FR2582694A1 - Method for horizontally and statically increasing the density of ground for foundations - Google Patents

Abstract

The invention relates to a method for increasing the density of ground layers, of the type in which a mortar is injected into the ground from a variety of boreholes 1, 2, 3. A first series of injections is carried out with a very viscous mortar having a very high internal angle of friction, using boreholes 1 arranged in a first grid, the mortar being injected in a ground layer at a depth between approximately 2 and 30 metres, a second series of injections is then carried out with the same type of mortar in boreholes 2 arranged in a second grid placed at the centre of the cells of the first grid, the injections being carried out in such a way that the total volume of mortar injected into the ground during the implementation of the method is less than 7% of the total volume of the ground in the case of a ground consisting of sands, less than approximately 5% of the total volume of the ground in the case of a ground consisting of silts and less than approximately 3% of the total volume of the ground in the case of a ground containing approximately 10% of bentonite.

Description

 The present invention relates to a method of densification of loose soil foundations which can be implemented above or below the water table, on a layer of a given thickness, at any depth.

 Various soil densification methods are already known which make it possible to confer on them higher mechanical characteristics and in particular to reduce the total and differential settlements in the long term.

 These methods involve using different means to reduce the interstitial volume that exists between the various solids constituting the soil and which is often filled with water.

 In particular, processes are known which involve injecting into the soil fluid compositions such as cement grouts or silica gels which penetrate under pressure in the interstices of the soil and which after hardening, increase the compactness of the soil.

 The methods of injecting into the soil such compositions are difficult to implement when it is a densification itself because it is very difficult to control the quantities of injected products that are just necessary and sufficient, which leads either to an insufficient consolidation of the soil, or to an excessive use of injection fluid which makes the process uneconomical.

 It has also been proposed to carry out, from boreholes, the injection into the ground of viscous mortars so as to form a continuous column having a relatively well-defined interface with the treated soil which is thus pushed radially and compacted between the different columns.

 However, the implementation of this method has not given the desired results because of the uncertainty in which it is to determine when it is useful to stop the injection of the mortar.

 Very empirically, it is generally considered that the injection of the mortar must continue, for example, until the cover layer, in particular the surface of the ground, begins to rise or until it is found that Mortar leakage occurs outwardly between the ground and the drill pipe.

 It is also considered that the injection of the mortar must be interrupted when it is observed during the implementation of the process a precipitation or decomposition of the mortar.

 It has been shown to the experiment that the observation of these criteria does not allow a fast and reliable implementation of this process.

 The present invention relates to an improvement of the process in question which makes it possible to obtain maximum densification of the soil while using a limited quantity of mortar, the majority of the masses of soil not being subjected to plasticization.

 The subject of the present invention is a method for performing the densification of soils, of the type in which a mortar is injected into the soil from multiple boreholes, characterized in that a first series of injections of a high viscosity and very high internal friction mortar made from drillings made in a first mesh, the injection of the mortar taking place in a layer of a given thickness at a depth of between approximately 2 and 30 meters, then that we proceed to a second series of injections of the same type of mortar in drillings made according to a second mesh disposed in the center of the meshes of the first mesh, the injection being conducted so that the volume of the mortar injected into the soil during the implementation of the process is less than approximately 7% of the total volume of the soil in the case of lands constituted by sands, less than approximately 5% of the total volume soil in the case of soils consisting of silts and less than about 3% of the total soil volume in the case of soil containing approximately 10% colloidal clay.

 In a variant of the process according to the invention, it is possible to carry out more than two series of injection which are each carried out in drillings made in the center of the preceding meshes.

 According to the invention, the total amount of mortar to be injected into the soil is preferably distributed substantially equally between the different meshes.

 the present invention is applicable to soils consisting of coarse powder materials whose dimensions of the largest elements do not exceed 100 mm, insofar as the size of the solid elements is not uniform. When the size of the largest elements does not exceed 5 cm the process according to the invention can be applied to all types of powdery materials.

 The process according to the invention is applicable to sandy and loamy soils as well as certain clay soils.

 The method according to the invention applies to embankments of various origins (such as excavation excavation, even consisting of clay blocks, rubble and industrial or municipal landfills).

 The lands likely to benefit from the process according to the invention may be either unsaturated with water or may be situated below the water table.

 Consolidated land according to the invention should generally be more than 2 meters below the ground surface at the time the process is carried out. However, in the case where it is necessary to densify the soil in the vicinity of the surface thereof, it is possible to implement during the implementation of the method an overload of materials which is then removed.

 In the current state of the injected mortar techniques, the depths of treatment are limited to about thirty meters but these depths could be increased by an improvement of the pumping techniques.

 The mortar that can be used according to the invention may consist, for example, of a fine sand aggregate having a particle size of 100% less than 2 cm and 25% smaller than 0.1 cm, which may require the addition of a and 10 to 15% by weight of cement or other binder with a cement / water ratio of between about 0.15 and 0.30%.

 For such mortars, Abrahams cone collapse is about 3 to 4 cm.

 To implement the method, drilling is performed to form the first mesh with meshes of about 5 to 7 m side.

 These holes are preferably small diameters, for example 50 to 100 mm in diameter.

 The distance between the boreholes used for the last series of injection is chosen so that the volumes of plasticized soil are limited to an acceptable minimum.

 the injection is made successively in the various drillings in passes of 1 to 2 meters in height, the casing being reassembled after each pass of an equivalent height.

 Alternatively, one can also perform the injection by raising the tube in a virtually continuous manner.

 In the case where it implements the method according to the invention in clay soils, it may be advantageous to place in the centers of what will be the final mesh, vertical drains that quickly dissipate the interstitial overpressure when it manifests.

 To perform the injection, a mortar pump can be used to inject with pressures up to 8 MPa (80 kg / cm2) but with a low flow that can go down to less than 3 liters / minute.

 By operating in this way, a continuous mortar roll is produced in the soil around the borehole having a regular surface and a clear boundary with the treated soil.

 According to the invention, the mortar must not infiltrate into the mass of the soil by filiform channels or preferred cleavage surfaces.

 The densification effects obtained by the method according to the invention can be controlled by performing in situ in the center of certain meshes geotechnical tests, such as standard penetration tests, as well as penetrometer or pressuremeter tests.

Other advantages and features of the invention will now be demonstrated by the following description with reference to the accompanying drawing in which
FIG. 1 is a plane representing the positions of three successive meshes for the implementation of an embodiment of the method.

 Figure 2 is a schematic sectional view showing the implementation of an injection according to the invention.

 FIG. 1 shows the positions of the holes corresponding to the first grid which have been represented by circles 1, whereas the holes of the second grid which have been represented by triangles 2 are at the center of the meshes formed by the drillings 1 .

 In the embodiment shown, a third grid has been made, the holes of which are represented by crosses 3 and which lie in the center of the meshes formed by the set of wells 1 and 2.

 We see in these conditions how the densified ground is subjected successively to. deviative stress fields produced by the injection of mortar into the boreholes.

 By the implementation of the invention using numerous wells distributed in several passes, with very small quantities of mortar, the maximum number of masses of soils free from plasticization, that is to say having been solicited only by pseudoelastic shear deformations. This effectively contributes to a maximum increase in the mechanical characteristics of the so treated soils including their shear modulus.

 FIG. 2 is a schematic representation of a sectional view of a soil being treated according to the invention.

 FIG. 2 schematically shows a tube 4 waiting for the injection process. This tube 4 passes through the superficial soil layer 5 which can not be treated in accordance with the invention as well as the soil layer 6 which is to undergo densification.

 The tube 4 can be placed in a borehole 7 previously made.

 In a variant, the tube 4 can also be used for drilling.

 The concrete is injected at 8 at the base of the tube 4 using a mortar pump 9, the tube being raised upwards gradually or stepwise, so as to treat the entire thickness of the layer 6 which must to be densified.

 We will now describe three non-limiting examples of implementation of the invention for different types of soil.

Example 1: Densification of sandy soils
It is generally sought to give such soils a working rate qaz 300 KPa (KiloPascals).

 the table below gives the proportion of Z9V / VZ mortar that must be injected in relation to the volume of the soil to be treated.

 q ci indicates in NPa (megaPascals) the penetrometer point resistance of the sandy soil layer that it is desired to treat and for which this resistance obtained after the implementation of the method according to the invention is at least 10 MPa .

E represents the modulus of deformation measured with the pressuremeter
normal pi (i.e., non-self-dreating) also expressed in MPa. the modulus of deformation measured under these same conditions after the implementation of the process according to the invention is also greater than 10 MPa.

<Tb>

<SEP> 9.1 <SEP> (MPa) <SEP> E <SEP> (MPa) <SEP> av / v <SEP> x
<tb><SEP> Pi
<tb> I
<tb><SEP> 3 <SEP> 3 <SEP> 7
<tb><SEP> 7 <SEP> 7 <SEP> 3
<tb><SEP> 9 <SEP> 9 <SEP> 1
<Tb>
It can be seen that, for the implementation of the method according to the invention, a volume of mortar is injected into the soil layer, which is all the greater as the peak resistance to the penetrometer and the modulus of deformation of the initial ground are lower. .

 Of course, the volumes of mortar to be injected are not defined rigorously and they can deviate by about 10% from the values indicated in the table above.

Example 2: Densification of soils formed by silts
In the case of layers of silty soil, the process according to the invention makes it possible to obtain a densification such that the working rate qa can reach the value of approximately 200 KPa.

 A table similar to that of the preceding example is reproduced below, with the difference that in the case of silty soil, the measurement of the penetrometer resistance to the penetrometer can be distorted by the appearance of interstitial overpressure under the tip of the penetrometer.

 This is the reason why the notion of penetrometer resistance to the penetrometer qc has been replaced by that of the limit pressure P1 which is measured with the pressuremeter in a conventional manner.

In the table below fold is the initial value of the
the limiting pressure in the ground to be densified in accordance with the invention.

By implementing the process according to the invention by injection in silty soils with a proportion of Av / V Z mortar indicated in the table below, it is possible to obtain final deformation moduli of approximately 6 MPa and pressures final limits of approximately 600 KPa.

<Tb>

Epj <SEP> (NPa) <SEP> Fold <SEP> (kPa) <SEP> i <SEP> v / v <SEP> Z <SEP>
<tb><SEP> 2.5 <SEP> 250 <SEP> 5
<tb><SEP> 3 <SEP> 300 <SEP> 3
<tb><SEP> 5 <SEP> 500 <SEP> 1
<tb> Example 3: Soils containing 10% clay with a plasticity index of less than 10.

 In such soils it is possible according to the process according to the invention to achieve densification of working rates of about 100 kPa.

The proportions of injection mortar iEV / VZ are shown in the table below.

<Tb>

Epi <SEP> (NPa) <SEP> Fold <SEP> (lova) <SEP> n <SEP><SEP> v / v <SEP> Z
<tb><SEP> t
<tb> 1.8 <SEP> 180 <SEP> 3
<tb> 2 <SEP> 200 <SEP> 1.5
<Tb>
The process according to the invention makes it possible to obtain, in such soils containing 10% of clay, a final deformation modulus of the order of 3 MPa and a final limit pressure of approximately 300 kPa.

 Note that, according to the invention, it is possible to increase the mechanical characteristics of soils by a coefficient of 3.3 in the case of sandy soils, by a coefficient of about 2.4 in the case of soils formed. by silts and a coefficient of about 1.6 in the case of clay soils.

 It can be seen that the process according to the invention which has just been described makes it possible in a simple, efficient and economical way, by injecting a controlled volume of cement mortar, to achieve a significant and reliable improvement of the mechanical characteristics of the grounds.

 Of course, by injecting volumes of mortar smaller than those indicated above, it is possible to obtain in this way, in accordance with the invention, a lesser improvement in the initial mechanical characteristics, but the recommended values make it possible to reduce the settlement to a minimum. long-term soil so treated, provided that the threshold of self-support of the soil is exceeded.

Claims (8)

 1 - Process for densifying soil layers, of the type in which a mortar is injected into the soil from multiple boreholes (1,2,3), characterized in that a first series of injection of a very viscous mortar and very high internal friction angle, made from boreholes (1) made according to a first mesh, the injection of the mortar taking place in a layer of soil at a depth (6) between 2 and 30 meters approximately, then that one proceeds to a second series of injections of the same type of mortar in boreholes (2) made according to a second mesh arranged in the center of the meshes of the first mesh, the injections being led so that the total volume of mortar injected into the soil during the implementation of the process is less than 7% of the total volume of the soil in the case of soils consisting of sands, less than about 5% of the volume total soil in the soil consisting of silts and less than about 3% of the total soil volume in soils containing about 10% colloidal clay.  2 - Process according to claim 1, characterized in that the injection of the volume of mortar is carried out according to more than two series of injection made in drillings made in more than two meshes, each mesh being located in the center of meshes formed by the previous meshes.  3 - Process according to any one of the preceding claims, characterized in that the total amount of mortar to be injected into the soil is distributed substantially equally between the various drillings.  4 - Process according to any one of the preceding claims, characterized in that the injected mortar is constituted by 10 A 15 Z by weight of cement or other binder with a water / cement ratio between about 0.15 and 0.30 Z and an aggregate of fine sand having a particle size of 100 Z less than 2 cm and Z less than 0.1 cm.  5 - Process according to claim 4, characterized in that the subsidence of the Abrahams cone of the mortar used is between about 3 and 4 cm.  6 - Process according to any one of the preceding claims characterized in that the holes (1) made to form the first mesh are meshes of about 5 to 7 meters side.  7 - Process according to any one of the preceding claims characterized in that the drilling (1, 2, 3) have a diameter of between about 50 and 100 mm.  8 - Process according to any one of the preceding claims, characterized in that during its implementation in a clay soil, it comprises the establishment of vertical drains located in the center of the final mesh to quickly dissipate the interstitial overpressure of the layer being processed.