BG1820U1 - Prefabricated construction for solar system - Google Patents

Abstract

The prefabricated support structure for a solar system, together with fastening elements by which it is detachably connected, is a part of the supporting systems of solar power plants and the like. The present structure consists of an inclined supporting beam (1), which with a rear hinge (9) is detachably connected with the rear leg (3), attached to the rear threaded rod (6) and a front hinge (8) is detachably connected with the front leg (4), attached to a front threaded rod (7). The front hinge (8) simultaneously through an adjustable length support (5) is detachably connected to the rear threaded rod (6).

Description

Field of technique

The utility model relates to a prefabricated support structure for a solar system which, together with the fastening elements to which it is releasably connected, constitutes a supporting part of solar power plant systems and the like.

Prior art

A number of solutions for supporting structures for solar panels are currently known. For example, the fixed support structure according to German utility model No. 20311967 consists of basic detachable parts with a trapezoidal shape. The solar panels are bolted to the upper oblique arms of these trapezoidal elements located on the spacers. Underneath the dividers is a plastic platform serving as a base, which is shaped so that its flat areas are separated by convex semi-circular parts. Separators are then attached to these protrusions. The plastic platforms serving as foundations may optionally be located below the surface of the ground and their ends may overlap each other. A disadvantage of this solution is, firstly, the shape of the metal supporting structure itself, requiring quite stable separate parts, and secondly, the use of plastic platforms, which require significant excavation for their placement.

An adjustable support structure enabling the solar panels to be placed at different angles during the summer and winter months is the subject of another German utility model No. 20319065. The structure disclosed here consists of an independent leg for each solar panel. The individual legs are connected by a horizontally oriented rotating axis that passes under the solar panels approximately midway along their length. A disadvantage of this solution is that the construction principle requires a large amount of feet dug into the ground, since one foot dug into the ground falls on each individual panel.

In the context of the two above-mentioned solutions, the lightweight support structure according to Czech utility model No. 19145 shows advantages. This structure consists of a rear leg, a front leg, rear struts, inclined struts and a support profile. The internal angles in the triangle created by the bearing profile, the inclined strut and the rear strut are 60° with a deviation of ± 5°, the distance between the top of the rear strut and the center axle is less than the distance between the bottom of the rear strut and the center axle, and at the same time, the inclined strut is located so that the connection of the front leg to the inclined strut is higher than the connection of the inclined strut to the rear leg. The advantage of this construction is the effort to achieve strength through an optimal solution of the form, and not through the strength of individual parts of the structure. However, this solution comes at the expense of the minimal possibility of changing the structure. For example, the connection of the front leg directly at the place of connection of the supporting profile with the inclined strut greatly complicates and in practice almost excludes the possibility of changing the settings of the structure depending on the unevenness of the terrain.

From the point of view of solving the above-mentioned shortcomings of the known structures, at present the best is the support structure for a solar system according to the Czech utility model No. 19791. This structure, as well as a number of other known support structures, consists of an inclined support beam, which is connected to the front leg and by means of a vertical support and an inclined support is simultaneously connected to the rear leg and carries the elements for fixing the longitudinal support beams of the solar panels. The new element in the solution is that the inclined support beam in its lower part is releasably connected to the body of the front leg, while its upper part, by means of the vertical support, is releasably connected to the hollow body of the rear leg. The region of this connection, by means of the inclined strut, is additionally connected to the inclined support beam at the location which is located above the area of connection of the inclined support beam to the front leg. The inclined support beam can also be additionally fixed by connecting

1820 UI her net to the inclined prop through the middle prop. This inclined support beam is made from an open C profile, the front leg and rear leg are made of hollow, mostly tubular, bodies. The inclined support, the vertical support, possibly the middle support are made of hollow sections. The detachable connection of the inclined support beam to the front leg can be well realized by an open C-profile, in the slot of which an adjustable screw is placed, which is moved in the direction of the orientation of the inclined support beam. The design, according to Czech utility model No. 19791, states that the unique connection of the inclined support beam directly to the front leg (without any reinforcing strut) allows the entire structure to be modified to completely eliminate the influence of terrain irregularities. However, experience shows that even this declared variability is not always enough and that this construction can also have problems as a result of uneven terrain. The reason for this is that, along with detachable parts, there are also some parts of the structure that have fixed connections. Another disadvantage of this solution is the fact that the fixed (non-detachable) connecting elements of the structure must be delivered and transported already in assembled form, which means more complicated requirements in terms of transport space.

Technical nature of the utility model

The prefabricated support structure for a solar system according to the present utility model contributes to the elimination of the above-mentioned disadvantages. The essence of the solution is that the structure consists of an inclined supporting beam, which is releasably connected by a rear hinge to the rear leg attached to the rear stud and is also releasably connected by a front hinge to the front leg attached to the front stud . At the same time, the front joint is releasably connected to the rear stud by means of a strut of adjustable length.

The connection of the strut to the rear stud has the advantage of being accomplished by means of a removable sleeve.

The inclined support beam, the rear leg and the front leg of the prefabricated support structure have the advantage of being made of hollow sections, while the adjustable-length strut consists of two hollow sections fitted telescopically into each other.

On the upper part of the inclined support beam, the support profiles with a cut in the shape of the letter C are fixed.

The hinged connections may consist of plates with holes attached to the lower part of the inclined support beam, which plates are releasably connected by screws with holes in one of the ends of the front leg and the rear leg, respectively.

The attachment of the rear leg to the rear stud and/or the attachment of the front leg to the front stud can be of variable height, which is an advantage.

The main contribution of the supporting structure for a solar system according to the proposed technical solution is that it is complexly designed as a prefabricated structure with structural elements that are connected by detachable hinge connections. Firstly, this allows for maximum variability of the structure setting with the ability to adapt to even the most complex terrains, and secondly, easy and undemanding, in terms of space, to transport the structure in a completely disassembled state all the way to the place of installation, where it is assembled.

Brief description of the figures

The attached drawings serve to explain the utility model in more detail, where:

Figure 1 is a general diagram of the prefabricated support structure for a solar system according to the utility model;

Figure 2 is a detail of the detachable hinge.

An exemplary version of implementation

The prefabricated support structure for a solar system in the exemplary embodiment (see Fig. 1) consists of an inclined support beam 1, which is releasably connected with a rear hinge 9 to a rear leg 3 connected to a rear stud 6. In addition, the support beam

1820 UI yes 1 c front joint 8 is releasably connected to the front leg 4 connected to the front stud 7. The front joint 8 is simultaneously, by means of a length-adjustable support 5, releasably connected to the rear stud 6.

The connection of the length-adjustable support 5 with the rear stud 6 is realized by means of a detachable sleeve 10.

The inclined support beam 1, the rear leg 3 and the front leg 4 are made of hollow profiles, while the adjustable length support 5 consists of two telescopically mounted hollow profiles, with the possibility of changing the length.

On the upper part of the inclined bearing beam I, the bearing profiles 2 with a cut in the shape of the letter C are fixed.

Hinged joints - the front hinged joint 8 (see details in Fig. 2) and the rear hinged joint 9 consist of plates with holes attached to the lower part of the inclined support beam 1, which are releasably connected with screws to the holes in one of the ends of the front leg 3 and the rear leg 4 respectively.

The attachment of the rear leg 3 to the rear stud 6 and the attachment of the front leg 4 to the front stud 7 is adjustable in height.

Claims (7)

1. A prefabricated support structure for a solar system, consisting of an inclined support beam (1) which is releasably connected by a rear hinge (9) to a rear leg (3) attached to a rear stud (6) and by a front hinge (8) is releasably connected is a front leg (4) attached to a front stud (7), characterized in that the front hinge of the connection (8) by means of a length-adjustable support (5) is also releasably connected to the rear stud ( 6). 2. Prefab support structure according to claim 1, characterized in that the connection of the length-adjustable support (5) with the rear stud (6) is realized by a detachable sleeve (10). 3. A prefabricated support structure according to claim 1, characterized in that the inclined support beam (1), the rear leg (3) and the front leg (4) are made of hollow profiles. 4. Prefab supporting structure according to claim 1, characterized in that the length-adjustable support (5) consists of two hollow profiles mounted telescopically into each other. 5. Prefab support structure according to claim 1, characterized in that on the upper part of the inclined support beam (1) are fixed support profiles (2) with a section in the shape of the letter C. 6. A prefabricated supporting structure according to claim 1, characterized in that the hinged connections (8, 9) consist of plates provided with holes, the plates being attached to the lower part of the inclined supporting beam (1) and releasably connected by screws to holes in one of the ends of the front leg (3) and the rear leg (4) respectively. 7. A prefabricated support structure according to claim 1, characterized in that the attachment of the rear leg (3) to the rear stud (6) and the attachment of the front leg (4) to the front stud (7) are adjustable in height.