rear leg 3 and the front leg 4 are formed by hollow profits, the length adjustable strut 5 is then formed by a pair of inserted and lengthwise fixed hollow profiles.

On the upper part of the inclined beam 1, the supporting profiles 2 with an open C-shaped cross-section are fixed.

The articulated joints - the front articulated joint 8 (see detail in Fig. 2) and the back articulated joint 9 are both flat holes provided with clips fixed to the lower part of the inclined beam 1, which are bolted releasably to the holes provided with the ends of the front leg 3 and respectively. hind legs 4.

The attachment of the rear foot 3 to the rear stud 6 and the attachment of the front foot 4 to the front stud are height adjustable.

PROTECTION REQUIREMENTS

Claims (7)

Composite support structure for a solar system, characterized in that it consists of an inclined beam (1) which is detachably connected by a rear articulated joint (9) to a rear foot (3) attached to a rear stud (6) and a front articulated joint (9). 8) detachably connected to the front foot (4) attached to the front stud (7), wherein the front articulated joint (8) is simultaneously detachably connected to the rear stud (6) by means of a length adjustable strut (5). Composite load-bearing structure according to claim 1, characterized in that the connection of the strut (5) to the rear stud (6) is realized by a removable sleeve (10). Composite bearing structure according to claim 1, characterized in that the inclined beam (1), the rear leg (3) and the front leg (4) are formed by hollow profiles. Composite load-bearing structure according to claim 1, characterized in that the length-adjustable strut (5) is formed by a pair of inserted and length-adjustable hollow profiles. Composite support structure according to claim 1, characterized in that support profiles (2) with an open C-shaped cross-section are attached to the upper part of the inclined beam (1). Composite load-bearing structure according to claim 1, characterized in that the hinged joints (8, 9) are formed by flat holes provided with grips fixed to the bottom of the inclined beam (1), which are detachably connected with holes provided with the ends of the front leg (3). ), respectively. hind legs (4). Composite support structure according to claim 1, characterized in that the mounting of the rear leg (3) to the rear stud (6) and / or the attachment of the front leg (4) to the front stud (7) is height adjustable.