ES1311022U - STRUCTURE FOR LAND SETTLEMENTS (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Structure for ground settlements (1) comprising the following elements: - Ballast (2) which receives the weight of the structure and keeps it attached to the ground, replacing the usual foundation. - Post support (3) fixed on the ballasts and which perform the function of supporting the posts by adopting an appropriate working position in case the ballasts (2) move. - Extendable post (4) is the profile that transmits the load of the structure to the ballast. - Extendable strut (5) is the profile at mid-height between the front and rear posts and which allows the bracing between the front and rear post. - Lintel (6) is the profile that transmits the load of the structure to the posts. - Purlin (7) is the profile that supports the load of the solar panels and transmits it to the lintels. The structure (1) is characterized in that the posts and struts that compose it can be acted upon at any time by elongating and contracting them, thus, the structure (1) allows rotation and movement, being able to adapt to the changing orography of the terrain.

Description

DESCRIPTION

STRUCTURE FOR LAND SETTLEMENTS

TECHNICAL SECTOR

The present invention belongs to the field of mechanical engineering, and more specifically to the sector of the generation of electrical energy from renewable energies.

The object of the present invention is to adapt the structures for photovoltaic solar installations to land in which settlement cannot be achieved through traditional foundations, such as footings, piles, direct driving, etc. and which have low compaction characteristics, so that when subjected to external loads they could compact and sink, so that the structure supported on the ground would become misaligned, causing breakages or damage.

BACKGROUND OF THE INVENTION

Photovoltaic solar energy is a booming sector that currently requires continuous technological development to increasingly optimize the design of structures, making them more efficient from engineering to manufacturing and assembly.

Photovoltaic panels are responsible for transforming solar energy into electrical energy. Photovoltaic park installations require large areas of land due to the type of installation and the ever-increasing size of solar panels.

The modules must be installed on metal structures that are capable of supporting not only their weight, but also of withstanding external stresses such as environmental factors (wind, snow, earthquakes, etc.) or due to the geomorphological characteristics of the terrain (irregular orography, unfavourable geotechnical factors, etc.).

Currently, there are various types of structures designed to perform this function, but there is no structure on the market that can adapt to the terrain's topography and also allow the level of the structure to be corrected during its useful life.

Photovoltaic solar structures are usually composed mainly of metal profiles. The dimensions and composition of these profiles are studied in the engineering and design phase and are determined by mechanical calculations based on applicable regulations according to the final location of the structures. These studies lead to the implementation of structures with fixed dimensions or that allow for very tight variations in them, that is, they are structures that once installed do not allow for adjustment in the event that the ground on which they are installed gives way or changes in its composition or structure.

The construction of a photovoltaic park involves the preparation of numerous reports on the location in which the composition of the land, its topography, its load-bearing capacity, the climate, etc. are studied.

The geotechnical study is very important, since it contains information about the bearing capacity, compaction and fundamental values based on which the foundation depth and the type of foundation will be determined. The corrosiveness of the soil will also be known. This is important because it also indicates the type of foundation that should be chosen to avoid premature deterioration of the materials used.

There are cases where the ground has a very weak and heterogeneous compactness, giving rise to differential settlements, that is, non-homogeneous ground movements on the support surface of the structure, which leads to the support points of the structure being at different heights. This results in the generation of structural overstresses that can affect the stability and operation of the structure, as well as the photovoltaic panels, which can be damaged due to poor settlement, even leading to their breakage.

For those areas where foundations are not necessary, ballasted structures are installed. The ballasts are made of a material that is strong and heavy enough to support the loads of the structures and to prevent them from moving unintentionally. These ballasts are placed directly on the ground. In locations where the ground is sufficiently compact or has a high hardness, the weight of the ballasts and the structures do not cause the ground to collapse. However, in areas with low cohesion, ground movements can occur under the ballasts. This causes premature breakage or deterioration of the structures and photovoltaic panels, since new stresses are generated in the materials that cannot be taken into account in the calculations.

EXPLANATION OF THE INVENTION

The inventor of the present application has designed a structure that is capable of absorbing the irregularities of the terrain both during its construction phase and during its useful life, without losing the stability and robustness necessary for its correct operation.

This invention makes it possible to ensure proper installation on uneven terrain that is difficult to identify during the pre-installation analysis phase. This process involves carrying out detailed studies of the terrain's irregularities, which require a considerable number of hours of dedication and result in a significant cost. In addition, the costly earthworks required to level the terrain are avoided.

A great advantage of this structure is the possibility of correcting its position in case the ground beneath it gives way. On many occasions, projects for photovoltaic installations are rejected because the ground does not have the appropriate geotechnical characteristics. This invention solves this problem. Through the intervention of suitable tools, the position of the profiles can be adjusted, allowing the release of tensions that have occurred on the structure due to their deformation. This occurs when the ground changes its topography due to the weight of the structure itself, due to rain or simply due to movements of the ground itself in its compaction or sliding due to internal or external factors. By varying the support points, these variations in the ground must be overcome. To do this, the structure has extensible profiles that provide it with flexibility and give the opportunity to correct its position without the need to make new foundations, but simply by adjusting the position of the structure's profiles thanks to support tools and fixing means that allow movement between profiles.

A very important aspect of this structural functionality is that the photovoltaic modules remain intact. When the ground settles, the structure acquires tensions and stresses in all directions, whether they are shear stresses, axial torsion, etc. These stresses are transferred to all the profiles of the structure and, therefore, to the photovoltaic modules. These photovoltaic modules break when these structural deformations appear, since they are not prepared to withstand these extra stresses. This invention solves this problem, since, if the photovoltaic panels break, the photovoltaic plant would stop generating energy, with the consequent economic loss that this entails.

The fixing means that the structure has are a very important part of the present invention, since they are what provide the basis for the utility and advantages acquired by it.

For a better understanding of the invention, the composition of a particular example of the structure will be described in general terms below.

Starting from the lowest part of the structure, we have the ballasts, which are the elements that replace the usual foundation. They receive all the weight of the structure and are responsible for keeping it attached to the ground, so they must be fixed to it, forming part of it. The ballasts are supported on the ground, transmitting the loads to it. If the ground gives way, they are the elements that transmit the movement to the rest of the structure, since they will be in continuous contact with the ground.

Post supports are fixed to the ballasts, which serve as support for the posts. These supports are characterised by having a fixing means that allows the readjustment of the position of the posts in the event that the ballasts settle on any of their axes due to differential settlements.

The ballasts are followed by the posts. They have front and rear posts, both with the same construction but of different lengths, although with the same capacity for elongation or contraction. The posts have a fixing means that allows their length to be adjusted at any time, from their assembly to the end of their useful life. Thanks to this functionality, the structure can maintain the optimal inclination of the solar panels constant, regardless of the topography of the terrain and the settlements of the ground. This leads to significant economic savings in terms of corrective actions, in addition to maintaining a constant capacity for generating electricity by reducing system losses due to inclinations that reduce the efficiency of the photovoltaic modules due to possible settlements of the ground.

At mid-height of the posts, we find extendable struts, capable of absorbing irregularities and changes in the configuration of the structure, since the fixing means they have allows their position to be adjusted at any time. These struts provide structural security thanks to the bracing between the rear and front struts.

The next profile we find after the posts is the lintel. This is what provides the inclination to the photovoltaic modules, since these are installed coplanar to the upper face of the lintels. They also have a means of fixing capable of absorbing ground movements, since, if the elongation of the posts varies, the lintels must be able to return to the required inclination, so they must allow the intended movement at the support points on the posts.

Next, we find the purlins. These profiles are the highest in the structure as a whole. They are responsible for fixing the solar panels to the lintels. These also have fixing means capable of adapting to changes in the structure's geometry during use.

As you can see, all the profiles as a whole have the ability to adjust to each other, so that the geometry of the structure varies in order to keep the inclination of the photovoltaic panels constant, without losing robustness at any time and ensuring the integrity of the photovoltaic modules. In addition, installation is very easy due to the assembly system and fixing means available.

The fundamental elements of this invention are the fixing means between the different profiles, which are designed and calculated in such a way that they allow movement between profiles in any direction and at all times. Without these fixing means between the different structural profiles, the invention lacks functionality, since it improves existing structures in terms of flexibility in their assembly and operation throughout their useful life.

Each connection point between profiles has a particular fixing means that allows the structure to be adjusted in any of its axes of rotation, since differential settlements are practically unpredictable. This is why this invention provides a solution to the problems presented by soils with weak and heterogeneous compactness, and it is common to discard a photovoltaic project due to problems of structural instability or because it is economically unviable.

BRIEF DESCRIPTION OF THE DRAWINGS

To complement the description being made and in order to assist in a better understanding of the characteristics of the invention, a set of drawings is included as an integral part of said description, in which, for illustrative and non-limiting purposes, the following has been represented:

Figure 1.- Shows a perspective view of the structure for ground settlements.

Figure 2.- Shows a profile view of the structure for ground settlements.

Figure 3.- Shows a front elevation view of the structure for ground settlements.

Figure 4.- Shows a perspective view of the structure for ground settlements with uneven ballasts.

Figure 5.- Shows a profile view of the structure for ground settlements with uneven ballasts.

Figure 6.- Shows a front elevation view of the structure for ground settlements with uneven ballasts.

Figure 7.- Shows a rear elevation view of the structure for ground settlements with the ballasts uneven.

Figure 8.- Shows a top view of the structure for ground settlements with uneven ballasts.

Below is a list of the various elements represented in the figures to facilitate understanding of the invention. It is again specified that these elements are representative and not limiting.

1. Structure for ground settlements

2. Ballast

3. Post support

4. Extendable pole

5. Extendable strut

6. Lintel

7. Strap

PREFERRED EMBODIMENT OF THE INVENTION

A particular example of a structure for ground settlements (1) is described below, in accordance with the present invention, making reference to the attached figures.

Figure 1 shows a perspective view of the structure for ground settlements, showing its complete assembly and the elements it is composed of. Figure 1 represents an example of a structure (1) on level ground. Figure 2 shows the structure (1) in a profile view, where it is more clearly seen that the ballasts of the structure are at the same level, as in Figure 3, which shows a front elevation view of the structure (1).

Following a logical assembly order, the ballasts (2) would be placed on the ground. The ballasts (2) replace the usual foundation for this type of structure, providing the same level of security and structural stability, with the advantage of adapting to the movements or settlements of the ground.

The post supports (3) are then fixed to the ballasts (2). These supports (3) are provided with a fixing means that allows the posts (4) to adopt a suitable working position in the event that the ballasts (2) move.

The next step is to fix the posts (4) to the post supports (3). The posts (4) can be elongated or contracted as needed during their lifespan. For example, if a ballast sinks from the front and rises from the rear, the front post can be elongated and the rear post can be contracted, in order to maintain a constant inclination or “tilt” of the photovoltaic energy conversion surface, as well as to control the structural overstresses that would occur due to misalignment due to poor support of the ballasts (2).

Next, the extendable struts (5) will be fixed between the front and rear posts (4). These are intended to brace the posts (4) and provide overall stability to the structure (1). The struts (5) also have flexible fixing to absorb movements of the structure (1).

At this point the lintels (6) can be assembled to the posts (4). The lintels (6) will adopt the optimal inclination over the horizontal for the generation of photovoltaic solar energy, since the straps (7) will be fixed to the lintels (6) to which, in turn, the photovoltaic modules will be fixed. Both the lintels (6) and the straps (7) will have fixing means that allow them to assume configuration changes in the structure (1) and that the technical characteristics do not vary at any time.

To move the profiles of the structure (1) once installed, tools and fixtures capable of exerting sufficient force to move the total weight of the structure (1) may be used.

Claims (1)

1. Structure for ground settlements (1) comprising the following elements: • Ballast (2) that receives the weight of the structure and keeps it attached to the ground, replacing the usual foundation. • Post support (3) fixed on the ballasts and which act as support for the posts, adopting an appropriate working position in case the ballasts (2) move. • Extendable post (4) is the profile that transmits the load from the structure to the ballast. • Extendable strut (5) is the profile at mid-height between the front and rear posts and allows bracing between the front and rear posts. • Lintel (6) is the profile that transmits the load of the structure to the posts. • Strap (7) is the profile that supports the load of the solar panels and transmits it to the lintels. The structure (1) is characterized in that the posts and struts that compose it can be acted upon at any time by elongating and contracting them, thus, the structure (1) allows rotation and movement, being able to adapt to the changing orography of the terrain.