SI24186A - Modular load-bearing structure of the solar system - Google Patents

Abstract

The composite supporting structure of the solar system, which, together with the fixing elements to which it is detachably attached, forms the carrier part of the solar cell solar system, and the like. This construction (see Figure 1) consists of an oblique support (1) which is disassembled via the rear rotary joint (9) with the rear leg (3), which is implanted in the last leg with the screw (6), and through the front rotary joint 8) is disjointly connected to the front leg (4) which is implanted in the front foot end with a screw (7). The front rotation joint (8) is also dismountably connected to the last leg with the screw (6) via the adjustable length (5).

Description

The subject of the invention is a composite load-bearing structure of the solar system, which together with the fasteners to which it is individually attached, forms the load-bearing part of the solar cell solar system, and the like.

The state of the art

Today, a variety of solutions for load-bearing solar cell structures are known. E.g. solid supporting structure registered according to German utility model no. 20311967 consists of basic trapezoidal components. Solar cells are secured by screws to the upper sloping supports of these trapezoidal elements, which are mounted on spacers. Below the spacers is a plastic washer that is designed to have flat surfaces divided by prominent semicircular elements. Spacers are attached to these prominent semicircular elements. Plastic washers may exceptionally be positioned below the earth's surface and their edges may overlap. The disadvantage of this solution is, on the one hand, the form of the metal support structure itself, which requires rather robust components, and, on the other hand, the use of washer plastic plates, which require quite extensive excavations to be assembled.

Following the example of German example no. 20319065 is a registered flexible supporting structure that allows you to adjust the different inclination of solar cells in the summer and winter months. This construction has a stand-alone foot for each solar cell. The individual legs are connected by a transverse axis of rotation that extends below the solar cells about half their length. The disadvantage of this solution is that a large number of legs need to be entrapped in the soil, which is a consequence of the construction principle already mentioned, which makes it possible for each mounted cell to have one foot in the ground.

In the context of the two solutions described above, a lightweight load-bearing structure registered in the Czech Republic according to utility model no. 19145. This construction consists of a rear foot, a front foot, a rear strut, an oblique strut, and a supporting profile. The inner angles in the triangle formed by the supporting profile, the oblique strut and the rear strut, measure 60 ° with a ± 5 ° deviation, the distance between the upper part of the rear strut and the center axis is less than the distance between the lower part of the rear strut and the center axis and is the sloping strut positioned so that the joint of the front foot with the sloping strut is positioned higher than the joint of the sloping strut with the rear foot. The advantage of this construction is that it tries to achieve greater strength with an optimum design solution rather than the robustness of individual parts. The downside of this approach, however, is the minimal variability of the whole structure. E.g. the joint of the front foot directly into the joint of the supporting profile with the oblique strut makes it very difficult and in practice almost eliminates the possibility of adjusting the layout of the structure according to the uneven terrain.

In view of the above disadvantages of known structures, by today's standards the most sophisticated load-bearing structure of the solar system is registered in the Czech Republic according to utility model no. 19791. Like many known load-bearing structures, this structure consists of an oblique bracket that is connected to the front foot and, with the help of a vertical and oblique strut, simultaneously with the rear foot, and carries the mounting elements of the longitudinal solar cell mounts. A new element introduced by the solution is that the oblique bracket in its lower part is directly individually connected to the body of the front foot, while its upper part is individually connected to the hollow body of the hind leg via a vertical support. The area of this joint is then further connected via an oblique support to an oblique bracket in a position which lies above the area of the joint of the oblique bracket with the front foot. The sloping bracket can further be fixed by joining it to the sloping strut by means of a center strut. In addition, this oblique bracket consists of an open C-shaped profile, the front leg and hind leg having hollow profiles, most often tube-shaped. Oblique struts and vertical struts, and possibly the center struts, have the advantage of being hollow profiles. The breakable joint of the sloping support with the front foot is ideally realized by an open element with a profile in the shape of an open letter C, in which the groove is flexibly inserted a movable screw that allows movement back and forth in parallel with the sloping carrier. When describing the construction according to utility model no. 19791 it is introduced that the unique direct connection of an oblique support with the front foot (without any strut that would make the structure less flexible) allows variable layout of the entire structure so as to completely eliminate the effects of uneven terrain. In practice, however, it is shown that even this variability is not necessarily sufficient and that even with such a design, there may be difficulties in encountering rough terrain. This is due to the fact that, in addition to the breakable joints of some parts of the structure, other joints still use fixed joints. Another disadvantage of this solution is the fact that the fixed-jointed (indivisible) parts must be attached and transported in an already assembled form, which implies greater requirements regarding the transport space.

Description of the new solution

The remedial load-bearing structure of the solar system which is the subject of the invention contributes to the elimination of the above disadvantages. The essence of the invention relates to the fact that this construction consists of an oblique bracket, which is individually coupled to the rear leg joint inserted into the rear foot end with a screw, and jointly connected to the front leg which is implanted through the front rotary joint. into the front knife end with a screw. At the same time, the front rotary joint is individually connected via the strut of adjustable length to the rear foot end with a screw.

The advantage is that the strut and the rear foot bolt are connected via a detachable clamp.

It is also advantageous that the oblique bracket, the back and front legs of the load-bearing structure have hollow profiles, as well as the hollow profiles having two parts inserted into each other that form a support of adjustable length.

A further advantage is that carrier profiles having an open C-shaped cross section are implanted on the upper part of the oblique carrier.

Rotary joints may have the advantage that they are formed by flat openings with pins attached to the lower part of the oblique bracket, which are detachably connected by screws to the opening at the end of the front or. hind legs.

It is also advantageous that the rear foot joint with the rear foot end is screwed in and / or the front foot joint is with the front foot end with the adjustable height screw.

The main advantage of the supporting structure of the solar system which is the subject of the invention is that it is fully formed as a composite structure whereby the components are joined via split rotary joints. This allows for the greatest possible variability of the structure adjustment, and thus the adaptation to the most demanding terrains, and on the other hand the simple and spatially demanding transportation of the structure in a fully disassembled form with on-site installation.

Sketch description

A more detailed explanation of the essence of the invention is provided by the accompanying drawings, in which: FIG. 1 is a complete schematic diagram of a composite supporting structure of a solar system, the subject of the invention FIG. 2 - Detail of the detachable rotary joint.

An example implementation

The integral supporting structure of the solar system in the exemplary embodiment (see Fig. 1) consists of an oblique bracket 1 which is individually connected via the rear rotary joint 9 to the hind leg 3, which is inserted into the rear foot end by a screw 6, and via the front rotary joint 8 is jointly coupled to the front foot 4, which is inserted into the front foot end with a screw 7. The front rotary joint 8 is simultaneously individually connected via a support of adjustable length 5 to the rear foot end with a screw 6.

The abutment 5 and the rear foot end with the screw 6 are connected to the detachable clamp 10.

The oblique bracket 1, the hind leg 3 and the front leg 4 have hollow profiles, and the hollow profiles have two parts inserted into each other, which form a support of adjustable length 5.

The upper part of the bevel bracket 1 is implanted with bracket profiles 2 which have open sections in the form of an open letter C.

Rotary joints - the front rotary joint 8 (see detail in Fig. 2) and the rear rotary joint 9 are formed by flat openings with pins attached to the lower part of the transverse bracket 1, which are detachably connected by screws to the opening at the end of the front foot 3 or . hind legs 4.

The rear leg joint 3 with the rear foot end with a screw 6 and / or the front foot joint 4 with the front foot end with a screw is of adjustable height.

Claims (7)

PATENT APPLICATIONS Composite supporting structure of the solar system, characterized in that it consists of an oblique support (1), which, through the rear rotary joint (9), is detachably connected to the hind leg (3), which is inserted into the rear foot end by a screw (1). 6), and through the front rotary joint (8) it is detachably connected to the front leg (4), which is inserted into the front foot end with a screw (7), the front rotary joint (8) being simultaneously through the adjustable length support (5). individually connected to the posterior foot end by a screw (6). Assembly assembly according to claim 1, characterized in that the support (5) and the rear foot end are connected with a detachable clamp (10) by a screw (6). Assembly assembly according to claim 1, characterized in that the oblique support (1), the rear foot (3) and the front foot (4) have hollow profiles. Assembly assembly according to claim 1, characterized in that the adjustable length support (5) consists of two parts with hollow profiles, which are inserted into each other and allow the length of the support to be fixed. Assembly component according to claim 1, characterized in that in the upper part of the oblique bracket (1) there are implanted supporting profiles (2) having cross sections in the form of an open letter C. Assembly assembly according to claim 1, characterized in that the rotary joints (8, 9) are formed by flat openings with pins fixed to the lower part of the transverse support (1), which are detachably connected by screws to the opening at the end of the front legs (3) or. hind legs (4). Assembly structure according to claim 1, characterized in that the hind leg joint (3) with the rear foot end with a screw (6) and / or the front foot joint (4) with the front foot end with the screw (7) is of adjustable height .