WO2016092167A1 - Geosynthetic for soil reinforcement with multi-modulus behaviour - Google Patents

Abstract

The invention relates to a geosynthetic for soil reinforcement which has, in a representation of the variation of the modulus of the geosynthetic with the deformation in the x-axis and the applied tension in the y-axis, at least two separate elongation areas under tension in at least one direction, respectively: a first major elongation area for deformation of the geosynthetic comprised between 0 % and a limit comprised between 0.5 % and 6 % in at least one direction for tensions of 0 and 10 to 400 kN/m corresponding to this limit deformation; and a second elongation area, beyond said first elongation area, characterised by a maximum deformation of 2 % to 20 % in at least one direction for tensions of 100 to 3000 kN/m at least, corresponding to said maximum deformation. The difference in the elongation areas is due to the nature of the threads that make up the geosynthetic and/or the structure of said geosynthetic.

Description

 MULTI-MODULATING BEAM REINFORCING GEOSYNTHETICS

TECHNICAL FIELD The invention relates to a geosynthetic, geo-textile, geogrid or geocomposite geotextile applied in the field of civil engineering, and more particularly, in the field of soil reinforcement during the construction of road-type structures. or rail. This type of situation can also be found under water retention or treatment basins or in other types of structures, such as hydraulic structures or waste storage facilities.

This geosynthetic is made so that it provides soil reinforcement in a civil engineering structure to ensure a high performance of resistance, especially in the case of cavities or faults causing a risk of collapse or collapse, or a reinforcement of the load transfer platforms on rigid inclusions of piles type.

The geosynthetic object of the invention differs from the materials known from the prior art by its behavior under traction force. Thus, it has a very low modulus (that is to say the slope of the curve giving the tensile force on the ordinate as a function of the elongation on the abscissa) at the first level of elongation allowing a rapid initial deformation resulting local collapse or subsidence or rigid pile-type inclusions. Then during a subsequent elongation, a higher module makes it possible to develop significantly greater reinforcing properties that limit the settlement of the structure and ensures its safety.

PRIOR ART

Geotextiles or reinforcement geosynthetics are commonly used in civil engineering structures as reinforcement structures subject to stress.

They are in the form of sheets, whose conditions of use are defined and applied in compliance with the rules and codes of the construction. They must ensure the longevity of the works and bring the security and durability of these in connection with their use. Until now, they have always acted in an immediate reaction armature, that is to say by opposing the movement of the ground, the objective being to stay as close as possible to the initial state. For this purpose, all the geotextiles or geosynthetics proposed to date are made with fibers of high modulus of traction and with the minimum of embossing (ratio between the length of the threads and the dimension of the fabric in the same direction) so that oppose to efforts, even in case of limited deformation. In order to improve these materials by providing economic solutions, it has been proposed, for example in documents FR 2 767 344 or FR 2 932 820, to use fibers of different types in order to confer on these materials a different behavior, and more particularly by introducing higher module fibers for the usual service conditions. The tensile curves of these geosynthetics show a reaction capacity in two stages acting with offset during their solicitation.

More precisely, it induces an immediate reaction of the geosynthetic, tending to oppose the deformation of said geosynthetic using in particular the characteristics of one of the fibers having the highest modulus of deformation at the start, followed by a delayed reaction obtained by a second fiber with greater elongation, allowing a "safety parachute" type effect, that is to say avoiding a breakage of said geosynthetic, and therefore the consequences of such a breakdown of the falling type of a car or a train following the occurrence of a fault or other. . However, in the particular case of soils likely to present local deformations of the cavity or fontis type, it is desired to be alerted to the occurrence of collapse or subsidence following the occurrence of such a phenomenon, while limiting the consequences of the phenomenon on the structure. Similarly, in the case of load transfer platforms at the base of embankments on rigid inclusions or on piles, it is first of all desirable to allow the charge transfer to take place above the inclusions, before limiting the deformations. This is the object of the present invention.

In fact, in the case of such structures, the prior state of the art consists of sizing the geosynthetic as follows: determination of the maximum allowable deflection for the geosynthetic in order to guarantee a maximum level of settlement at the surface of the embankment covering said geosynthetic; this maximum admissible deflection of the geosynthetic corresponds to a maximum deformation (s _max ) thereof; it follows the definition of a minimum geotextile module corresponding to this deformation (s _max ), guaranteeing the maximum deflection of the geosynthetic and therefore the maximum settlement on the surface;

 determination of the minimum allowable traction to take up the forces transmitted by the embankment situated above the cavity or the fault; in fact, it is inferred from the elements of FIGS. 3A and 3B that the greater the allowable deflection of the geotextile, the less the tensile force required, and therefore permissible, of the geosynthetic is high.

Analogous reasoning can be used for the calculation of reinforcement geosynthetics in the load distribution overlays on inclusions.

By "settlement" is meant the deformation of the structure visible on the surface.

By "arrow" is meant the difference between the initial geosynthetic dimension when the web is positioned horizontally, and the dimension reached by said web at the lowest point of the deformation.

The deformation of the geosynthetic designates the local elongation of the latter (expressed in%) under the effect of the tensile stress.

The modulus of a geosynthetic for a given strain ε is the quotient of the tensile force on the deformation.

OBJECT OF THE INVENTION

The present invention relates to a geosynthetic soil reinforcement, particularly in such situations of cavities, faults or load transfer platforms, exhibiting a behavior in two steps:

a first step allowing a visible deformation or in any case measurable by a collapse or collapse sensor, and therefore in which the geosynthetic is likely to deform relatively significantly; a second step stopping this deformation, blocking and at least strongly limiting the elongation of said geo synthetic. For this purpose, the invention proposes a reinforcing geosynthetic having at least two different elongation zones under tension in at least one direction, respectively:

 a first major elongation zone for a deformation of the geo synthetic between 0% and a limit of between 0.5 and 6% deformation in at least one direction for voltages between 0 and 10 to 400 kN / m corresponding to this deformation limits;

 a second elongation zone, beyond said first elongation zone, characterized by a maximum deformation of between 2 and 20% of deformation in at least one direction for voltages of between 100 and 3000 kN / m corresponding to this maximum deformation.

The differential of the elongation capacities results from the nature of the constituent yarns of the geo synthetic and / or the structure of said geotextile for example by the creation of a fiber embossing.

The geosynthetic of the invention makes it possible to obtain a material with a traction curve with at least two slopes. The product has in particular in the first elongation zone a very low (or almost zero) module, then in the second elongation zone a high deferred modulus (value 500 to 3000 kN / m at least, or even much more.

The invention may furthermore provide a third zone of elongation, with either an intermediate module (creation of a safety "parachute" effect - see above), or a higher module providing ultimate security in the event of risk of enlargement of the cavity to very large dimensions (from 5 to 15 or 30 meters in diameter or width).

The objective is to reinforce a soil at risk, that is to say likely to appear cavities or faults, integrating in the latter a warning function provided by the initial deformation of the geotextile, making it detectable, in particular visually, a limited settlement of the structure.

This detection will be perceptible either on the surface of the work and will be visual or instrumented, or by measurement at the geosynthetic positioned under the embankment. Such an instrumentation consists, for example, of optical fibers associated with a Braggs or Brillouin-type network, of extensometers bonded or reported on the geosynthetic, or of any other means capable of detecting a modification of a physical quantity, such as a length. These instrumented detection systems are integrated into the textile construction or reported in a subsequent step by gluing or any other means of attachment.

Furthermore, it is demonstrated that in the case of cavity formation or in the context of the realization of load distribution mats on rigid inclusions, or on regularly spaced piles, the fact of accepting a certain initial deformation makes it possible to limit the necessary resistance of the geosynthetic.

Indeed, the geosynthetic must be dimensioned according to the maximum size expected of the cavity or the fault on the considered site. For the maximum settlement on the surface, this fixes the maximum deflection of said geosynthetic, and therefore the minimum modulus at the maximum deformation of the geosynthetic (s _max ).

In the case of a conventional mono-material geotextile, thus assimilated by simplification for reasoning to a single-module (single module for all deformations less than (s _fmax ), during the initial opening of the cavity or the For example, for a quarter (or half) of the diameter of the cavity or the width of the fault, the deflection of the geosynthetic and its deformation (if _nt ) for this intermediate phase are very small. order of 10 (3 to 15) times lower than the tolerated value for sizing.

It follows that the surface displacements of the embankment are not observable, and that, even for the geosynthetic, the deformations are often too weak to be measurable by direct instrumentation (optical fiber or extensometer).

It is obvious that the geotextile is largely oversized for the initial opening phase of cavities, that is to say when it is smaller than the maximum size provided for in the specifications, mainly for two reasons:

 1. The geotextile is designed for a larger cavity.

2. the geotextile is designed to resist over time with a material (polymer) that flows, that is to say whose elongation, when actually subjected to a stress, increases with time. The geotextile is therefore oversized so that its resistance is still sufficient after 2, 10, 25 or 100 years according to the specifications.

The invention proposes a geosynthetic able to deform during the opening phase of the cavity, or the fault, while ensuring the specifications, both in terms of settlement and in terms of strength, for the final configuration of the notebook charges During the opening phase, for example for a quarter (or even half) of the diameter of the cavity or the width of the fault, the geosynthetic of the invention allows the settlement to occur while ensuring the stability of the structure and by ensuring compliance with the specifications, and the permissible settlement of the surface fill. It thus makes it possible to obtain intermediate deformations (if _nt ) much higher than those obtained with a mono module (of the order of 2 to 3 times). This then makes it possible to reach easily measurable levels of deformation from the beginning of the formation of the cavity or fault, and thus to study or monitor the evolution of the situation to intervene if necessary before risk of rupture or simply plan the rehabilitation of the structure.

Then, during the progression of the opening resulting from the cavity or the fault until the final configuration, the higher module allows the geosynthetic to oppose the important displacements of the soil, guaranteeing the stability of the structure following the specifications.

It can be encountered in the context of works to realize the risk of formation of very large cavities, whose diameter is more than 5 m, up to 10 or 30 meters.

In this case, alternative solutions to geosynthetics are very expensive. The solutions implementing conventional geotextiles are themselves limited by the required ultimate strength level, typically from 2000 to 6000 or 8000 kN / m, possibly in several layers.

These solutions may require very high strength with very high modulus aramid type polymers.

The invention makes it possible to propose a solution at least at the level of the security, by accepting a significant apparent deformation, but by making the polymer work once the membrane effect, that is to say the distribution of the forces in the different directions of solicitation, already well in place.

It can even work in three progressive modules, which allows to use the most resistant and expensive polymer in the ultimate case of very large opening, but the maximum of its effectiveness for a limited time before repair in the measure where it will not have undergone previous creep, having not been solicited. Similarly, the multi module product of the invention, having a high modulus offset from the origin, has advantages in other rigid inclusion type applications. The geosynthetic is then installed at the base or up to mid-height (possibly in several layers) of the charge transfer layer above the rigid inclusions. An initial deformation, before solicitation of the geosynthetic in the high modulus zone, allows a deformation which reduces the maximum required resistance of said geosynthetic, or improves the charge transfer on the inclusions. This synthetic geo allows a first distribution of the charge transfer on the rigid inclusions before opposing the subsequent and long term deformations thanks to the higher modulus.

In such an application, the embankment is placed in two stages: a first step of depositing a portion of the embankment, followed by compaction inducing the deformation of the geosynthetic for its implementation and its tensioning . There are undulations of the backfill layer in place, which is filled in a second step by adding backfill, which is almost no longer deformed to compaction, the geosynthetic then working in the high modulus zone.

According to a first embodiment of the invention, the geosynthetic is a knitted structure made by discarded mesh technology, incorporating into a chain (production direction) a first series of rectilinear yarns, and a second series of yarns linked to possible yarns. weft (arranged in transverse directions), or to a possible support material (in the case of a geocomposite, and for example constituted by a woven fabric, a nonwoven fabric, a knitted structure, a film, a membrane or even several layers of these materials) by binding yarns capable of imparting to them an undulation of amplitude chosen as a function of the desired embolization and, consequently, of the constitutive law, and in particular the limits of the deformation zones of said geosynthetic.

According to a second embodiment of the invention, the geosynthetic is a woven structure, constituted by a base with plain weave or taffeta, with son in a form floated in warp or weft, that is to say passing over several warp or weft son, the amount of past warp or weft son conditioning the constitutive law, and in particular the limits of the deformation zones of said geosynthetic under the effect of immediate traction. The floats, being less wavy, are immediately put in tension during the tensile stress of the geosynthetic, which corresponds to the first zone of the stress / strain curve. According to the invention, the constituent yarns of the structure as well as, optionally, the binding yarns are made from fibers with a high tensile strength, and preferably chosen from the group comprising PET (polyethylene terephthalate), polyamide, polypropylene, polyethylene, polyvinyl acetate, aromatic polyester (eg Vectran ^® ), aramid, carbon, steel, stainless steel, biosourced fibers (polylactic acid, polybutylene succinate ( PBS)), or even natural fibers (cotton, hemp or linen).

According to an optional feature of the invention, the geosynthetic may be associated with another geosynthetic capable of additionally providing the functions of drainage, filtration, protection, or even total or partial sealing, of anti-contaminant, vector miscibility, anti-pollution treatment, etc.

In summary, the multi-module geo synthetic of the invention offers significant advantages in terms of performance and economic gains. In the different variants it allows:

 • to propose an alert function in the event of faults or cavities;

 • better load transfer efficiency in case of rigid inclusions;

 • a more economical design of geo synthetic that works with larger arrows, thus requiring for the same efficiency of more limited resistances, and therefore the implementation of less expensive fibers;

 • in the case of rigid inclusions, a decrease in the price of the building site inherent to a lower density of the necessary mesh size and a simplification of the inclusion heads;

• to offer an unprecedented security solution for the risk of very large cavities larger than 5 meters that require very high resistance.

Moreover, the geo synthetic of the invention may have at least three different elongation zones under tension in at least one direction, respectively:

A first major elongation zone for deformation of the geosynthetic between 0.5 and 6% in at least one direction for voltages between 0 and 400 kN / m corresponding to this limiting deformation;

 A second elongation zone, beyond said first elongation zone, characterized by a maximum deformation of between 2 and 20% in at least one direction for voltages of between 100 and 3000 kN / m at least, corresponding to at this maximum deformation,

A third zone of elongation, beyond said second elongation zone, in which the modulus of the fibers constituting it is higher or lower than that of the fibers constituting said first and second elongation zones. BRIEF DESCRIPTION OF THE FIGURES

The manner in which the invention can be realized, and the advantages which result therefrom, will emerge more clearly from the following exemplary embodiments, given as an indication and not by way of limitation, in support of the appended figures.

 Figure 1 is a schematic representation in section of a work positioned above a fault or cavity, implementing a geosynthetic.

 FIGS. 2A and 2B schematically illustrate two configurations of structures on rigid inclusions, without (FIG. 2A) and with FIG. 2B, charge transfer platform. FIGS. 3A and 3B respectively illustrate, according to the prior art and according to the invention, the principle implemented, and in particular the "membrane" effect.

 Figures 4A and 4B are views similar to views 3A and 3B, tending to illustrate the principle implemented by the invention on rigid inclusions.

 FIG. 5 is a representation of the variation of the geo synthetic module of the invention, with the deformation on the abscissa and the applied voltage on the ordinate. The first zone of elongation according to the invention corresponds to the part A on the axis of the deformations, the following zones to parts B and B '(etc)

 FIGS. 6A and 6B are curves similar to FIG. 5 of variants of the invention. Figures 7A, 7B and 7C are schematic representations of different variants of the geosynthetic of the invention, the latter being then a knitted structure.

 FIGS. 8A, 8B and 8C are other variants of the geosynthetic of the invention, still in knitted mode.

 Figures 9A and 9B illustrate another embodiment of the geosynthetic of the invention, the latter being in woven mode.

Figures 10A and 10B are views similar to Figures 8A and 8B of an alternative embodiment.

DETAILED DESCRIPTION OF THE INVENTION FIG. 1 shows one of the preferred applications of the invention. In this case, the geosynthetic 1 is intended to support the embankment 4, placed on the ground 2, likely to present risks of localized collapse due to the opening of cavities or faults 3. In Figure 1, the fault is represented, but it is obvious that during the construction phase, the fault does not exist yet. As can be seen, when the fault 3 occurs, the geotextile of the invention surmounted by the embankment 4 collapses locally in line with said fault, this subsidence being intended to be visible or in any case detectable. by instrumentation at the geotextile level.

In the case of structures set up with rigid inclusions, that is to say generally on soft ground, it is previously planted at regular intervals with piles 5, on which will firstly be positioned geo synthetic 1. A first layer of embankment 6, also called charge transfer platform, is deposited on said geosynthetic. The weight and the compaction of this layer induce a deformation of the assembly in "bowl" between two consecutive piles. These cuvettes are filled in a second step by the deposition of a second layer of embankment 7.

As will be understood, one wants to be able to visualize the settlement of the structure when it intervenes, for example following the opening of a cavity. It is inferred from Figures 3A and 3B the influence of the geosynthetic design on this settlement, observable in Figure 3A and not in Figure 3B. The invention makes it possible to confer a certain deformation on the geosynthetic, limited however to a maximum deflection, which determines in fact the characteristics of said geosynthetic.

A simple vector decomposition makes it possible to demonstrate that the force Fl (prior art) of traction on the geosynthetic resulting from the recovery of the load P (constituted by the embankment + the overload of operation of the structure) is greater than the force F2 (Invention): it is the interest of the first low modulus zone: thus the tensile stress F2 is lower according to the invention, which limits the cost of the solution.

The deflection of the geosynthetic in the first zone of elongation will induce, when the deformation SAB is reached, the implementation of the characteristics of said geosynthetic in zone B (FIGS. 5, 6A and 6B) with the second series of fibers which will be put in tension,

In order to allow such applications, the geotextile of the invention exhibits a particular behavior, illustrated in particular in relation to the curve of FIG. 5. Thus, according to a first part A, the curve which is at a certain level of resistance RI calculated for the implementation and according to the requirements of the book specifications, allows a relatively consistent deformation of the geosynthetic, which can range from a low value, for example 0.5 to 3% up to values more high (2 to 5, even 6% if necessary). We wish to accept a deformation of the geosynthetic, and corollary of the embankment which covers it, in order to be detectable, in order to play the role of alarm in case of occurrence of a collapse or a subsidence following the formation of a cavity or fault. This deformation is also desired to allow the tensioning of the geotextile in the case of a structure to be implemented using rigid inclusions.

Then, the curve straighten very strongly in B to react and oppose the deformation of the geosynthetic, and corollary to the displacement of the ground or the subsidence or collapse during the formation of a cavity or to initiate the tensioning geosynthetics on rigid inclusions.

It is thus noted that the slope of the second part of the curve is very much higher than that of the first part.

It is understood that this is a radically different approach reinforcement designs known from the prior art.

Indeed, it is demonstrated (see above) that to take up the load corresponding to the embankment plus the overload of operation of the structure, the necessary resistance of the geosynthetic is lower in case of greater deflection of the geosynthetic than the resistance required in case of low initial deformation.

It is recalled that the effect of soil swelling and the vault effect may render the surface deformation invisible, which is not satisfactory if the developer wishes to intervene or at least plan an intervention from the beginning of the project. formation of the cavity or fault for repair, in order to secure its structure and not to take the risk of a major subsequent disaster, when the cavity would eventually exceed in diameter the values provided by geologists.

Similarly, in the case of rigid inclusions, by similarity, for the same load transfer, the resistance required in the case of Figure 4A is lower than in the case of Figure 4B. And especially in corollary with an equivalent level of resistance, the load recovery is higher in the case of Figure 4A that in that of Figure 4B. In these figures, P represents the weight of the embankment, R the reaction of the soft ground on the geosynthetic, and Tv the vertical component of the voltage applied to said geosynthetic. In addition, the method of setting up the geotextile of the invention in two stages, the first to ensure the tensioning of the geotextile, and the second to finalize the embankment, ensures a greater load transfer on the rigid inclusions, allowing a more economical design of the inclusions: thus, by increasing the allowed spacing between the inclusions (mesh), it is possible to decrease the overall quantity.

FIGS. 6A and 6B show curves similar to that of FIG. 5. The starting of these curves is substantially identical to that of FIG. 5, that is to say a slight slope, followed by a much greater slope, in order to achieve the above result.

With regard to FIG. 6A, the slope curves (zone C) so as to make visible a surface settlement of the structure: in this case, which can occur for example in case of opening of the cavity in several phases, the geosynthetic plays again its role of alarm and the visible deformation on the surface indicates the necessity of a repair of the work. Nevertheless, the geosynthetic, even deformed, allows an anti-fall safety since it prevents the collapse that would normally follow the opening of the cavity. Typically, in this configuration, the fibers used may be the following:

 • PET or polypropylene with high elongation, to give properties to zone A;

• Aramid or PVA (polyvinyl acetate) to impart properties to Zone B;

 • and high-resistance PET (PET HT) for zone C.

With regard to FIG. 6B, the slope increases further (zone C) with respect to zone B ': this case also corresponds to the possibility of an opening of the cavity in several phases, but this time assuming that the specifications allow only a very small additional settlement: it is understood that in this case, the geo-synthetic module in this third part must be even higher in order to recover significant efforts by limiting the deformation (D 'zone). ).

In this case, the fibers used may be the following:

 • PET or polypropylene with high elongation, to give properties to zone A; · High resistance PET (HT HT) for zone B ';

• Aramid or PVA (polyvinyl acetate) to impart properties to zone C FIGS. 7A to 7C show a first embodiment of the geosynthetic of the invention, which has a knitted structure. This knitted structure is obtained according to the technology knit jetty. FIG. 7A thus illustrates a first example of construction of a monodirectional (frameless) geosynthetic that satisfies the desired application. This is a schematic representation in which a first series of son 71 is arranged in a rectilinear manner in the production direction (chain). A second series of son 72 is introduced in a structure imposing said son a given undulation.

These corrugations are obtained by making said threads 72 work around a binding structure, constituted by binding threads 73 and 74, for example with two simple knits in opposition or simply by the "on" feeding, which is achievable with a double positive flow control device illustrated in Figure 8C specific type of looms, that is to say with positive delivery of son in production sense Rachel. specific

These corrugations of the wires 72 thus generate a clogging, whose amplitude can be modulated according to the desired size of the zone A of the curves of FIGS. 5 and 6.

It is then understood that when the tensile forces on the geosynthetic are exerted, the wires 71 are immediately stressed (zone A), and the reaction of the wires 72 intervenes only when the elongation of the first wires 71 reaches breaking or exceeds the percentage of waving of the wires 72. Their intervention then results from the breaking of the connecting threads 73 and 74, inducing de facto their "unwinding", that is to say the elongation of the textile when Γ embossing of the threads is resorbs when powering up.

In other words, the "stranding" of the yarns 72 takes place while an extension of the authorized geosynthetic is exerted by deformation of the connecting structure, which consists of yarns 73 and 74 which are themselves of high elongation, and possibly up to break.

If the ripple is programmed for x% elongation, and for example 0.5 to 3%, the son 72 will start to intervene only from this value. Beyond the latter, there is addition of the resistances of the son 71 and 72, and a resultant curve (zone B or B '), whose slope or module will be defined by the characteristics of the son used.

Several types of structure or wire paths 72 are possible. For example, the wires 72 may be connected only to all the "n" rows of meshes so as to introduce only a very small offset. Thus, in FIG. 7B, the binding of the yarns 72b can be modified with a connection on the gillnetting thread only in the four rows allowing a lower filling when this is desired.

Figure 7C also illustrates a different bottom structure variant for bonding. Other types of binding and armor can be envisaged, the common point being always a controlled filling of the fibers ensuring the second level of resistance and deformation

In these three examples of monodirectional geosynthetics, we did not introduce a frame. It may then be necessary to work with four sets of wires, so with four different wire guide bars. FIGS. 8A and 8B show other constructions, in which the wires 82a and 82b evolve with greater amplitude on suitable bonds, for example in the form of two-needle sectional frames with chain, double-knit or other bonds, authorizing precisely this evolution on the one hand, and allowing a certain latitude of displacement of the corrugated son 82a and 82b, during their stress on the other hand.

It will be understood that the path traversed by these wires 82a and 82b is longer than that of the straight wires 81a and 81b and that they respond in a delayed manner with respect to the latter.

The resulting curve (zone A) with a relatively low slope can then have a longer first portion.

In the example of FIG. 8B, transverse frames illustrated in dashed lines have been introduced, offering the possibility of using only three wire guide bars because it is possible in such a case to have only one set of binding threads 83b. Thus, it is possible to produce a geosynthetic in the form of a grid, or to obtain an increased resistance in the weft direction. In addition, this construction is more economical.

In the example of FIG. 8A, variants of binding threads 83a and 84a are illustrated. Moreover, it may be envisaged to confer an additional function on the geosynthetic, in particular of separation and / or filtration of the soil. For this purpose, it is possible to add directly, during the manufacturing step, a nonwoven, a woven fabric or a veil 86. FIG. 8C is another example of construction of the geo synthetic of the invention, in which all the wires or cords are arranged on the same guide line (designated wire guide bar), but with a positive double feed with a different flow rate. This solution is possible when the deviation or phase shift sought between the first part of the curve (zone A) and the second part of the curve (zone B) is relatively small.

Threading the son or cords is then performed with, for example, the repetition of a type 81b wire, then a type 82b wire. To achieve the desired performance, the choice of the nature of the son composing the geosynthetic in question is very precisely adapted to the specific conditions of the work and the site.

For rectilinear yarns 71, 81a, 81b which are involved immediately in the reaction of the material, it is possible to opt for yarns of high strength but having a long elongation curve, that is to say with a high elongation at break. for example of the order of 5 to 20%.

It can be standard polyester or retracted type with high elongation curve), polyamide, polypropylene or high-strength polyethylene but elongation at break of the order of 20%.

Other fibers can be used again, whether synthetic, chemical or natural, depending on the requirements of the book.

For high-modulus wires 72, 72b, 82a, 82b arranged with supercharging or waving, it is a question of using high-strength or high-modulus wires such as HT (high tenacity) polyester, aramid fibers, PVA (polyvinylacetate), glass, carbon, basalt, polyethylene HT (high tenacity), or fibers such as Vectran® (aromatic polyester), etc ...

The choice of these combinations of materials for the two types of yarns is determined by the computed requirements of reinforcement of the structure in terms of short and long term resistance. Chemical compatibility is also taken into account, in particular according to the application environment. For example, polypropylene may be combined in the position of the wires 71, 81a or 81b and an alkaline-insensitive high modulus fiber such as PVA for the wires 72, 72b, 82a or 82b. The binding son can be standard, and typically polyester or polyethylene Indeed, their low resistance allows a fuse effect in phase 1 (zone A) to allow passage to phase 2 (zone B, B ').

The geotextile of the invention may also have a woven structure, and no longer knitted.

Due to the compulsory corrugation around the frames, which are essential for the construction of a woven fabric, the delay effect expected during the pulling of said geosynthetic is available.

Figures 9 and 10 show two embodiments implementing such a woven structure.

These are "Cannelé" type armors in which there are several sets of wires with longer or shorter chain floats.

 Many armor respond to these possibilities of son sets with ripples, generating a differentiation in terms of behavior; In these armor, one generally has a regular bottom with a "taffeta" or plain weave 90 with always a passage once on the frame and once under the frame; this is the case of the son 91 and 101.

In the example of FIGS. 9, wires 92 are then introduced which pass over several frames according to a predefined program and which therefore remain rectilinear for a certain distance in the form of "floats".

When putting the geosynthetic into traction, it is understood that the son 92, which have a low clogging, are immediately solicited, while the son 91 must be "undone" before reacting. This "désondulation" occurs after breakage son 92 or very important extension of these son 92. It was well, playing on the one hand on this armor and on the other hand on the type of wire used (nature and mechanical behavior), a resultant curve with double slope of the type of that of Figure 3.

Figures 10 illustrate another armor, in which we find exactly the same principle but with two sets of different son in addition to the basic taffeta 100, 101.

The threads 101 of the base fabric intervene only when they are "undone"; they are based on the most efficient material in terms of mechanical properties and act on the second part (zone B) of the geosynthetic tensile curve.

The wires 102 and 102 'are stressed immediately when the geosynthetic is subjected to traction, that is to say corresponding to the zone A of the curve of FIG. 5.

If, as shown in FIG. 10A, the threads 102 and 102 'have floats of different lengths, and therefore different embossments, in addition to the different type of materials constituting them, different slopes of the initial tensile curves are obtained. More specifically, a tensile curve with three successive slopes is obtained, as illustrated in FIGS. 6A and 6B.

Figures 9B and 10B are schematic representations of armor for programming on looms.

Claims

Soil strengthening geosynthetic having at least two different elongation zones under tension in at least one direction, respectively:

 A first major elongation zone for a deformation of the geosynthetic between 0% and a limit of between 0.5 and 6% in at least one direction for voltages between 0 and 10 to 400 kN / m corresponding to this deformation limit;

 A second elongation zone, beyond said first elongation zone, characterized by a maximum deformation of between 2 and 20% in at least one direction for voltages of between 100 and 3000 kN / m at least, corresponding to at this maximum deformation,

the differential of the zones of elongation resulting from the nature of the constituent wires of the geosynthetic and / or the structure of said geosynthetic.

Geosynthetic soil reinforcement according to claim 1, characterized in that it consists of a knitted structure made by jetty mesh technology, integrating in chain (production direction) a first series of straight son (71, 81), and one or more series of warp yarns (72, 82) related to any weft yarns (cross-machine direction) or to a possible support material by binding yarns capable of imparting to them an amplitude ripple chosen as a function of the embossing desired and corollary, the importance of the constitutive law, and in particular the limits of the deformation zones that one wishes to confer on said geosynthetic.

Soil strengthening geosynthetic according to claim 2, characterized in that the support material is constituted by a woven, a nonwoven, a knitted structure, a film, a membrane, or even several layers of these materials.

Soil strengthening geosynthetic according to claim 1, characterized in that it consists of a woven structure, constituted by a base with plain weave or taffeta, of satin or fluted type with insertion of son in float form in chain or in weft, that is to say passing over several warp and weft son, the amount of warp or weft son passed determining the behavior of the geosynthetic under the effect of immediate traction.

5. reinforcing geosynthetic according to one of claims 1 to 4, characterized in that the constituent son of the structure are made from high tensile fibers, and preferably selected from the group comprising PET (polyterephthalate) ethylene), polyamide, polypropylene, polyethylene, polyvinyl acetate, aromatic polyester, aramid, carbon, steel, stainless steel, biosourced fibers (polylactic acid, polybutylene succinate (PBS )), or natural fibers (cotton, hemp or linen for example).

6. geosynthetic soil reinforcement according to one of claims 1 to 5, characterized in that it is associated with one or more layers of woven material type, a nonwoven, or a knit capable of providing additional the functions of drainage, filtration, anti-contaminant, miscibility vector, total or partial sealing, anti-pollution treatment. 7. geosynthetic soil reinforcement according to one of claims 1 to 6, characterized in that it incorporates in the textile construction or reported in a subsequent step by gluing or other means of attachment, a method of measuring deformation of fiber optic type Braggs or Brillouin type or equivalent or extensometers.

8. Soil strengthening geosynthetic having at least three different elongation zones under tension in at least one direction, respectively:

 A first major elongation zone for deformation of the geosynthetic between 0.5 and 6% in at least one direction for voltages between 0 and 400 kN / m corresponding to this limiting deformation;

 A second elongation zone, beyond said first elongation zone, characterized by a maximum deformation of between 2 and 20% in at least one direction for voltages between 100 and

3000 kN / m at least, corresponding to this maximum deformation,

 A third zone of elongation, beyond said second elongation zone, in which the modulus of the fibers constituting it is higher or lower than that of the fibers constituting said first and second elongation zones.