FR2471740A1 - Composite geo:textile laminate - has at least three layers, for irrigation of desert lands - Google Patents

Abstract

Composite geotextile laminates for use in earthworks comprise a filter layer, a drainage layer and a reinforcing layer. The laminate of the invention is used with a water-tight film, not for drainage but for irrigation of tropical or desert soils, without excessive surface evaporation, or water loss by filtration. The central drainage layer ensures a regular distribution of water over all its surface, and the upper filter layer supplies the arable soil with moisture by a 'wick' effect, without clogging, and without loss of soil nourishment. A low pressure pump may be introduced in a closed circuit having perforated pipes to assist the regular supply of water to the geotextile.

Description

The present invention relates to a new application of geotextiles to the underground irrigation of tropical desert soils
We designate under the name of geotextiles composite materials based on textile materials, in woven or non-woven form, used in geotechnics, These geo-textiles can possibly consist of the assembly of several layers and their domains d There are many applications: sub-basements for roads and railways, temporary access routes during construction, drainage channels, construction of earthen dykes or reservoirs, earthworks, embankments, where they play a role, among others drying to drain. To play this role effectively, geotextiles can have several layers of different properties9 for example and from top to bottom
- a filtering layer ensuring the separation of water and solid particles, and protecting the drain from the risks of clogging,
- a draining layer, looser and thicker facilitating the evacuation of water,
- an anticontaminating or reinforcing layer, most often consisting of a second filtering layer and / or a reinforcing fabric.

The Applicant has discovered that these types of textile complexes, supplemented by a waterproof film, could find interesting applications not only, as is already known, for the drying of the grounds but also for the enrichment of the ground with water, in a word that they could not be used either to evacuate water but well to bring it, and that this use like "drain with back" made it possible to ensure the underground irrigation of the desert grounds. tropical without excessive surface evaporation or loss of water by infiltration.

 The subject of the invention is therefore a new application of geomembrane geotextile complexes, of the type comprising the association of at least one filtering layer, a draining layer and an impermeable layer, optionally assembled and associated with a composite material, to irrigation. underground tropical desert soils by reverse drainage effect, the geotextile layer being buried in the ground, filter layer at the top. The water arriving in the ground will therefore be stopped by the waterproof membrane constituting the lower part of the geotextile, which avoids all wastage and infiltration of water into the soil below said membrane as well as any loss of nutrients, possibly contained in this water; the central draining layer for its part ensures the routing and the regular distribution of this water over its entire surface, thereby allowing a real irrigation of the soil, this irrigation being ensured by the upper filtering layer which diffuses by effect of ' tmeche ", without clogging, the humidity in the cultivable soil with possible contribution of the nourishing elements introduced into the water at the roots of the plants.

 According to a preferred embodiment of the invention, a regular supply of water to the geotextile sheet is provided by at least one pumping device under low pressure, operating in a closed circuit and comprising at least two perforated pipes connected by the geotextile sheet. the two ends of which are fixed along a generator to each of said pipes, said sheet enclosing said pipes, the filter layer being pressed against the perforations while providing a solution of continuity along said generator at the level of the filter layer .

The water inlet pipe and the return pipe are advantageously placed in two different horizontal planes, in order to give a slight slope to the irrigation assembly to facilitate the circulation of the liquid, in the draining layer; possibly an analyzer-doser system is inserted in the circuit in order to allow the introduction and then automatic readjustment of feeder and / or fertilizer elements in the water.

The two pipes are possibly very slightly clinched in relation to the ground plane in the direction of the flow of the liquid, in order to reduce the load on the pump.
If the geotextile is used in stony soils, it is preferable to reinforce the lower part of the waterproof membrane with a textile reinforcement in order to protect it from punctures. This frame is advantageously constituted by any high-performance fabric or nonwoven.

The present invention will be better understood moreover and its advantages will emerge clearly from the description which follows with reference to the appended schematic drawing in which
Figure 1 is a very schematic sectional view of a geotextile used according to the invention to provide underground irrigation of desert soils.

 Figure 2 is a sectional view of the irrigation device using the above geotextile sheet.

The geotextile 2 used according to the invention, for ensuring underground irrigation of desert soils, is of the type constituted by the combination of or at least a filtering layer 3, a draining layer 4, an impermeable layer 5, and an anti-perforation layer 6, possibly assembled together by any means known per se.

The filtering layer 3 is advantageously made of a non-woven material formed of fibers of fine titer, mono or multicomponents, obtained by any conventional process of fiber bonding, whether mechanical, physical or chemical. The nature and fineness the fibers constituting the filtering layer are chosen according to the nature of the soil to be irrigated and so as to effectively protect the draining layer against any risk of clogging. The drainage layer 4 is made of any material having a power sufficient transmissivity; thus it can be an extruded plastic grid, a corrugated plastic plate or a non-woven material, but of greater thickness and coarser fiber structure, than those of the material constituting the wire layer. It is thanks to the many voids existing in this coarse structure that the geotextile transports water in its plane and ensures its lateral diffusion. The impermeable layer 5 is advantageously made of a film of plastic or elastomer, for example made of polyvinyl chloride, to the lower part of which is optionally associated a textile reinforcement 6 consisting for example of a woven material as shown in 6a or of a nonwoven shown in 6b, with high performance in order to protect the plastic film against any perforations that could affect its sealing.

 We see in Figure 2 the application of these geotextiles to the development of cultivable desert soils, allowing the circulation of a nutrient liquid and its diffusion to the roots of plants by means of two closed circuit feeding devices placed side by side. These devices, intended to provide underground irrigation of the soil in which they are placed, essentially consist of the perforated pipes 7 and 8 of the pump 9, of an analyzer-doser system 10 and of an adjustable feed valve. automatic 11.

 The two perforated pipes 7 and 8 are connected by the geotextile sheet 2, the two ends of which are fixed, by any means known per se, along a generator of the pipe.

In the embodiment shown in the figure, the geotextile sheet 2 almost completely encloses the pipes 7 and 8, the filtering layer 2 being removed pressed against the perforations of the pipes. It is, however, provided by any means known per se 12, a continuity solution at the level of the filtering layer so as not to harm the subsequent diffusion of water in the part of the geotextile serving as a connection between the two pipes. This is how lton can for example staple the corresponding parts of the filtering layer after wrapping the geotextile around the pipe. According to another embodiment (not shown), only the filtering and draining layers are pressed against the perforations of the pipe, the impermeable layer covering only very partially the latter.

 The pipe 7, which ensures the arrival of water to the geotextile sheet 2, is placed on a plane slightly greater than that of the pipe 8, which ensures the return of the water to the pumping device.

In addition, the pipes 7 and 8 have a very slight inclination in the direction of flow of the liquid, relative to the horizontal plane of the soil in which they are buried. The number of pumps to be installed depends on the length of the field and can only be defined experimentally after a test carried out in the soil in question.

The water supply (not shown) is controlled by the valve 11, which can be connected, in a manner known per se, to an automation device regulating the supply as a function of the desired humidity.

The analyzer-doser 10 makes it possible to add nutrients to the water introduced into the device at will and to compensate for the sampling carried out by the plants.

An independent water supply system (not shown) is provided to compensate for losses by surface evaporation and by the assimilation of plants
It is clearly seen in FIG. 2 that once the pump 9 is started, the water will circulate from its entry into the perforated pipe until it is collected at the low points of the perforated pipe 8 through the irrigating geotextile sheet 2. This water , possibly loaded with nourishing elements, will not be able to infiltrate into the ground due to the presence of the waterproof membrane 5 possibly reinforced with an anti-perforation layer, which avoids any waste of water in the deep part of the soil.

The capillary power of the geotextile's filtering layer allows the water to diffuse regularly in the upper part intended for cultivation, this diffusion being accelerated by the depression caused both by the evaporative effect of the sun and by the suction effect exer ee by the roots of plants.

It is of course possible to modify the system of underground irrigation at will by adjusting the pump 8.

Finally, the rain eventually falling on the ground will not be lost in the deep layers of the latter but will be retained by the waterproof membrane and will gradually diffuse into the soil through 1 t through the draining and filtering layers, and will be integrated into the system where it can be recovered
As is obvious and as is clear from the above, the present invention is not limited to the single embodiment described above by way of example; on the contrary, it embraces all variants of it, whatever the number, nature and composition of the filtering, draining and impermeable layers, the method of fixing the geotextile sheet around the pipes and the mode of automation of the system.

 In addition, the invention, although more particularly described for an application to the irrigation of tropical desert soils, can also be used in temperate countries to allow the use, in all weathers, of sports grounds, possibly with suppression of the impermeable layer and the geotextile can then function, acting on the water supply device, either as a drainage device or as an irrigation device.

Claims (3)

- CLAIMS 1 = Application of geotextiles of the type comprising the association of at least one filtering layer, a draining layer, an impermeable layer, possibly assembled and associated with a lower protective layer, to underground irrigation of tropical desert soils - cals, characterized in that this irrigation is carried out by reverse drainage, the geotextile being buried in the ground, filter layer at the top  2 - Application of the geotextile according to claim 1, characterized in that the filtering layer is made up of non-woven material in the form of fibers of fine titer, mono or multicomponent, the nature and fineness of which depend on the nature of the soil and that of the draining layer whose clogging it must prevent, the draining layer is made of any material having a high transmissivity and is chosen from grids of extruded plastic; corrugated plastic sheets or coarse fiber nonwovens, the impermeable layer is a plastic or elastomer film and the protective layer is a textile composite material chosen from woven or nonwoven fabrics.  3 - Device for implementing the application according to claims d and 2, characterized in that it consists of a pumping device with a closed circuit comprising at least two perforated pipes buried in the soil to be irrigated, connected by the geotextile, the two ends of which are fixed along a generatrix of said pipes, said geotextile enclosing said pipes, filter layer pressed against the perforations, while providing, along said generator, a solution of continuity ' at the level of the filtering layer. i Device according to claim 3, characterized in that the eua inlet pipe and the return pipe of which placed on two different planes, the two pipes being optionally inclined relative to the horizontal plane of the ground in the direction of flow some cash.  5 - Device according to any one of claims 3 and 4, characterized in that the water supply is controlled by a valve connected to a program device 'depending on the desired humidity.