ES2736015B2 - SYSTEM FOR THE CONTAINMENT OF EROSION IN SLOPES - Google Patents

Description

DESCRIPTION

SYSTEM FOR THE CONTAINMENT OF EROSION IN SLOPES

TECHNICAL FIELD OF THE INVENTION

The present invention is related to elements, devices or protection, coating or consolidation systems for geotechnical applications configured to avoid or minimize the effects of erosion on sloping terrain such as a slope, which are generated by chemical alteration, rain and the wind, among others, that cause the alteration and transport of the material that originally formed the slope.

STATE OF THE ART

Erosion control aims to avoid or minimize the degradation of substrate materials (mostly soils) in order not to lose the conditions for the development of vegetation, the appearance of gullies, gullies and differential erosions that can generate structural instability on a slope, whether on a slope, an embankment or in the clearing of a terrain. This degradation of the material can affect the normal use of the infrastructures, being a cause of risk for the users and the infrastructures themselves, which ultimately incurs high economic and human costs that are difficult to quantify.

A multitude of bioclimatic conditions influence the erosion of substrates, therefore its control is highly influenced by these conditions as well as by the characteristics of the slope, such as the slope, length, location, among others.

Some of the most common construction solutions to control erosion have been attached walls, cladding, coatings and finishes on the surface of the slope. Despite the fact that these solutions have been widely implemented, they have a high relative cost and are increasingly less accepted from an environmental point of view due to the significant impact they cause.

Another type of solutions are those called environmentally integrated, which consist of the contribution to the slope of elements of natural origin that help the development of vegetation to provide its intrinsic benefits against erosion, either by providing seeds, germinated plants, cuttings , a suitable soil, fertilizers or organic amendments, or simply cover the slope with elements such as plant debris or gravel.

These solutions are usually accepted in a good way thanks to the positive environmental impact they have and their low relative cost, but they require specialized techniques and means to guarantee their proper application on the slope.

Some of these environmentally integrated systems are described in patent documents WO / 9423133 aimed at the containment of erosion in channels, and the US patent application US 2017/138013 aimed at the formation of a wall system configured to stabilize a slope with an aesthetic arrangement of greenery and plants. Such systems have proven to have good performance, however, as they require a significant constructive deployment, they make them little flexible in terms of their scope of application and adaptation to particular situations.

On the other hand, there are various developments, as it appears in ES2477317A1, where the methodology of the mixture of inert components and plant materials for the rooting of the vegetation according to the environmental conditions from the biological point of view is affected. In this publication, the contribution of the mixture of components to the slope is mandatory, whether or not they are retained by a retaining mesh, so the disclosed invention does not work without the mentioned contribution.

Other systems that support the provided material are disclosed in patents ES2301263A1, ES2043134T3 or ES2077535A1, however the disclosed systems do not adapt to the specific requirement of each slope as they have constant dimensions and characteristics.

Other slope stabilization techniques, such as those applied for the protection or stabilization of riverbanks, are shown developed in WO2014 / 076628, DE3507428, JP2001140239, which are intended to contain a heavy element inside, arid or organic matter, which, attached to the sloping surface of the land, outside the river or lake element, protects it by opposing the forces produced by the movement of water.

Unlike submerged or partially submerged slopes in bodies of water, in the case of erosion protection on non-submerged slopes, the acting forces are the dragging of the rains, the wind and the chemical alteration of the materials, which fall from the slope due to the gravitational action, for which the erosion control techniques will be different for both cases.

Based on the previous discussion, the need to provide a system for the control of erosion in slopes that can be adapted to the particular conditions of each slope and that allows, based on such conditions, or to support only the material original slope, or provide different amounts and types of materials added to fix those materials that originally form the slope, avoiding erosion and favoring the growth of vegetation on it, and where the construction component of the system implies the least possible deployment, making it cheaper costs and facilitating its implementation

DESCRIPTION

To overcome the need encountered, the present invention provides a system for the containment of erosion on slopes that aims to create an artificial support for an existing or contributed plant substrate, aggregates of different sizes with great resistance to erosion and a great drainage capacity, and support of revegetant elements, which provide the growth capacity of the vegetation through seeds and fertilizers, on slopes with different levels of inclination, types of soil, rock or concrete walls that comprise at least one rolled element intended to be arranged on an inclined surface of the slope in an angular orientation "p" with respect to a reference line "H" of the slope, said reference line "H" corresponding to the horizontal of the ground, said rolled element being configured to support containment elements from erosion from a mesh structure wound on itself a number of turns "n"; and anchoring means configured to anchor the rolled element to the inclined surface of the slope.

In alternative embodiments, the slope erosion containment system comprises at least one additional mesh element structurally linked with the rolled element with respect to a lower part of the rolled element that is in contact with the inclined surface of the slope, or with respect to a upper part of the rolled element which is opposite the lower part, the additional mesh element being configured to at least partially cover an inclined surface of the slope, and also configured to receive and support erosion containment elements.

In other alternative embodiments of the slope erosion containment system the rolled element comprises a tubular element around which the mesh structure is wound the number of turns "n".

In other alternative embodiments of the system for the containment of erosion on slopes, the rolled element additionally comprises a sheet formed from material of plant origin rolled together with said rolled element and / or a sheet formed from artificial material rolled together with the element. rolled up and / or a combination of said sheets.

In alternative embodiments of the slope erosion containment system the additional mesh element is configured as an extended portion of the rolled element or is a structural element independent of the rolled element.

In other embodiments of the system for the containment of erosion in slopes the additional mesh element is coupled to at least two coiled elements spaced apart from each other, where a first end of the additional mesh element is coupled at the top or bottom of one of the rolled elements, and a second end of the mesh element engages on top or bottom of the other of the rolled elements.

One of the advantages achieved by the system of the present invention is related to the self-supporting capacity of the rolled elements once they have been fixed to the inclined surface of the slope by the anchoring means since, unlike other systems, by the In the form of its construction, no additional elements are required for fixing said wound elements, providing a greater adaptability of the system and a lower cost compared to currently known techniques.

Another advantage provided by the system for the containment of erosion in slopes of the invention is that the arrangement of the rolled elements is foreseen for the entire surface of the slope to be treated, said rolled elements not being punctual or isolated, since the inclusions of such Rolled elements their dimensions and separations are determined so that their area of action conveniently overlaps with adjacent elements, and therefore, the area of action extends to the entire slope.

Another notable advantage is related to the ability of the system to support a layer of material provided on the slope through the different configurations with which the additional mesh elements can be arranged with respect to the rolled elements, which may be the provided material. topsoil or arid, where vegetation can develop that takes root in said layer provided or even on the slope if this is possible, or provide the necessary protection against aggressive elements, chemical alteration, rain and wind mainly, which cause the alteration and transportation of the material that originally formed the slope.

BRIEF DESCRIPTION OF THE FIGURES

The foregoing and other advantages and characteristics will be more fully understood from the following detailed description of some exemplary embodiments with reference to the attached drawings, which are to be considered by way of illustration and not limitation, in which:

- Fig. 1 is a perspective view in which two coiled elements can be seen arranged on the inclined surface of the slope.

- Fig. 2 is a front view of the slope in which the arrangements of the rolled elements are observed with respect to an inclination referred to the horizontal of the ground.

- Fig. 3 is a profile view of a rolled element.

- Fig. 4 is a front and profile view of a wound element comprising a tubular element as the core of the winding.

- Fig. 5 is a perspective view in which the additional mesh element arranged between two wound elements is observed.

- Fig. 6 is a profile view of the rolled element with the additional mesh element coupled thereto in two different ways.

- Figs. 7A to 7D show the different configurations in which the additional mesh element is linked with two closely wound elements.

- Fig. 8A and 8B show the space between the additional mesh element and the inclined surface of the slope filled with erosion containment elements.

DETAILED DESCRIPTION OF AN EXAMPLE OF EMBODIMENT

In the following detailed description, numerous specific details are set forth in the form of examples to provide a thorough understanding of the relevant teachings. However, it will be apparent to those skilled in the art that the present teachings can be practiced without such details.

According to the figures that accompany the description, the present invention discloses a system for the containment of erosion on slopes in which at least one rolled element (1) is arranged on an inclined surface (A) of the slope (T), where said rolled element (1) is configured to support erosion containment elements (2). Figure 1 shows the arrangement of two rolled elements (1) on the inclined surface (A) of the slope (T) which has an inclination "B" with respect to a plane that is parallel to the horizontal of the ground.

The rolled element (1) is formed from a mesh structure (3) rolled on itself a number of turns "n". The rolled element (1) is made with a retaining system (not shown) that rotates on itself. The same number of turns "n" to wind the mesh structure (3) until reaching a diameter "D" or height that ensures its robustness and retention capacity of the elements for erosion control (2) according to the design for each slope (T). Depending on the characteristics of the slope (T) and the elements to be retained, a type of wire mesh structure (3), the number of turns "n" and a necessary winding tension will be used to obtain a winding density, a retention capacity and a diameter "D" or suitable height, as seen in figure 3. Once the required dimensions for the rolled element (1) have been obtained, it is tied so that it does not lose her CARACTERISTICS.

On the other hand, and due to the wound configuration, the wound element (1) is a substantially cylindrical body comprising an axial shaft (1 ') This axial shaft (1') defines an angular orientation "p" of the wound element (1 ) with respect to a reference line "H" of the slope that is parallel to the horizontal of the terrain. Therefore, and as can be seen in Figure 2, the arrangement of each wound element (1) will be a function of the value of the angular orientation "p" with respect to the reference line "H". For example, it will be considered horizontal when the value of "p" is zero degrees, or inclined to the right or left, when "p" has a value other than zero.

In preferred embodiments, the mesh structure (3) with which the rolled element (1) is formed, is a "sheet" of a triple twist mesh (MTT) that is wound on itself until the diameter "D" is achieved. or desired height, this should not be taken as limiting, since it is possible to choose a different mesh structure (3) according to each particular application of the system of the invention. A length "L" of the wound element (1) will be determined by the length of the sheet of the mesh structure (3) used. Non-limiting examples of some of the materials used as mesh structure (3) are steel wire meshes triple twist and single twist with different wire diameters, hole size and steel protection by Galvanized, Galfan or PVC.

In other alternative embodiments of the system of the invention at least one wound element (1) comprises a hollow tubular element (6) around which the mesh structure (3) is wound the number of turns "n", according to how can be seen in figure 4. This tubular element (6) is incorporated to provide greater structural stability to the rolled element (1) when the forces of the system incorporated in the slope (T) require it.

In an embodiment not shown, the rolled element (1) additionally comprises a sheet formed from material of plant origin rolled together with said rolled element and / or a sheet formed from artificial material rolled together with the rolled element and / or a combination of said sheets. This additional sheet can be chosen from, but not limited to, coconut or jute fibers, twigs, polypropylene mesh (such as KMat), geogrids, turf or vegetable blankets and / or combinations of these. In this embodiment, the rolled element (1) can also include the tubular element (6).

On the other hand, the rolled element (1) is fixed to the inclined surface (A) of the slope (T) with anchoring means (4). Said anchoring means (4) are chosen from metal pegs or bars, in the shape of a club or U and steel bolts, these elements being of common use within the technical field of the invention. The quantity and type of these elements chosen as anchoring means (4) to be placed in each case, is the result of the sizing and calculation developed with the described system of the invention, together with the determination of the size of the rolled element (1), separation between these elements, and other dimensions of the system to adapt it to the type of slope to be protected according to the slope, geology and climate.

As has been said in previous lines, the objective of the erosion control system is to create an artificial support to the existing or contributed plant substrate, for which the rolled element (1) is configured to support elements of containment of the erosion (2) that are chosen from arid materials of different sizes with great resistance to erosion and a great drainage capacity, and revegetant elements, which provide the growth capacity of the vegetation through seeds and fertilizers on the slope.

Alternatively, and as can be seen in Figure 5, the system for the containment of erosion in slopes of the invention comprises at least one additional mesh element (5) structurally linked to the rolled element (1) or with respect to a part bottom (1A) of the rolled element (1) that is in contact with the inclined surface (A) of the slope (T) or with respect to an upper part (1B) of the rolled element (1) that is opposite the lower part (1A) said additional mesh element (5) being configured to at least partially cover the inclined surface (A) of the slope (T), and also configured to receive and support erosion containment elements (2).

This additional mesh element (5) can be a "sheet" of a mesh that in turn can be an unrolled extension of the rolled element (1) or a structural element that is coupled to said rolled element (1) but is Depending on the part from which the additional mesh element (5) is attached or from which it comes out with respect to the rolled element (1), it will be considered upper or lower, as seen in figure 6 and the direction with respect to the slope "B" of the slope will be ascending or descending.

When the additional mesh element (5) is linked to two wound elements (1), as in figure 5, the length of the additional mesh element will be measured between the axial axes (1 ') of each wound element (1) . Furthermore, as seen in Figures 6 to 8B, the additional mesh element (5) can start from the top (1A) of a wound element and reach the opposite (1B) in the next wound element (1), and combinations of the same that also depend on the direction of the inclination in which it is built. The latter is important when the additional mesh element (5) is an extension of the rolled element (1).

The additional mesh element (5) can be a triple twist mesh (MTT) "sheet", but this should not be construed as limiting, since both for the wound element (1) and for this additional mesh element (5) the mesh configuration will be chosen based on each particular application.

With reference now to Figures 7A to 7D, according to the position of the additional mesh element (5) with respect to the wound element (1) (or the wound elements (1) when coupled to more than one), it is generated a space (E) between the inclined surface (A) of the slope (T) and the additional mesh element (5), and this space (E) can be conveniently filled with erosion containment elements (2), as observed in Figure 8A. In some applications the space (E) can be filled with a material that can be topsoil or gravel, although it is possible to fill it with other materials such as reused plastic waste, pine bark, sand or concrete, without being limited to any of these.

At the same time, the additional mesh element (5) can support on top other erosion containment elements (2) that may be the same or different from those that have been deposited between the inclined surface (A) and the mesh element additional (5), as seen in figure 8B.

It is important to highlight that the system of the present invention is designed for each particular application taking into account that, according to the size of the slope (T) to be treated, as many rolled elements (1) as necessary as well as mesh elements can be arranged additional (5) associated with them so that, in their different combinations due to their arrangement and materials, they are able to retain the elements of containment of erosion (2) according to the climatic conditions and geomorphology of the area where said slope is located ( T).

Claims (6)

1. System for the containment of erosion on slopes characterized in that it comprises - at least one wound element (1) formed from a steel wire mesh structure (3) wound on itself a number of turns "n" at a predefined winding tension, said wound element (1) being provided to be arranged on an inclined surface (A) of the slope (T) in an angular orientation "p" with respect to a reference line "H" of the slope corresponding to the horizontal of the ground; - anchoring means (4) configured to anchor the rolled element (1) to the inclined surface (A) of the slope (T); and - at least one mesh element (5) extending from the rolled element (1) with respect to a lower part (1A) of the rolled element (1) that is in contact with the inclined surface (A) of the slope ( T), or with respect to an upper part (1B) of the wound element (1) that is opposite to the lower part (1A); said mesh element (5) being configured to at least partially cover the inclined surface (A) of the slope (T), and to receive and retain erosion containment elements (2). 2. System for the containment of erosion on slopes according to any of the preceding claims, wherein the wound element (1) comprises a hollow tubular element (6) around which the mesh structure (3) is wound. 3. System for the containment of erosion on slopes according to any of the preceding claims wherein the rolled element (1) additionally comprises a sheet formed from material of plant origin rolled together with said rolled element and / or a sheet formed from artificial material rolled together with the rolled element and / or a combination of said sheets. 4. System for the containment of erosion in slopes according to any of the preceding claims, wherein the mesh element (5) is configured as an extended portion of the rolled element (1). 5. System for the containment of erosion on slopes according to any of claims 1 to 3, wherein the mesh element (5) is a structural element independent of the rolled element (1). 6. System for the containment of erosion on slopes according to any of the preceding claims, wherein the mesh element (5) is coupled to at least two wound elements (1) separated from each other, where a first end (5A) of the mesh element (5) is attached to the top (1A) or to the bottom (1B) of one of the wound elements (1), and a second end (5B) of the mesh element (5) is attached to the top (1A) or in the lower part (1B) of the other of the rolled elements (1).