RU2791743C2 - Geocomposite and its production method - Google Patents

Abstract

FIELD: composite materials.

SUBSTANCE: invention relates to geocomposite, which is suitable for strengthening and/or drainage of the soil and to its production method. Geocomposite consists of a set of layers including at least first geotextile canvas (12) and at least second geotextile canvas (14), which are thermally fixed with attachment to sides of intermediate separating layer (16), which is obtained using at least one geomat of twisted plastic threads, having a thickness from about 4 to 5 mm or more. At least one of first geotextile canvas and second geotextile canvas (12, 14) is water-repellent non-woven textile material. This geocomposite can be used as a base to form complex geocomposite, in which, on at least one of canvas (12, 14) of basic geocomposite (10), at least one additional geosynthetic layer (19, 42, 44) is thermally fixed, selected from a group including geogrids, geonets, geomats, geotextiles, geomembranes, or a combination or layering thereof.

EFFECT: invention provides creation of geocomposite, which reduces a risk of efficiency loss as a result of impact of localized high pressures, and which, thereby, provides suitable shock absorption, which is effective, suitable, and reliable in use, while being simple and economical in manufacture, as well as provides creation of a method for the production of geocomposites, which is technologically flexible, and which can be effectively used for formation of different geocomposites, which have required mechanical properties and filtration characteristics.

8 cl, 6 dwg

Description

The field of technology to which the invention belongs

The present invention relates to a geocomposite. The invention has been developed in particular in connection with a geocomposite which is composed of multiple layers and which is suitable for soil reinforcement and/or drainage. The invention also relates to a method for producing such a geocomposite.

State of the art

Known drainage geocomposites, which are composed of layers of different materials. Typically, these drainage geocomposites consist of two webs of geotextiles, such as nonwoven textiles, which are bonded to an intermediate release layer. The separating layer is usually a permeable material such as a geomat, geogrid or geogrid. A geomat that is suitable for this application is, for example, known from patent document EP1160367 (to Greenvision Ambiente SpA), and is composed of a collection of extruded plastic filaments that are entangled and welded together in a hot-forming process to form a thin mattress with low density, that is, with a high coefficient of porosity.

A specific type of drainage geocomposite is known as Terram Frost Blanket and is manufactured by TERRAM. This geocomposite is formed by two layers of non-woven textile material, which are separated by an extruded plastic geogrid. The bottom layer of non-woven textile is made of a water-repellent type material to prevent or limit the penetration of moisture from the ground into the geocomposite. This geocomposite is specifically designed to reduce damage to, for example, the pavement resulting from freeze/thaw cycles of the ground beneath the pavement. The purpose of this geocomposite is to limit the penetration of moisture by capillary forces from the soil under the geocomposite into the upper region of the soil or pavement.

Known types of geocomposites are effective and currently suitable for many applications, but have some inherent limits of applicability that in some cases preclude or prevent their use. When the intermediate separating layer is made of a geogrid, as in the case of the aforementioned "Terram Frost Blanket", there is a risk that a pressure higher than that intended for the geocomposite, applied, for example, in a local area, may bring two webs of geotextile into contact with each other. the other through holes in the geogrid. This leads to the disappearance of the insulating/draining action of the geocomposite in this zone, which thereby ceases to fulfill its function. Therefore, in order to overcome this disadvantage, the use of relatively rigid geotextile webs is required, which can withstand localized deflection under high pressure, which naturally increases the cost of the webs themselves and thus the geocomposite in which they are used.

Another limitation of prior art geocomposites is their limited thickness, which does not make them soft enough for use, for example, as an underlay for sports fields, to provide a proper impact absorption effect from the steps of athletes ("shock absorption"), therefore unsuccessful in providing prevention injuries to the joints of athletes.

The essence of the invention

The object of the invention is to provide a geocomposite which overcomes the disadvantages of the prior art, and in particular which reduces the risk of inefficiency due to localized high pressures and which thereby provides adequate shock absorption ("bump damping"). Yet another object of the invention is to provide a geocomposite which is simple and economical to manufacture and which is efficient, convenient and reliable to use. Yet another object of the invention is to provide a method for producing geocomposites that is technologically flexible and that can be effectively used to form various geocomposites that have desirable mechanical and filtration properties.

To achieve the above objects, the invention relates to a geocomposite and to a method that is suitable for its production, having the characteristics indicated in the paragraphs of the attached claims.

According to one particular aspect of the invention, a base geocomposite is provided that is useful for soil reinforcement and/or drainage. The base geocomposite can be composed of multiple layers of geosynthetics. The base geocomposite may include at least two layers of geotextile, preferably non-woven textile, which are separated by a three-dimensional geomat. The geomat may be of the mattress type which is made of extruded threads of plastic material which are intertwined after being extruded so as to form a structure having a given thickness and having a very low density and irregular pores therein. More specifically, a geocomposite is provided that may include at least a first geotextile and at least a second geotextile that may be thermally bonded to the sides of an intermediate release layer. The intermediate separating layer may be formed by at least one geomat of interlaced plastic threads. The geomat may have a thickness of about 4 to 5 mm or more.

According to one particular aspect of the invention, the geotextile webs are relatively flexible and comprised of entangled filaments and, where applicable, heat-set during the manufacturing process. In one embodiment, at least one of the geotextile webs may be water-repellent, that is, may have pores of a size that is small enough to keep out moisture that could enter the web by capillary action.

According to another aspect of the invention, the base geocomposite can be used to form a geocomposite having a multiple structure. In a multiple geocomposite, at least one of the webs of the base geocomposite may be heat-set with at least one additional layer of geosynthetics. The at least one additional geosynthetic layer may be selected from the group consisting of geogrids, geogrids, geomats, geotextiles, geomembranes, or a combination or overlay thereof.

In one particular aspect, the geocomposite may include a geomat and/or a geogrid that is bonded to one or both of the underlying geotextile webs. A structure of this type has - in addition to the desirable ground drainage characteristics - a good ability to absorb shocks, which makes it particularly advantageous, for example, in the construction of running tracks or sports fields and the like. The presence of the intermediate geotextile in the laminate creates a planar reinforcement which, by absorbing shocks due to its own tensile strength, transfers less stress to the underlying geomat layer, thereby increasing fracture resistance. If the geocomposite has a geomat and a geogrid that are connected to each other, for example by hot heat setting, it becomes particularly resistant to its thickness without reducing its drainage capacity. This makes it suitable for use, for example, in places where localized pressures applied to the geocomposite become high, for example, for use in garbage storage areas.

If the geocomposite has an additional layer, which is made of a geomat, then a specific aspect of the invention is proposed, according to which an impermeable geomembrane is applied, preferably by heat sealing, to it.

In the process for producing a geocomposite of the above type, a base type geocomposite is first produced with a geomat as a separating element between two geotextile layers, preferably in the form of a non-woven textile layer. The production is carried out by obtaining a geomat according to the methods known in the technology. The geomat is then passed through a pair of rollers which pull two layers of geotextile which are unwound from respective rolls. Applying heat, for example by means of localized heaters, or by heating the rolls themselves, results in a localized softening of the geomat strands to which the two geotextiles are thermally bonded adhesively on both sides. The base geocomposite obtained in this way is cooled and wound into rolls for further processing to produce the multilayer geocomposite variants mentioned above. In particular, the base geocomposite can be unwound from a roll and guided by one or more rollers under the geomat and/or geogrid under local heat supply to heat seal the geomat and/or geogrid with one of the geotextiles of the base geocomposite. Local heat supply can also lead to thermal welding of the geomat and geogrid with each other, as well as with the geotextile of the base geocomposite in a continuous process.

Alternatively, the geogrid and geomat may be heat-sealed upstream of their heat-seal with the geotextile of the base geocomposite, to which they are thereby heat-sealed or bonded with adhesives.

In one embodiment, the base geotextile, which is unwound from a roll, is fed under the geomat and geomembrane. In this case, the local heat supply also ensures thermal welding of the geomat and geomembrane with the base geocomposite.

In a geocomposite plant, both the temperature and the pressure applied to heat seal the various layers to each other are controlled to ensure that they are appropriate for fixing the layers to each other without exceeding values that densify the geocomposite and, in in particular the geomat(s) to such an extent that the drainage effect of the geocomposite is impaired.

Brief description of the drawings

Other advantages and characteristics will become apparent from the following detailed description of the preferred embodiment, which is presented with reference to the accompanying drawings, which are given by way of non-limiting example only, and in which:

- Figure 1 is a schematic isometric view of one example of a basic geocomposite incorporating aspects of the present invention,

- Figure 2 is a schematic view of the installation for obtaining the base geocomposite from Figure 1,

- Figure 3 is a schematic isometric view of the first example of a multilayer geocomposite based on the base geocomposite of Figure 1,

- Figure 4 is a schematic view of the installation for obtaining a multilayer geocomposite from Figure 3,

- Figure 5 is a schematic isometric view of the second example of a multilayer geocomposite based on the base geocomposite of Figure 1, and

- Figure 6 is a schematic view of the installation for obtaining a multilayer geocomposite from Figure 5.

Detailed description of the invention

Now with reference to Figure 1, the base geocomposite 10 includes a backsheet 12 of a geotextile, preferably, but not limited to, a nonwoven textile such as polypropylene. In addition, the base geocomposite 10 includes a geotextile topsheet 14, which is preferably, but not limited to, a non-woven textile material, such as polypropylene. The bottom web 12 and the top web 14 may be the same or different from each other. In particular, for applications in which it is beneficial or necessary to provide ice protection, the backsheet 12 may be of the water-repellent type, particularly with a pore size that is small enough to prevent moisture from penetrating through the backsheet 12 by capillary action. . The bottom web 12 and the top web 14 are bonded to both sides of an intermediate separating layer 16 which is preferably formed from a geomat. As is known in the art, a geomat is a layer of material that is formed by entangled strands of plastic material that are welded together to form a structure having a given thickness and having a very low density and irregular pores therein. The intermediate release layer 16 preferably has a thickness of approximately 4 to 5 mm or more, so as to prevent any contact, even accidental, between the lower web 12 and the upper web 14, for example, due to localized pressure or collapse of the base geocomposite 10, at the same time remaining active.

The base geocomposite 10 is produced in a plant and process of a commonly known type, as shown schematically in Figure 2. Hot filaments 23 of plastic material, such as polypropylene, polyethylene, polyamide, polyester, or a mixture of such polymers, are output from the extruder 21, and, where applicable, with a part that is also of natural origin. Under the extruder 21 is placed a cooling tank 22 which contains a coolant to cool the hot filaments 23 which, being supported by the roller 24, are intertwined with each other to form a three-dimensional material structure. The extrusion speed of the hot strands 23 and the rotation speed of the roll 24 are controlled and synchronized to produce a geomat 16 having a predetermined thickness, preferably about 4 to 5 mm or more. The geomat 16 is then passed through a pair of rollers, a lower roller 29 and an upper roller 31, which preferably compress it slightly. One of the two webs that form the base geocomposite 10 is pulled over the top roll 31, for example the top web 14, which is fed from the first roll 26. The other of the two webs is pulled over the bottom roll 29, for example the bottom web 12, which is fed from the second roll 27. When passing between the lower roller 29 and the upper roller 31, the geomat 16 and the lower web 12 and the upper web 14 are locally heated in order to heat seal them. Localized heating may be carried out by heating the lowermost roller 29 and the upper roller 31, or by a separate heater such as burners 30, or emitters, or other functionally similar devices.

In an embodiment that is not illustrated, the top web 12 and the bottom web 14 are passed over both the bottom roll 29 and the top roll 31, respectively, while the roll 24 is configured to form a single geomat that will form the separating material 16 of the base geocomposite 10 The base geocomposite 10 described above can be advantageously used to produce multilayer geocomposites. For this purpose, the base geocomposite 10 can be sent to subsequent processing steps either in the same facility or elsewhere. In the first case, downstream of the base geocomposite 10 production plant, additional process stations are provided that are synchronized with the base geocomposite 10 production plant. as shown schematically in Figure 2, which can subsequently be used to obtain multilayer geocomposites.

This latter mode of application provides considerable technological flexibility, making it possible to obtain the base geocomposite 10 both for use only as a conventional drainage geocomposite, and for use as a base material to obtain more complex geocomposites, which are required from time to time for specific needs, in quantities required at this time.

Now with reference to Figure 3, a first example of a complex geocomposite 20 is given, which includes a base geocomposite 10, which consists of two geotextile webs 12, a bottom web 12 and a top web 14, which are welded with an intermediate separating layer 16, which is obtained, for example, from a geomat , as shown above, preferably having a thickness of 4 to 5 mm or more. In the heat-sealed state, on the top sheet 14, on the side opposite the intermediate separating layer 16, a second intermediate separating layer 19 is placed, which is also obtained, for example, from a geomat, also preferably having a thickness of 4 to 5 mm or more. In a heat-sealed state, on the second intermediate separating layer 19, an outer web 25 of geotextile is placed, which preferably, but without limitation, is a non-woven textile material, for example, from polypropylene, or one of the materials indicated above with reference to the lower web 12 and the upper web. 14. The outer web 25 may be of a type that is identical to the lower web 12 and/or the upper web 14, or a type that is different from both of the lower web 12 and the upper web 14. According to a particular embodiment, the outer web 25 may also be impermeable or water-repellent geosynthetics.

Described above and illustrated as an example in Figure 3, the multilayer geocomposite 20 can be obtained in the installation and method that are schematically shown in Figure 4. The installation has similarities with the installation schematically described in Figure 2 for obtaining the base geocomposite 10. From the extruder 21' output hot strands 23' of a plastic material, for example polypropylene, polyethylene, polyamide, polyester, or mixtures of such polymers, and, where applicable, with a part that is also of natural origin. Below the extruder 21' is placed a cooling tank 22' which contains a coolant to cool the hot filaments 23' which, being supported by the roll 24', intertwine with each other to form a three-dimensional material structure. The extrusion speed of the hot strands 23' and the rotational speed of the roll 24' are controlled and synchronized to produce a separation geomat 19 having a predetermined thickness, preferably about 4 to 5 mm or more. The separating geomat 19 is then passed through a pair of two rollers, a lower roller 29' and an upper roller 31', which preferably compress it slightly. The base geocomposite 10, which is unwound from the base roll 32, is passed along the bottom roller 29'.

The geotextile 25, which is unwound from the corresponding roll 26', is passed over the top roller 31'.

During the passage between the lower roller 29' and the upper roller 31', the base geocomposite 10 is welded to the separating geomat 19 and connected to the outer web 25 to form a multilayer geocomposite 20, which is wound on a precast roll 35. The geomat 19 and the base geocomposite 10 are locally heated, to heat them up. Localized heating may be carried out by heating the lowermost roller 29' and the upper roller 31', or by a separate heater such as burners 30', or emitters, or other functionally similar devices.

With reference to Figure 5, a second example of a composite geocomposite 40 will now be described which includes the base geocomposite 10 as described above and which consists of two geotextile webs 12, a bottom web 12 and a top web 14, which are welded to an intermediate separating layer 16, which is obtained, for example, from a geomat, as shown above, preferably having a thickness of 4 to 5 mm or more. On the side opposite the intermediate separating layer 16, bonded to the top web 14 is a geomat 42 which is reinforced with a geogrid 44, for example of the type consisting of ribbons of plastic filaments that are heat-sealed together in a warp and weft shape, as shown above with reference to the complex geocomposite 20 in Figure 3. Geogrid 44 is mixed with and/or placed between intertwined plastic filaments that form geomat 42 during the extrusion process.

Described above and illustrated by way of example in Figure 5, the multilayer geocomposite 40 can be produced in the plant and method schematically illustrated in Figure 6.

From the extruder 21″, hot filaments 23″ of plastic material, such as polypropylene, polyethylene, polyamide, polyester, or a mixture of such polymers, and, where applicable, with a part that is also of natural origin, are output. Below the extruder 21'' is placed a cooling tank 22'' which contains a coolant to cool the hot filaments 23'' which, supported by a 24'' roller, intertwine with each other to form a three-dimensional material structure. Next, a geogrid 44 is passed along the roller 24'', which is unwound from the roll 26'', and which is passed through the tensioner 28'', which occupies a position in which the position of the geogrid 44 is influenced, more or less centered relative to the center of the geomat 42, which is formed from filaments 23'' which are welded together and also to the geogrid 44. The extrusion speed of the hot filaments 23'' and the rotational speed of the roller 24'' are controlled and synchronized in order to obtain a geomat 42 having a predetermined thickness, preferably from about 4 up to 5 mm or more. The separation geomat 42, which is reinforced with a geogrid 44, is then passed through a pair of rollers, a lower roller 29'' and an upper roller 31'', to be connected to the base geocomposite 10 in a manner similar to that described above with reference to Figure 4, which may be referred to. .

Of course, other variants of complex geocomposites based on the base geocomposite 10 can be provided, using any combination of one or more of the geogrids, geogrids, geomats, geotextiles and/or geomembranes that are layered on one of the two sides or on both sides of the base geocomposite 10, according to principles of formation that will be apparent to a person skilled in the art upon reading this specification and from the accompanying Figures. The intermediate separating layer 16 may also include one or more geogrids or geogrids of material and/or one or more metal reinforcing meshes that are fixed or embedded or woven into intertwined plastic filaments that constitute the geomat of the intermediate separating layer 16.

Of course, while the principles of the invention remain the same, the forms of the embodiments and details of construction may vary widely from what is described and illustrated without thereby departing from the scope of the present invention.

Claims (8)

1. A geocomposite suitable for reinforcing and/or draining soil, containing a plurality of layers, including at least a first web (12) of geotextile material and at least a second web (14) of geotextile material, which are thermally fixed to the respective sides of the intermediate separating layer (16 ) obtained using at least one geomat of interlaced plastic filaments having a thickness of approximately 4 to 5 mm or more to form a base geocomposite (10), in which at least one of the first web (12) and the second web (14 ) of geotextile is a water-repellent non-woven textile material. 2. Geocomposite according to claim 1, in which there is at least one additional layer (19, 42, 44) of geosynthetics selected from the group including geogrids, geogrids, geomats, geotextiles, geomembranes or their combination or layering, which is heat-fixed to the at least one of the first web (12) and the second web (14) of the base geocomposite (10). 3. Geocomposite according to claim 2, in which at least one additional layer includes at least one layer obtained using a geogrid (44) and / or geomat (42), which (s) are heat-set (s) to one from two geotextile fabrics (12, 14) of the base geocomposite (10). 4. The geocomposite according to claim 2, in which at least one additional layer includes at least one geomat (42), which is reinforced with a geogrid (44), moreover, the plastic threads of the geomat (42) are intertwined with the geogrid (44), and the geomat ( 42), which is reinforced with a geogrid (44), is heat-fixed to one of the two geotextile sheets (12, 14) of the base geocomposite (10). 5. Geocomposite according to claim 2, in which at least one additional layer includes at least one geomat (19), which is heat-set to one (12) of the two geotextile webs (12, 14), and the outer web (25) is heat-set to the geomat (19) on the side opposite to one (12) of the two geotextile sheets (12, 14). 6. Geocomposite according to claim 5, wherein the outer web (25) is a geomembrane. 7. The method of obtaining a geocomposite according to any one of paragraphs. 1-6, which includes the step of obtaining a base geocomposite (10) based on a geomat (16) from interlaced plastic threads, which are obtained by hot extrusion (21), wherein the geomat (16) has a thickness of approximately 4 to 5 mm or more, and moreover it is then heat-sealed on its sides with two geotextile webs (12, 14) by means of localized heating. 8. The method according to claim 7, including the step of supplying the base geocomposite (10) to the heat sealing station for fixing to at least one of the sheets (12, 14) of the base geocomposite (10) of one or more layers (19, 42, 44) geosynthetics, which is selected from the group including geogrids, geogrids, geomats, geotextiles, geomembranes, or a combination or layering thereof.

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