RO128934B1 - Method and device for draining off the water seeped into a soil beneath hydraulic structures - Google Patents

Abstract

A method and a device for draining off water seeped in a soil underlying a hydraulic structure (10), such as a canal, basin, dams and the like. A protective and waterproofing covering (13, 14), is laid down on the bottom wall (11) and side walls (12) of the hydraulic structure (10), by providing the covering (13, 14) with one-way gravity drainage valves (17). The waterproof covering (14) along the side walls (12), is anchored by a concrete ballast (18A) within a longitudinal trench (15), and by one or more tiltable concrete slabs (18) overlapping the waterproof covering (14), in which the slab or slabs (18) downwards extend from the anchoring ballast (18A). The water seeped in the soil, having a level higher than that of the water in the hydraulic structure, flows off by gravity towards the one-way valves (17), along an interface between the waterproof geomembrane (14) and the soil, slightly raising the tiltable concrete slab or slabs (18) by pressure of the same water seeped into the soil, having a level greater than the level of the water into the hydraulic structure (10).

Description

The invention relates to a method and a device for draining, by gravity, water infiltrated into a soil under hydraulic structures, such as canals, basins, dams and the like.

They are well known, for example from patent applications US 4913583 A (DIDIER LEDEUIL), 03.04.1990, and US 5720576 A (SIBELON SRL), 24.02.1990, devices intended for impermeable hydraulic structures, comprising a protective shell, consisting of: a geomembrane made of synthetic material, which is fixed by a surface of the hydraulic structure, in order to be in contact with water.

In the aforementioned applications there is a need to drain water infiltrated into the soil under the base and side walls of the hydraulic structure, in order to prevent the infiltrated water pressure from causing the soil to sink or damage the hydraulic structure. To partially overcome this shortcoming, US Patent Application 4913583 A suggests incorporating a waterproofing membrane into the hydraulic structure, providing a number of microperforated pipes for drainage of infiltrated water into the soil. On the other hand, US Patent Application 5720576 A suggests anchoring a waterproofing coating to those surfaces of a hydraulic structure that are directed to and are to come into contact with the water in a basin, using a number of properly configured metal sections. , to allow water infiltrated into the soil to be drained outwards.

Utility model application DE 20 2008 014 492 U1 (HAGN UMWELT GMBH), 26.03.2009, and the corresponding international patent application, WO 2010/028959 A, which are considered to represent the closest state of the art for the present invention. , illustrates a suitable method and device for waterproofing the channels and the like, according to the preamble of claim 1. However, said document proposes the use of a method and a waterproofing device with different characteristics, to solve a problem different from the present invention.

More specifically, the document DE 20 2008 014 492 U1 illustrates the waterproofing of the channels with the aid of the reticular materials, the fixing of the respective reticular materials in a drainage channel located at the level of the upper edge of the side walls, with the help of any common fixing means. In order to protect the lattice materials in extreme climatic conditions, a concrete layer is sprayed onto a ballast bed and a metal mesh; pumping stations are also provided, in connection with wells for lowering the water level, in order to lower the water level in the soil.

International application WO 2007/059924 A (GSI BV), 31.05.2007, proposes the provision of impermeable cover sheets, for a hydraulic structure, having a number of unidirectional drainage valves, and the use of common anchoring means, for fixing the impermeable sheets. , as well as drainage valves.

While these solutions have provided satisfactory results in some applications, the construction of a drainage and waterproofing device is not always possible in the case of existing hydraulic structures or is very difficult and expensive.

The problem to be solved by the present invention is to provide a method and a device for waterproofing and draining water infiltrated into the soil, under a hydraulic structure, such as a channel, a water basin, dams and the like, as an alternative. to known systems of the prior art, to avoid deterioration of the hydraulic structure produced by the same infiltrated water.

It is therefore an object of the present invention to provide a method and a device for draining water infiltrated into the soil, under the base walls and side walls of a hydraulic structure, to solve the problem referred to, and which to present a simple construction, to be less expensive than ordinary systems and to take advantage of

EN 128934 Β1 gravity and pressure of the same water infiltrated into the soil, to allow the infiltrated water to flow from one or more one-way valves, while maintaining the valves in proper operating conditions, so that any sedimentary material can be dredged and removed through the same drainage water stream.

The foregoing have become possible by a method according to the one of claim 1, as well as by a device according to that of claim 2.

According to the invention, a method has been provided for drainage of infiltrated soil, under the side walls and the base wall of a hydraulic structure, a method according to which, over the side walls and from the base, a protective covering is provided which comprises a plurality of sheets. waterproofing, arranged side by side, having the lateral edges superimposed and tightly connected, in which the waterproofing sheets of the side walls are fixed in a longitudinal drainage channel, which extends in parallel with the upper edge of the side walls and in which it is secured a concrete layer, over the respective waterproofing sheets of the side walls, characterized by the steps of:

- stretching of a first set of waterproofing sheets over the base wall of the hydraulic structure;

- the extension of a second set of waterproofing sheets over the side walls of the hydraulic structure, from the respective longitudinal drainage channel;

- providing unidirectional drainage valves, normally closed, by partially overlapping the waterproofing sheets of the side walls over the waterproofing sheets of the base wall;

- anchoring the waterproofing sheets of the side walls, by overlapping a concrete bed in the longitudinal drainage channel and at least one concrete slab, connected with the possibility of tilting and extending from the concrete bed, along the side walls ; and

- the drainage of the infiltrated water from the soil in the hydraulic structure, allowing the leakage of the infiltrated water outside, along the interface between the waterproofing sheets of the side walls and the respective soil, by easy lifting, by tilting, the concrete slab and the opening of unidirectional valves the counter-pressure of the water infiltrated into the soil, which presents a higher level than that of the water from the hydraulic structure.

According to another aspect of the invention, a suitable drainage device has been provided for drainage water infiltrated into the soil under the hydraulic structure having base and side walls, according to the method of claim 1, the device comprising:

- a plurality of waterproofing sheets arranged side by side, spread over the base and side walls, the respective waterproofing sheets having tightly connected and overlapping lateral edges,

- in which the waterproofing sheets of the sidewalls are fixed in a longitudinal drainage channel, which extends in parallel with the upper edge of the sidewalls, and,

- in which a concrete layer is provided, over the waterproofing sheets of the side walls, characterized in that the respective plurality of waterproofing sheets comprises:

- a first set of waterproofing sheets spread on the base wall;

- a second set of waterproofing sheets stretched and extending downstream on the side walls of the longitudinal channel;

- means for retaining the second set of waterproofing sheets in the drainage channel and to the side walls, the respective retaining means comprising a concrete bed in such a drainage channel and at least one concrete slab connected with possibility tilting the concrete bed into the drainage channel;

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- the respective concrete slab, which extends from the concrete bed, over the waterproofing sheets, along the side walls;

- the respective concrete slab, which is connected, with the possibility of tilting, by the concrete bed of the retaining means;

- unidirectional valves, normally closed, in the waterproofing sheets of the side walls and / or the base wall.

These and other features of the drainage method and device according to the invention will be apparent from the description, with reference to the examples in the attached drawings, wherein:

FIG. 1 is a top view of the length of a channel, comprising an impermeable shell and a drainage device according to the first embodiment of the invention;

FIG. 2 is a cross-sectional view taken along line 2-2 of FIG. 1;

FIG. 3 is a cross-sectional view, enlarged, of a first detail taken along line 3-3 of FIG. 1, which illustrates the connection between a concrete bed and a concrete slab;

FIG. 4 is a cross-sectional view, enlarged, of the second detail, taken along line 4-4 of FIG. 1, which refers to the first embodiment of a unidirectional drainage valve for the side walls;

FIG. 5 is a sectional view similar to FIG. 4, which relates to the second embodiment of a closed, unidirectional drain valve for a side wall;

FIG. 6 is a sectional view of the drainage valve of FIG. 5, in the open state;

FIG. 7 is a sectional view similar to that of FIG. 3, which refers to a hinged joint between a concrete bed and a concrete slab;

FIG. 8 is an enlarged sectional view of the second detail taken along line 8-8 of FIG. 1, which refers to the first embodiment of a unidirectional drainage valve for the base wall;

FIG. 9 is a top view of the length of a channel, similar to FIG. 1, comprising a waterproof coating and a drainage device according to another embodiment of the invention;

FIG. 10 is an enlarged cross-sectional view similar to FIG. 8, which relates to the second embodiment of a unidirectional drainage valve for the base wall of the channel of FIG. 1;

FIG. 11 illustrates another type of drainage valve for the base wall of the channel of FIG. 1 and 9;

FIG. 12 is a cross-sectional view taken along line 12-12 of FIG. 11.

Fig. 1 and 2 show, for example, a hydraulic structure 10 provided with a waterproofing protective coating and a unidirectional drainage valve for water infiltrated into the soil below, according to the present invention, wherein the hydraulic structure consists of a water channel having a indefinite length.

As can be seen, the channel at the bottom 10A of the hydraulic structure 10 of FIG. 1 is provided with a waterproofing protective coating and a concrete bed, both on the side walls and on its base wall, as will be explained below, while the concrete bed at the top 10B of the structure hydraulics 10 of fig. 1 was removed.

The hydraulic structure 10 comprises a base wall 11 and some side walls 12, only one of the latter being illustrated in FIG. 2, walls extending in the longitudinal direction of the channel or hydraulic structure 10.

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According to FIG. 1, the hydraulic structure 10 is provided with a waterproofing protective coating, which consists of a geomembrane comprising a plurality of sheets 13, 14 of waterproofing, made of a synthetic material with elastic capacity, for example thermoplastic material, thermoplastic rubber, thermosetting materials, bituminous material or other suitable material, according to the table below.

Type Basic material Abbreviating Thermoplastic material high density polyethylene HDPE low density polyethylene LLDPE chlorinated polyethylene CPE ethylene vinyl acetate copolymer E / VAC polyethylene ON polypropylene PP polyvinyl chloride PVC Types of thermoplastic rubber polyethylene chloro-sulfonate CSPE ethylene-propylene copolymer ES Thermally stable polymers isobutylene poly GDP chloroprene rubber CR ethylene-propylene-diene monomer EPDM butyl rubber HR butadiene-nitrile rubber BR Bituminous products oxidized bitumen Prefabricated GM polymeric bitumen -

The geomembrane consists of a number of impermeable sheets of the desired length, having a thickness between 0.2 and 50 mm, with a module between 10 and 5000 MPas.

Also with reference to FIG. 1, the geomembrane that provides the protective covering for the hydraulic structure 10 comprises a first set of waterproofing sheets 13, arranged side by side, which are longitudinally stretched on the base wall 11, their lateral edges being partially superimposed and connected tightly to each other, by welding or with adhesive. in FIG. 1, the wrapper also comprises a second set of waterproofing sheets 14, arranged side by side, which extend transversely over the side walls 12, in which the lateral edges of the sheets 14 have again been superimposed and connected tightly to each other, in a manner similar to the longitudinal sheets 13 of the base wall 11.

As illustrated in FIG. 1 ... 3 and in the detailed view of fig. 4, each transverse waterproofing sheet 14 extends from the upper edge to the lower edge of the side walls 12, starting from the base of a drainage channel 15, on a top, flat length 16, and along the slope of the side wall 12 , ending with the lower edge 14A, freely overlapping with a lateral edge of the base sheet 13, for example,

RO 128934 Β1 on a length from 10 to 50 cm. A one-way drainage valve 17 is thus provided between partially overlapping sheets 13 and 14, along which the one-way valve 17 extends longitudinally, over a length of several meters, tens of meters, or more. As will be further explained, the one-way valve 17 allows the outlet of water that has seeped into the soil under the respective hydraulic structure 10 and its side walls, for example through the valves 17, when there is a negative pressure difference between the upper and lower parts. , at the level of the edges 14A of the sheets 14 impervious, or in the external environment.

The sheets 14, which define the waterproofing protective coating for the side walls 12, are fixed in the drain channel 15 and are attached along the side walls 12 in the slope of the channel of the hydraulic structure 10, by means of a concrete bed 18A made, for example , from a molded pouring of poured concrete into the drain channel 15, in parallel with the upper edge of the side walls 12 and through at least one flat concrete slab 18, extending downstream from the bed of concrete 18A, as illustrated, ending with the lower edge 18B, at a reduced distance from the unidirectional drain valve 17; In the example illustrated in FIG. 4, the valve 17 appears as being outside and away from the concrete slab 18.

As illustrated in FIG. 2 and 3, the concrete bed 18And the concrete slab 18 are cast into the concrete as a one-piece unit, which extends longitudinally over a certain length. Depending on the shape and size of the hydraulic structure 10, one or more concrete bed units and slabs, arranged side by side, may be provided to retain the waterproofing sheets. The connection between the concrete bed 18A and the slab 18 as well as the thickness of the respective slab 18 should be such as to provide a joint, or a connection configured to allow the slab 18 to be deflected elastic and high, with the possibility of tilting, under the force. shear caused by the pressure of water seeping into the soil.

In order to prevent damage to the waterproofing sheets 14 of the sidewalls, between the concrete slab 18 and the waterproofing sheets 14, a layer of anti-drilling material 19 was arranged, such as lining a textile material suitable for geological applications, as defined normal as "geotextile, material that is capable of withstanding perforations caused by the weight or slight displacements of the concrete slab.

finally, in FIG. 1 and 2, with mark 20, were designated continuous concrete strips which are superimposed with respect to the longitudinal waterproofing sheets 13 of the base wall 11, in order to allow the service vehicles to move and to perform the maintenance operations. .

In the example of FIG. 4, the one-way drain valve 17 consists of the overlapping edges of the longitudinal sheets 13 and the transverse sheets 14; for this purpose, as illustrated in FIG. 4, the edge of the sheet 13 has been anchored, in order to be maintained in a state of adhesion to the ground, by means of any mechanical fixing system, schematically illustrated by the reference 21, while the edge of the sheet 14, superimposed on the aforementioned one, is free both rises to open valve 17 and allows water that has seeped into the ground to flow outward and down, to close valve 17, preventing water in the channel or hydraulic structure 10 from flowing through the same valve 17, in the case of a positive pressure difference that exists between the water in the channel or the hydraulic structure 10 and the water in the ground.

This can also be explained with reference to FIG. 2, wherein a first high level of water in the channel of the hydraulic structure 10 was indicated by L1, while a possible level of water that infiltrated into the soil, lower than L1, was indicated by L2. Under these conditions, it is understood that the valve 17 with unidirectional membrane will remain closed due to the positive pressure difference resulting from the water in the channel of the hydraulic structure 10 being higher than the pressure of the water that has seeped into the soil.

On the other hand, when the water level in the channel has decreased to the level L2, lower than that of the ground water, as indicated by L3, between the two surfaces of the edge 14A of the sheet, or of each sheet 14, a negative pressure difference is generated, due to the fact that the level and pressure of the water in the soil is higher than the level and pressure of the water in the channel, which will cause the valve 17 to open, and the water to flow from the ground into the channel or hydraulic structure. 10.

The water can flow from the ground outside by gravity, along an interface between the respective soil and the waterproof sheets 14, and through the unidirectional valve or the unidirectional valves 17 in the open state, due to a slight bending or lifting of the concrete slab 18 and the edge 14A of the waterproofing sheet 14, produced by the high shear force exerted by the water pressure of the soil, as a result of the prolonged extension of the surfaces in contact with each other at the respective interface.

In the example of FIG. 3 and 4, illustrating the provision of the one-way valve 17 outside and away from the concrete slab 18. Fig. 5 ... 7 illustrates, on the other hand, an example in which the one-way valve 17 is positioned below the lower edge 18B of the concrete slab 18, along the side walls of the channel or hydraulic structure 10. In this sense, in FIG. .5 ... 7 the same marks as in the preceding figures were used to designate similar or equivalent parts.

The difference between the solution in fig. 3 and 4 and the solution of FIG. 5 and 6 not only consist of the different positioning of the one-way valve 17, but also of providing a hinged joint 22 between the slab 18 from the top edge of the side wall 12, and an extension of the concrete bed 18A that protrudes, partially, from one side of the drain channel 15, as illustrated in FIG. 7. The hinged joint 22 acts so that the concrete slab 18, along the wall 12, under the shear force of the water pressure which has soaked the soil, can be tilted in the upward direction and lifted slightly by a few millimeters or less, ensuring a gap, to cause the infiltrated water in the soil to flow outwards, along the existing interface and outward from the one-way valve 17, into the channel or hydraulic structure 10.

for this purpose, as illustrated in the enlarged detail of FIG. 7, the joint 22 may comprise a rubber lining 23 or other synthetic, compressible elastic material, extending through the slab 18 between the opposite edge surfaces of the concrete bed 18A and the slab 18; reinforcing and connecting rods 24, 25 of iron, U-shaped, pivotally engaged relative to each other, are embedded in the concrete of the concrete bed 18A and the tile 18.

Fig. 5 schematically illustrates the closed state of the valve 17, while FIG. 6 illustrates the same valve 17 in the open state.

Fig. 8 illustrates the one-way valve 17 which is substantially similar to that of FIG. 5 and 6, between two sheets 13.1 and 13.2, longitudinal, covering the base wall 11 of the channel, in a position below the concrete strip 20 of fig. 1; in this sense, in FIG. 8, some of the benchmarks used in the previous figures were used to designate similar or equivalent parts.

Fig. 9 illustrates another embodiment of the waterproofing protective coating and the unidirectional valves 17 of the same channel illustrated in FIG. 1; In the example of FIG. 9, the waterproofing sheets 13, which cover the base wall of the channel of the hydraulic structure 10, have been stretched transversely, instead of being stretched longitudinally, in a similar manner to the waterproof walls 14 for the side walls of the channel. otherwise, especially with regard to the one-way drain valves, the two solutions are equivalent; In this respect, the same benchmarks as in fig. 1 and in FIG. 9 to designate similar or equivalent parts.

finally, in FIG. 9, the reference 26 refers to an additional unidirectional valve for the waterproofing sheets of the base wall of the channel, for example, of the type illustrated in fig. 11.

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Fig. 10 illustrates providing an additional drainage valve 17 at one part of the concrete strip 20, similarly to valve 17 in FIG. 4; the solution in FIG. 10 differs from the solution in FIG. 4 in that the free upper edge of sheet 13.1 was welded to the lower sheet 13.2 by means of a superficial welding line 31, which may break. By "superficial welding line" it is understood that the welding cannot withstand the force produced by the pressure of the water of the ground, therefore the welding can break when the pressure of the ground water exceeds a preset value, depending on the level of resistance to variable breaking of the welding 31.

Optionally, at the base wall of the channel or hydraulic structure 10, to replace or in combination with the valves of FIG. 8 and / or 10, the unidirectional drainage valves 26, cavity type, additional, can be provided, one of which is illustrated in fig. 11 and 12.

As shown in FIG. 9 and 11, in predetermined positions of the base wall, in a few sheets 13 of waterproofing, one or more slots 27 or elongated cutouts are provided, and one edge of the cutout is fixed by the ground below or by the base wall of the channel. , by means of a mechanical fastening feather 28, leaving the other edge free to move up and down, under the pressure of ground water.

When the cutout 27 has been made, after an edge thereof has been fixed with a fastening wedge 28, the waterproofing coating membrane 29 is superimposed on it, for example, having a rectangular shape and a size larger than that of the cutout 27. The membrane 29 is then tightly secured along a portion of the peripheral edge, for example along three sides, by means of a strong welding line 30. "Heavy-duty welding" means a welding that can withstand the pressure exerted by the water from below ground; the remainder of the peripheral edge portion, that is, the fourth side, parallel to the cutout 27 in the example in fig. 11 and 12, it is welded by the waterproof sheet 13.2 by means of a superficial welding line 31, as defined above, in FIG. 10.

From what has been said and illustrated in the figures, it should be understood that a method and device were provided to drain, by gravity, the water infiltrated into the soil under the waterproofing shell of any hydraulic structure, in which it was Suggested use of normally closed unidirectional drainage valves, in which the waterproofing sheets of the protective coating are simply retained with the help of a concrete bed in a drainage channel and with the concrete slabs extending in the direction down from the drainage channel, to retain the waterproofing sheets on the side walls and in which the concrete slabs are connected with the possibility of tilting the concrete bed, to allow the respective slab and the waterproofing sheets to be lifted by means of water pressure, in order to allow the drainage of the water infiltrated into the ground by opening the respective unidirectional valves.

However, it should be understood that all that has been said and illustrated is merely to exemplify the general features of the invention, the unidirectional drain valves and the impervious sheets 13 and 14; In fact, alternatively to the transverse stretch of the sheets 14, the latter can extend in a longitudinal direction, parallel to the side walls 12. Therefore, other modifications or variations in the method and device can be made, without departing from the the protection provided by the claims below.

Claims (13)

1. Method for drainage of infiltrated water into a soil under hydraulic structures (10) having side walls (12), a base wall (11) and a longitudinal drainage channel (15), which extends parallel to the edge upper side walls (12), wherein a protective covering comprising a plurality of waterproofing sheets (13, 14) arranged side by side, having the lateral edges superimposed and connected tightly, is extended over the side walls (11, 12) and basic of the hydraulic structure (10) and in which the sheets (14) of the waterproofing of the side walls (12) are fixed in the drainage channel (15) longitudinally and are provided with a concrete layer, characterized in that it is carried out in the following sequence of steps: - a first set of sheets (13) of waterproofing is spread over the base wall (11) of the hydraulic structure (10); - a second set of sheets (14) of waterproofing from the respective drainage channel (15) longitudinally down over the side walls (12) of the hydraulic structure (10); - certain unidirectional main valves (17), normally closed, are provided by partially overlapping the waterproofing sheets (14) of the side walls (12) over the waterproofing sheets (13) of the base wall (11); - the waterproofing sheets (14) of the side walls (12) are anchored by overlapping a concrete bed (18A) in the longitudinal drainage channel (15) and at least one concrete slab (18), connected by tilting possibility, and extending from the concrete bed (18A) along the side walls (12); - the infiltrated water is drained from the soil into the hydraulic structure (10), allowing the infiltrated water to flow outwards, along an interface between the waterproofing sheets (14) of the side walls (12) and the respective soil, by tilting the concrete slab (18) and opening of unidirectional drainage valves (17) by counter-pressure of water infiltrated into the soil, water having a level higher than that of water in the hydraulic structure (10). 2. A device for draining infiltrated water into a soil under hydraulic structures (10), according to the method of claim 1, comprising: - a plurality of waterproofing sheets (13,14), arranged side by side, spread over the walls (11,12) from the base and sides, the respective sheets (13,14) of waterproofing having side edges connected tightly and superimposed; - in which the waterproofing sheets (14) of the side walls (12) are fixed in a longitudinal drainage channel (15), which extends in parallel with the upper edge of the side walls (12) and, - in which a layer of concrete is provided over the waterproofing sheets (14) of the side walls (12); characterized in that said plurality of sheets (13,14) of waterproofing comprises: - a first set of sheets (13) of waterproofing, lying on the base wall (11); - a second set of sheets (14) of waterproofing, extending and extending from the drainage channel (15) longitudinally downwards on the side walls (12); - means for retaining the second set of sheets (14) for waterproofing in the drainage channel (15) and to the side walls (12), the respective retaining means comprising a concrete bed (18A) in the drainage channel (15) ) and at least one concrete slab (18) extending from the concrete bed (18A) over the waterproofing sheets (14), along the side wall (12); RO 128934 Β1 - said concrete slab (18), which is connected with the possibility of tipping over the concrete bed (18A) of the retaining means; - the waterproofing sheets (13,14) of the side walls (12) and / or the base wall (11), provided with some unidirectional main drain valves (17), normally closed. A soil drainage device according to claim 2, characterized in that an articulated joint (22) is provided between the concrete bed (18A) and the concrete slab (18). Drainage device according to claim 3, characterized in that the hinged joint (22) comprises an elastic lining element (23). Drainage device according to claim 2, characterized in that the second set of sheets (14) of waterproofing extends transversely with respect to the side walls (12) of the hydraulic structure (10). Drainage device according to claim 2, characterized in that the first set of sheets (13) of waterproofing extends over the base wall (11), in a parallel direction with respect to the side walls (12). Drainage device according to claim 2, characterized in that the first set of sheets (13) of waterproofing extends over the base wall (11), in a transverse direction relative to the side walls (12). Drainage device according to claim 2, characterized in that the main drainage valve (17) is provided in a position located at a distance relative to an edge of the concrete slab (18). Drainage device according to claim 2, characterized in that the main drainage valve (17) is provided under one edge of the concrete slab (18). A drainage device according to claim 2, characterized in that it further comprises additional unidirectional drainage valves (17) in the impermeable sheets (13) of the base wall (11). Drainage device according to claim 10, characterized in that the additional drainage valves (17) extend longitudinally to at least one side edge of a concrete strip (20) that overlaps the foil (13) of the base wall waterproofing. (11). Drainage device according to claim 11, characterized in that said additional drainage valves (17) comprise the overlapping edges of the impermeable sheets (13) of the base wall (11), sealed by means of a welding line. (31) shallow, to be broken at a predetermined value of the water infiltrated into the soil. Drainage device according to claim 10, characterized in that said additional drainage valves (17) comprise cavity valves (26), each consisting of a slot (27) in the waterproof sheet (13) of the wall. base (11), a waterproof membrane (29) being extended to the slot (27); a portion of the peripheral edge of the waterproofing membrane (29) being sealed by the waterproof sheet (13) below, through a resistant welding line (30), to withstand the pressure of water seeping into the soil; the remainder of the peripheral edge portion of the waterproofing membrane (29) being sealed securely by the bottom waterproofing sheet (13), via another surface welding line (31), to yield a preset value of the water pressure infiltrated into ground.