RU2707214C2 - Protective-drain membrane with high-strength spikes, providing the effect of avoiding damage - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to construction and represents made of plastic thin membrane of spike type with high resistance to buckling and effect of avoiding damage at interface. Technical result is achieved by the fact that the protective-drain membrane is made with a certain arrangement of spikes, wherein said spikes have a support surface corresponding to said upper part, area of which is more than 40 mm² without taking into account said rounding edges, so that ratio between common support surface of upper parts and total surface of membrane, on which they are located, is more than 1/14, providing effect of avoiding damage to said waterproofing layer and providing resistance to warpage higher than 60,000 N/m² according to ISO EN 25619-2; wherein said resistance value corresponds to minimum density of said plastic sheet, specifically 250 g/m², wherein density of plastic sheet is from 250 to 1,000 g/m², wherein said values correspond to thickness of about 330 mcm and 1,100 mcm, respectively.

EFFECT: creation of thin protective-drain membrane of honeycomb or single-layer type for protection of underground walls, which could be laid so, that upper parts of spikes rested directly in bitumen layer, shape and distribution of spikes of which would be optimal for simultaneous provision of required drain capacity of the membrane.

9 cl, 6 dwg

Description

FIELD OF THE INVENTION

The object of the present invention is a protective and drainage membrane for the construction industry, which is a thin studded membrane made of plastic with high resistance to warping and the effect of avoiding damage at the interface.

The intended area of use of this innovation is the construction industry, in particular the sector of semi-finished materials for civil engineering projects, for example, such as (but not only) thin-walled membranes used for waterproofing and protecting the created underground structures, separating them from the surrounding soil and adjacent layers. In particular, the membrane of the present invention is single-layer, it is very light and strong, and has spikes that create the effect of avoiding damage, more precisely, the upper parts of the spikes, which, due to their construction, form a direct abutment surface at the interface, preventing them from warping or local damage without intermediate layers. An example is the often used protection and drainage outside of bitumen layers covering foundations or underground walls, in which local openings and / or tears form over time due to the fact that the plastic shell is too thin, or because its density does not correspond to the task, and also due to the fact that the membrane spikes are too far apart and / or have a too small upper part, which, having a limited supporting surface, has a perforating effect, as will be explained below.

In general, various types of membranes are currently used in construction, both single-layer and multi-layer, serving for various purposes: for example, evaporation membranes, bitumen-waterproofing membranes, drainage membranes, dividing membranes, geomembranes and dividing sheets of non-woven fabric. In particular, thin-walled studded membranes, also called honeycomb membranes, are widely used in civil engineering and environmental engineering and are generally waterproof; they are made in the form of a thin sheet of plastic with hollow protrusions (spikes), obtained by ensuring the continuity of the surface and having the shape of a cylinder, a truncated cone or a truncated pyramid, while they are arranged in the form of a regular matrix so that the distance between the lower layer and the upper layer increases , and, in fact, perform the function of struts. Essentially, they are used to create a hollow gap between the layers to provide isolation and / or drainage of penetrating liquids; indeed, it is much easier to flow along the gap formed by the aforementioned protrusions and drain naturally, under the influence of gravity, into the areas below the liquid collecting device or manifold, so that the penetrating liquids are reliably diverted from the building object to the removal device.

The most famous of studded membranes, widely used in the construction sector, is the Plato membrane of the Norwegian company Isola AS (Norway, Poshgryunn, 3946, www.isola.no) with spikes with a square base, as well as the Isostad membrane The Italian limited liability company TeMa Technologies and Materials (Italy, commune Vittorio Veneto, 31029, www.temacorporation.com) with spikes having a round base. Another example of an improved studded membrane used for waterproofing in the case of very wet or water-containing soil is the Tefond membrane manufactured by the aforementioned Italian company TeMa Technologies and Materials, which provides simplified overlap of the edges, since this membrane has studs of various shapes, contributing to the retention of the edges, as well as the adhesive joint forming a waterproof seam. It has been found that the aforementioned studded membranes used to insulate the external surfaces in contact with the ground are usually laid with the spikes outward, since they are closed on top with a filter layer of a nonwoven web connected to the upper parts of the aforementioned spikes, so as to provide free drainage space.

From the point of view of production technology, a studded membrane of the aforementioned type can be obtained by extruding a plastic sheet using a roll, on the surface of which protruding spikes are made, also called a studded forming roll. For a more detailed description of the above extrusion technology, it can be noted that it provides a gravimetric feeding system that automatically delivers the required amount of source material directly from the hopper to the extruder, where it is melted, followed by feeding on the aforementioned forming roll and uniform distribution of material along the length roll. The plastic material produced in this way by extrusion is fed slowly and temporarily adheres to the surface of the spikes of the forming roll, reproducing the shape of the spikes, and also ensuring a smooth surface in the areas between the spikes. The membrane formed in this way is then passed through heat-treating cylinders and enters the storage tank, from where it is supplied to other production lines for cutting, folding and packaging. If a filter base layer is provided in the membrane, the non-woven fabric can also be attached to the membrane during production.

The most suitable starting materials for the production of this type are olefin type resins, in particular low, medium or high density polyethylenes, called, respectively, LDPE, PESP and HDPE (HDPE is usually used for high-strength membranes), as well as polypropylene (PP ) In some cases, polystyrene (PS) is also used. These source materials may be primary or recycled; the latter are the product of recovery in the post-production or post-operational phase. For the production of high strength membranes, it is preferable to use HDPE, as in the present invention.

Taking into account the above factors, it should be recognized that the construction industry currently needs new membranes to protect underground structures, which would provide a significant reduction in size, weight and overall cost compared to conventional and well-known solutions, while at the same time ensuring sufficient strength and drainage characteristics. In particular, there is a need and desire to create a new protective-drainage membrane, which could be laid “as is”, preferably single-layer, for foundations and / or underground walls, with spikes directed towards the wall, and without any intermediate layer, so that the aforementioned underground structures are protected and properly drained, and that the interface is protected, which is usually the aforementioned bitumen layer, which can easily be damaged due to warping and / or as a result of the load on the supporting surface, the area of which is too small. Specialists in this field are well aware of the problem associated with high-strength, but significantly pointed spikes, since such spikes are small and have a conical and / or pyramidal shape, which provides high compression resistance, but sometimes also leads to damage to the aforementioned bitumen layer, since such the spikes partially penetrate into the bitumen layer, mainly due to the small size of the upper parts.

In addition, there is a need to create inexpensive studded membranes of small thickness, for example more than 5 mm to ensure optimal drainage, but less than 8 mm to ensure small dimensions produced from a sheet of plastic of low density (less than 600 g / cm ² ), in order to reduce the consumption of the original material and lower production costs, as well as ease of use and transportation compared to conventional studded membranes used for the same purpose.

State of the art

In order to determine the known level of technology development in this area, a study was conducted with the study of state archives, as a result of which the following prototypes were identified:

D1: EP0073786 (John Bergsland);

D2: EP0706594 (Luciano Mazzer);

D3: Membrane "Delta-MS" produced by the German company Dörken GmbH (Germany, D-58313 Herdecke, www.doerken.de);

D4: Delta Florax membrane of the aforementioned Dörken GmbH;

D5: US20080086958 (Jorn Schrer);

D6: WO2007087832 (Von Ötinger et al.).

Document D1 discloses a protective membrane for a foundation wall or floor on the ground made of plastic and hard material, with a plurality of spikes spaced apart and protruding from the same side, with a truncated recess in the center of each spike cone or funnel, the bottom of which is located almost flush with the membrane, so that it performs the function of an additional support at high loads. The design provides for open channels made in such a way that ribs are formed between the spikes; and finally, a filter layer may be provided on the rear side of the membrane to allow drainage from the back of the above channels.

D2 proposes a protective waterproofing membrane for covering walls or floors, containing studs arranged in the form of a regular matrix, in the overlapping zones or along the vertical connecting edges of which studs are provided that have a different shape, so that they form connecting elements of the protrusion type. cavity "; the aforementioned connecting studs are arranged in cylindrical groups, each of which includes five studs of a larger or smaller diameter depending on the relative position of the aforementioned membrane parts superimposed on one another.

In D3, a two-layer studded membrane for underground walls is disclosed, on the front side of which a filter layer is attached, with the upper parts of the spikes facing the ground (as shown, for example, in Fig. 1a, which shows the construction of a prior art membrane), in order to prevent local damage to the aforementioned bitumen layer; in particular, the proposed solution provides for spikes with a height of 4 mm, having a shape resembling an eight-pointed star, and having increased compressive or warping strength compared to known designs.

Document D4 discloses a breathable studded membrane for flat roofs and grass roofs, characterized in that the large protrusions (for example, 20 mm high) to provide increased protection for the floor slab due to the air cavity face downward; the membrane is installed on an insulating panel that protects and closes the floor slab; the aforementioned reinforced protrusions in the shape of a truncated pyramid have stiffening ribs, forming a shape like an eight-pointed star with side lobes and providing increased resistance to warping.

Instead, a single-layer studded membrane is used in D5, which is used to protect and waterproof underground walls, the design of which was proposed to eliminate the known problem of frequent damage to the bitumen layer due to the concentrated load on the upper parts of the tenons supported on it, as shown, for example, in the second figure (Fig. . 1b), also illustrating the prior art. It was proposed to increase the contact area of the aforementioned shell, more precisely, the ratio of the surface area of the spikes to the total surface, due to a denser arrangement of the protrusions and their special shape, including, in combination, more precisely, in an irregular matrix.

Document D6 describes a special single-layer studded membrane for underground walls, thin and high strength, with the upper parts of the spikes abutting the aforementioned bitumen layer, as schematically shown in the second figure, illustrating the prior art (Fig. 1b); in particular, a reinforced configuration with truncated cone-shaped spikes with six oblique cylindrical grooves with a radius of 2.5 mm on the base, next to which there are the same number of side ribs located around the circumference at an angle of 60 degrees to each other, is proposed. The proposed upper part of the spike, thus, has small dimensions and the shape of a six-pointed star.

Thus, well-known technical solutions for used underground membranes for waterproofing and / or drainage of civil engineering or environmental engineering include:

- studded waterproof sheet of thin plastic with protrusions of a cylindrical, or truncated-conical, or truncated-pyramidal shape, used separately with the upper parts of the spikes resting on a waterproof shell, or with a filter layer attached to the aforementioned upper parts and in contact with the soil, such so that it is possible to drain the incoming liquids in the gap formed by the spikes;

- studded waterproofing membrane with different areas, more precisely, areas where the protrusions have a flat upper part to provide normal stop at the interface, and the side areas on which the protrusions have a rounded upper part and are located differently than mutual overlap along the edge and the formation of connecting protrusion-cavity elements in order to create a continuous waterproof layer;

- hardened spikes to increase resistance to warping, having the shape of a truncated cone or pyramid with grooves inside and / or ribs outside, arranged so that the resulting spike profile resembles a star and / or flower with petals.

The disadvantages of the prior art

Undoubtedly, it was noticed that the technical solutions described above have certain disadvantages or limitations.

In general, the first problem is that damage occurs at the interface as a result of the studded membrane resting directly on the interface with its upper parts, as is currently done in the construction sector, and as shown in the aforementioned FIG. 1b, demonstrating the prior art. The experiments showed that in a conventional waterproofing bitumen layer 3.5 mm thick, recesses up to a depth of 0.63 mm can occur, i.e. its thickness can be reduced by 20%, which can occur, for example, when using a studded membrane with a total thickness of approximately 6 mm with reinforced truncated conical spikes in the form of a six-pointed star, known on the market under the trade name Gutta Beta Star manufactured by the Swiss company Gutta International AG "(Switzerland, 6302 Zug, www.gutta.com), which generally corresponds to the aforementioned technical solution for document D6. In addition, it was found that the aforementioned serious problem of damage to the interface is not well defined and regulated by the currently applicable standards and / or specifications for registered products.

Secondly, it was found that in cases where the aforementioned upper parts of the studs of single-layer membranes are filled with filler or backfill material, the pressure that they exert on the waterproof shell of the underground wall is significantly lower than the maximum pressure values declared by manufacturers, which, for example, declare that the warping resistance is 200 or 300 kN / m ² , which, however, is sufficient to damage the aforementioned waterproofing and the appearance of the aforementioned recesses on its surface th, i.e. for local reduction of shell thickness.

Thirdly, it was found that the limited height of the spikes, which should be, for example, no more than 5 mm, and the increased density of the supporting surfaces significantly reduce the drainage capacity of the membrane and increase (with the same density) its compressive strength. Thus, among the known solutions of studded membranes, it was found that the optimal height of the spikes for single-layer vertically stacked membranes, to ensure optimal drainage and ease of use, is from 5 to 8 mm; however, for the aforementioned membranes, it was also found that in order to achieve increased warping resistance, a density of the aforementioned spikes of more than 1850 or even 2000 elements per square meter is required and that such increased density sometimes leads to the aforementioned damage and / or damage to the waterproof membrane due to a local reduction in its thickness commonly called "indentation." The same thing happens with a limited abutment surface, namely, as a result of the fact that each tenon has a small upper part, that is, an upper part with a supporting surface less than or equal to 35 mm ² , sometimes angular in shape, which reinforces the aforementioned damage effect. For example, the aforementioned Gutta Beta Star membrane manufactured by Gutta International AG has spikes with a diagonal matrix with a density of more than 1850 / m ² , equipped with lateral reinforcing grooves that give the hexagonal upper part a small shape of a pointed six-pointed star, with an apofem equal to approximately 3.5 mm, the surface area of the aforementioned upper part being less than 35 mm ² ; thus, such a configuration of the spikes can provide increased resistance of the spikes to warping, but contributes to damage at the interface.

Considering this problem in more detail from a professional point of view, with all the desire, it is impossible to find any known single-layer protective membrane for underground walls that would be thin, that is, would provide moderate weight and cost, and which could be used by installing in this way so that the upper parts of the tenons rest against waterproofing, providing the necessary drainage and warping, that is, that would solve the above problem of penetration of the tenons into the interface. For example, the aforementioned conventional technical solutions according to documents D1-D4 do not provide the possibility of such an application, and the solution according to document D5 is ineffective, since the invention has other purposes; the latter solution, nevertheless, offers certain principles that are useful for solving the aforementioned problem, for example, the principle of increasing the bearing surface, as well as the principle of ensuring the optimal combination of the spikes height, their distribution and their shape, even the sheet thickness affects the resistance of the studs . And finally, the aforementioned D6 solution provides both the required drainage and the increased resistance of the tenons to warping; it has significantly increased dimensions in comparison with known solutions, but does not create the aforementioned problem of damage at the interface, nor does it create problems in sheet density, which can be reduced, thereby providing a significant reduction in weight and material costs. In particular, it was found that the distribution and shape of the spikes in D6 can be improved so as to significantly increase the bearing surface at the interface and eliminate significant protrusions and sharp edges, as well as reduce the density and facilitate the process of separating the product from the forming element.

Thus, it was found that all known solutions meet only some of the requirements for modern studded membranes for underground walls, and do not provide the ability to create a production configuration that would provide a balanced and optimal solution to all the above problems, namely, the optimal shape of the studs and their distribution, the drainage of walls and the resistance of the spikes to warping, as well as the elimination of damage at the interface, all in combination with the optimal overall height and thickness Noah. Thus, the task facing specialists in this field is to identify solutions that are more effective than the known solutions, and the task of the present invention is to solve the above problems.

SUMMARY OF THE INVENTION

The above and other problems are solved by the present invention, the distinguishing features of which are set forth in the attached claims and which offers a high-strength protective and drainage membrane (10) for use in construction, with the effect of avoiding damage to the separation layer containing truncated pyramidal spikes (111) located a regular or diagonal matrix with a pitch (P) from 24 to 26 mm, while their base (113) is inscribed in a regular octagon with an apofeme (122) equal to approximately 8.5 mm, and their upper part (112) is inscribed in a regular octagon with an apofem (123) of approximately 4.5 mm, with rounded edges with a minimum radius of curvature of 0.6 mm, with an effective area of more than 40 mm ² and a ratio of the total supporting surface to the membrane surface area of more than 1 /14. Preferably, said spike (111) is reinforced with curved side walls that can be continuously connected to each other so that they form a sine wave shape with a specified ratio of approximately 1/10. The specified membrane (10) contains overlapping side strips that do not contain these spikes (111).

Object of the invention

Thus, the present invention creates a significant creative contribution, providing a valid inventive step.

The first task is to create a thin protective-drainage membrane of a honeycomb or single-layer type to protect the underground walls, which could be laid so that the upper parts of the tenons rest directly against the bitumen layer, the shape and distribution of the tenons of which would be optimal to simultaneously provide the required drainage the ability of the membrane, sufficient resistance of the spikes to warping, and, in particular, to solve the above problem of damage at the interface, that is, to achieve Ia effectively avoid the damage effect.

The second objective of the present invention, inextricably linked with the above first task, is to create a protective-drainage membrane, the spikes of which would be as hardened to provide resistance to warping, sufficient for most applications for underground walls, that is, above 60 kPa according to the EN ISO standard 25619-2, even with a small thickness of the plastic sheet or with its limited density equal to, for example, 250 g / m ² , which would provide obvious advantages in weight and cost.

The third task is to create a protective-drainage membrane, which could be easily produced on an industrial scale at low production costs and with increased production volumes; in addition, the proposed membrane with rounded edges of the studs should provide ease of separation of the studs from the forming rolls.

A fourth object of the present invention is to provide a protective-drainage membrane having all of the above advantages, as well as facilitating the process of laying in place and connecting adjacent adjacent edges of the membrane using overlapping side strips providing continuous protection.

These and other advantages of the technical solution proposed by the present invention will become clearer after reading the following detailed description of some preferred options for its implementation, with reference to the accompanying drawings; it should be borne in mind that the preferred embodiments of the invention are not limiting, but are given only as examples.

Brief Description of the Drawings

In FIG. 1a and 1b show two different studded membrane structures according to the prior art used for protecting and draining a foundation wall covered with a waterproofing layer, for example a bitumen layer. In more detail, the first structure (Fig. 1a) is a studded membrane connected to a filter layer located in accordance with the upper parts of the spikes and facing the ground so that a gap is formed between the aforementioned filter layer in contact with the ground and the sheet plastic in contact with the wall. The second structure (Fig. 1b), on the contrary, is a single-layer studded membrane, that is, a membrane without the aforementioned filter layer, which is installed “opposite” compared to the previous structure, that is, to the wall, with the upper parts of the spikes resting directly against the waterproofing layer . The present invention relates to a second configuration (FIG. 1b);

in FIG. 2 is a side view of a membrane according to the present invention with two adjacent spikes (image is schematic, rounded edges are not shown);

in FIG. 3 is a plan view of the membrane of the present invention shown in the previous figure;

in FIG. 4 is a schematic view (top view) of a tenon according to a possible embodiment of the invention, showing the geometrical parameters of the tenon;

in FIG. 5 is an image of a tenon (top view) according to the present invention with rounded edges highlighted.

The implementation of the invention

Below is a detailed description of the present invention with reference to the accompanying drawings, the object of which is an improved protective drainage membrane 10 for use in the construction sector, studded type and thin (Fig. 2-5), which is single-layer or preferably does not have a filter layer, so that it is installed in such a way that the upper parts of the spikes face the wall (Fig. 1b, illustrating the prior art), providing increased resistance to warping and efficient drainage of the foundation mantle wall 104, according to modern technology, and so that it protects the interface 103, preventing damage due to indentation and / or penetration of the upper parts of the spikes into it. The aforementioned studded membrane 10 is made from a sheet 110 of recycled plastic material, preferably a polyolefin type, such as HDPE or PP, or a mixture thereof.

The proposed membrane 10 already provides increased resistance to warping, preferably more than 60,000 N / m ² according to ISO EN 25619-2, with a sheet of 110 HDPE plastic with a minimum density of about 250 g / m ² , as a result of which the thickness of such a membrane is reduced in comparison with known technical solutions; it should be noted that such a value of buckling resistance is quite sufficient for most applications with a depth of not more than 5 m and medium density soil and / or this type. Thus, a higher warping resistance can be achieved by simply increasing the weight of the aforementioned plastic sheet 110 while maintaining the shape of the spike 111, that is, using the same equipment, a membrane 10 with a density of 250 to 1000 g / m ² can be obtained. In a preferred (but not the only possible) embodiment of the invention, a HDPE sheet 110 is used with a density of 500 g / m ² and a thickness of approximately 550 μm, with a spike height H1 of approximately 5.5 mm, i.e. with a total height of H2 6 mm, which provides a sufficiently high resistance to warping with good drainage ability vertically and an acceptable total weight.

The proposed membrane 10 (Fig. 2-5) contains hollow protrusions 111, called spikes, extending upward from the upper side 114 so that the upper part 112 abuts directly at the interface, i.e. into the waterproofing layer 103 of the foundation wall 104, for example, into the bitumen layer, and the lower side 115 of the membrane 10 is in direct contact with the backfill material 102. In more detail, the present invention provides an improved design of the studs 111 having the shape of an octagonal truncated pyramid 116, 117, 121, which is able to balance and optimize the various functions that it must perform at the same time, i.e. drainage and warping, including the effect of avoiding damage at the interface ; in addition, the proposed membrane 10 is light, and it can easily be laid on the wall in a continuous layer; in addition, this membrane is inexpensive, and it can be produced in large volumes on an industrial scale.

Thus, the aforementioned studs 111 are studs of a conventional type, but have an optimized shape and arrangement, which allows an increased warping resistance due to the special design of the walls and tops of the studs, providing a reduced density of the aforementioned sheet 110. In particular, an octagonal stud with a plurality of structurally interacting patterns is proposed. sides, with an enlarged upper part and edges that are rounded, which provides a solution to the aforementioned problem of penetration of the spike into the bitumen layer. With respect to known and conventional technical solutions for hardened truncated conical studs, for example, such as the aforementioned Gutta Beta Star membrane manufactured by Gutta International AG, the proposed membrane 10 is a non-damaging membrane and has studs 111 located with reduced density, namely less than or equal to 1800 / m ^2, preferably approximately 1600 / m ^2, wherein the area of the upper portions 112 of each of them is at least 40 mm ^2, preferably greater than 60 mm ^2, and thus the ratio of total second supporting surface of the membrane in contact with the interface, to the total area of the membrane, effectively increases; in addition, the construction of this membrane eliminates all pointed or angular elements that may cause the aforementioned indentation or penetration.

In a preferred embodiment of the invention (FIGS. 2-5), the aforementioned spike 111 is a reinforced spike in the form of a truncated octagonal pyramid with curved side walls, which, in this way, uses the known method of hardening, which consists in using a reinforcing star-like shape, and / or a flower and / or petal type; in particular, in the aforementioned spike 111, the aforementioned curved walls are optimized in shape and size, depending on the scope of the invention, and are curved sections 126, 127, continuously connected so that they form a sinusoidal wave shape with rounded edges (FIG. 5), and retain the above-mentioned advantages of an enlarged bearing surface with the effect of avoiding damage.

Upon a more detailed consideration of the embodiment of the invention shown in FIG. 4, it can be seen that the aforementioned spike 111 can be geometrically inscribed in an octagonal truncated pyramid, since the base 113 of the aforementioned spike 111 can be inscribed in a regular octagon, called the large octagon 116, with an apofee 122 of 8 mm to 10 mm, and the aforementioned upper part The spikes 112 can be inscribed in a regular octagon, called the small octagon 117, with an apofeme 123 of 4 mm to 5 mm. Thus, the aforementioned octagons 116, 117 and the aforementioned octagonal truncated pyramid have vertices 120 and side ribs 121 located radially at an angle of 45 ° to each other, with all sides 119 being equal to each other. The aforementioned studs 111 have a height H1 of 5 mm to 7 mm and are arranged in the form of a regular or diagonal matrix with a pitch P of 24 to 28 mm, with all edges 131 of these studs 111 being rounded from the outside 114, with a minimum the radius of curvature is 0.6 mm. The aforementioned spike 111 has a support surface corresponding to the aforementioned upper part 112, the area of which is more than 40 mm ² without the area of the aforementioned rounding, so that the ratio of the common supporting surface of the upper parts 112 to the common surface of the membrane 10 on which they are located is more than 1 / 14, which creates the effect of avoiding damage to the aforementioned waterproofing layer 103 and provides a value of warping resistance above 60,000 N / m ² according to ISO EN 25619-2; moreover, such a value of buckling resistance is achieved at a minimum density of the aforementioned plastic sheet 110, which may be, for example, 250 g / m ² .

In a preferred (but not the only possible) embodiment of the invention (Fig. 4, 5), the spike 111 comprises curved and wavy inclined side walls, consisting of 16 cylindrical sections convex outward and inward alternately, namely, eight concave sections 126 and eight convex sections 127, said sections 126, 127 being connected to each other in such a way that they form a sinusoidal wave shape, so that the tenacity of the tenon is significantly increased; the octagonal oblique profile described above forms the aforementioned upper portion 112, which serves to provide the aforementioned effect of avoiding damage as well as facilitating molding. The aforementioned concave sections 126 form the sides of the aforementioned octagonal truncated pyramid, since they start from arcs 124 on the base 113, and the arcs 124 have a radius R1 of 4.4 ± 0.5 mm centered outside the spike 111; the aforementioned radius R1 is equal to the radius R4 of a circle 129 inscribed in the aforementioned upper part 112, with a tolerance of ± 5%. Conversely, the aforementioned convex portions 127 form side ribs 121 of the aforementioned octagonal truncated pyramid; they start on the base 113 with arcs 125 of radius R2 of size 8 ± 0.5 mm centered inside the stud 111, the radius aforementioned R2 being preferably equal to the radius R3 of circle 128 inscribed in base 113 with a tolerance of ± 5%. The aforementioned large octagon 116 has an apofema 122 of 8.5 mm size, and the aforementioned small octagon 117 has an apofema 123 of 4.5 mm size, with a tolerance of ± 0.5 mm for the indicated values; preferred values of said apothems 122, 123 are 8.9 mm and 4.5 mm, respectively.

In addition, in a preferred, but not the only possible embodiment of the invention (FIGS. 2-5), the total height H2 of the aforementioned membrane 10 is 6 mm and the spike height H1 is 5.5 mm, while the thickness of the aforementioned sheet 110 is 550 μm at a density of 500 g / m ² ; the tolerance on the above heights H1, H2 is ± 1 mm. In addition, the aforementioned spikes 111 are arranged in a square matrix with a pitch P of 26 mm and a total number of spikes of approximately 1600 / m ² . The aforementioned arcs 124 have a concavity on the outside (FIG. 4) with a radius R1 of 4.39 mm, this radius essentially corresponding to the radius R4 of the circle inscribed in the upper part of the tenon and the chord 130 obtained by crossing with the side 119 of the aforementioned large hexagon and equal to 4.76 mm. The aforementioned arcs 125 have a concavity from the inside with a radius R2 of 7.99 mm, which essentially corresponds to the radius R3 of the circle inscribed in the base of the tenon; thus, both arcs 124, 125 and the aforementioned chord 130 are bounded by an angle of approximately 14 °, with the same center 118 as the aforementioned octagons 116, 117, and with a bisector at the aforementioned ribs 121 or vertices 120 radially located at an angle of 45 ° to each other. The tolerance for the above values is ± 5%.

With the configuration described above, the surface area of the aforementioned upper portion 112 is 67.5 mm ² without the aforementioned rounding area, so that the resulting aforementioned ratio of the total supporting surface of the studs on the waterproofing layer to the total surface of the membrane 10 is at least 1/10.

In addition, the improved membrane 10 according to the present invention provides some implementation options, not shown in the accompanying drawings, which facilitate laying the membrane in place, allowing overlapping and partial connection with each other of the edges of the two membranes. In particular, in addition to the distinguishing features described above, along at least one edge of the membrane 10 there is an overlapping side strip on which there are no aforementioned studs 111, so that partial overlap between adjacent membranes is ensured, which ensures continuity of protection and drainage, exactly the same as, for example, this is provided in the aforementioned membranes, known in the market under the names Isostad and Tefond, produced by the aforementioned Italian limited liability company yu "TeM Technologies & Materials".

In more detail, in the first simplified embodiment of the invention, the aforementioned overlapping side strip is smooth and has a width of 5 cm with a tolerance of ± 20%. In another embodiment of the invention, allowing the membranes 10 to be combined, the aforementioned overlapping side strip is provided on two opposite sides of the membrane 10 and comprises protrusions serving as fastener buttons; moreover, on one side are male fastener elements, and on the other side are female fastener elements, the protrusions have a corresponding response shape on two opposite sides of the same membrane 10; the width of the aforementioned overlapping side strip is 18 cm with a tolerance of ± 5 cm. Finally, in another embodiment of the invention, a safety strip is provided that is located on and parallel to the aforementioned overlapping side strip and which may contain a sealant and / or a gasket, for example, like double-sided adhesive tape.

The production of the protective and drainage membrane 10 described above can easily be carried out using existing technologies and existing conventional equipment used by modern plants in this industry. In more detail, the production method involves the following operations: extruding the starting material to form a thin sheet 110 (at least one high-strength thermoplastic polymer such as HDPE or a mixture of different polymers can be used as the above-mentioned starting material); then the resulting thin sheet is passed through a forming rolling roller, on the surface of which protrusions are made, which ensure the formation of the aforementioned spikes 111 located in the matrix with a constant pitch P, with a total height of 5 to 7 mm. Thus obtained studded membrane 10 is rolled into coils or rolls. It should be noted that the shape of the aforementioned improved studs 111 (see FIG. 3) with rounded edges 127 and concave-convex side walls 125, 126 connected to each other so that they form a sinusoidal wave shape greatly simplifies the molding process by Compared to molding conventional studs in the shape of a star or a truncated pyramid, in particular, it facilitates the separation of the aforementioned protrusions from the forming roll, which provides increased productivity and / or reduced production waste in.

Thus, in practice, it was found that the object of the present invention, the protective-drainage membrane provides the tasks, providing increased resistance to warping, good drainage ability, as well as effective prevention of damage at the interface; the proposed technical solution greatly simplifies the production process and provides the opportunity to increase production volumes without increasing production costs.

Designations

10 - high-strength studded protective-drainage membrane for use in construction, which is the object of the present invention;

100 - ordinary studded membrane;

101 - permeable layer of non-woven fabric;

102 - backfill material;

103 - waterproofing layer;

104 - foundation wall;

105 - ordinary spike;

106 - the usual upper part of the spike;

110 - waterproof extruded plastic sheet of a membrane, which is the object of the present invention;

111 is a spike of the membrane of the present invention;

112 - the upper part of the spike of the membrane, which is the object of the present invention;

113 - the base of the spike of the membrane, which is the object of the present invention;

114 - the upper side of the membrane, the upper parts of the spikes of which abut against the waterproofing layer;

115 — bottom side of the membrane facing backfill material;

116 is a large octagon, described around the base of the tenon;

117 is a small octagon described around the top of the tenon;

118 - the center of the aforementioned large and small octagons;

119 - side of a large octagon;

120 - the top of a large octagon;

121 - the edge of the octagonal truncated pyramid described around the spike;

122 - apothem of the large octagon;

123 - apothem of the small octagon;

124 - inwardly concave arc on the base;

125 - arch curved outward on the base;

126 - inclined concave section of the cylindrical wall;

127 - inclined convex section of a cylindrical wall;

128 - a circle inscribed in the base;

129 - circle inscribed in the upper part;

130 - the chord of the arc concave inward at the base;

131 - rounded edge;

H1 - spike height;

H2 is the total height of the studded membrane;

P is the pitch of the regular matrix in which the spikes are located;

R1 is the radius of the concave arc on the base;

R2 is the radius of the arc curved outward on the base;

R3 is the radius of the circle inscribed in the base of the spike;

R4 is the radius of the circle inscribed in the upper part of the tenon.

Claims (9)

1. A protective-drainage membrane (10) of a single-layer studded type for construction, obtained from a thin extruded sheet (110) of plastic, with high-strength hollow protrusions or spikes (111) and an improved supporting surface near the interface; wherein said truncated pyramidal type studs (111) protrude from the upper side (114) of said membrane (10) so that the upper part (112) can directly abut against said interface, such as a waterproofing layer (103) of the foundation wall ( 104), leaving the bottom side (115) of the membrane (10) in direct contact with the backfill material (102), characterized in that each tenon (111) can be inscribed in an octagonal truncated pyramid, while the base (113) of the indicated tenon ( 111) can be entered in the correct eight the golnik, called the large octagon (116), with an apofeme (122), comprising from 8 to 10 mm, and the indicated upper part (112) of the tenon can be inscribed in a regular octagon, called the small octagon (117), with the apofeme (123), component from 4 to 5 mm; wherein said octagons (116, 117) and said octagonal truncated pyramid have vertices (120) and side ribs (121) located radially at an angle of 45 °, with all sides (119) being equal to each other; while these spikes (111) have a height (H1), the value of which is from 5 to 7 mm, and rounded edges (131) on the outside (114) with a minimum radius of 0.6 mm; moreover, these spikes (111) are located in the matrix and with a density of not more than 1800 spikes / m ² ; wherein said studs (111) have a supporting surface corresponding to the indicated upper part (112), the area of which is more than 40 mm ² without taking into account the indicated rounding of the edges, so that the ratio between the common supporting surface of the upper parts (112) and the common membrane surface (10 ), on which they are located, is more than 1/14, provide the effect of avoiding damage to the specified waterproofing layer (103) and at the same time provide a value for warping above 60,000 N / m ^{2 in} accordance with ISO EN 25619-2; moreover, the specified resistance value corresponds to the minimum density value of the specified sheet (110) of plastic, namely 250 g / m ² , while the density of the sheet (110) of plastic is from 250 to 1000 g / m ² , and these values correspond to a thickness of approximately 330 μm and 1100 μm, respectively. 2. A protective-drainage membrane (10) according to claim 1, characterized in that said spikes (111) are arranged in a regular or diagonal matrix with a pitch (P) of 24 to 28 mm. 3. The protective-drainage membrane (10) according to claim 2, characterized in that said spike (111) contains inclined side walls that are curved and wavy and consist of 16 cylindrical sections directed outward or inward alternately, namely , respectively, of eight concave sections (126) and eight convex sections (127), and these sections (126, 127) are connected to each other in a continuous sequence in the form of a sine wave in such a way that the resistance to warping and the octagonal inclined profile are increased said upper part (112) is used, which serves to provide the indicated effect of avoiding damage, and molding is also facilitated; while these concave sections (126) are located in accordance with each side of the specified octagonal truncated pyramid, and they begin on the basis of (113) from arcs (124) with a radius (R1) of 4.4 mm with a tolerance of ± 0.5 mm, wherein said radius (R1) is also equal to the radius (R4) of a circle (129) inscribed in said upper part (112), with a tolerance of ± 5%; moreover, these convex sections (127) are located in accordance with each side edge (121) of the specified octagonal truncated pyramid, and they begin on the basis of (113) from arcs (125) with a radius (R2) of 8 mm with a tolerance of ± 0.5 mm ; wherein said large octagon (116) has an apofema (122) of 8.5 mm and said small octagon (117) has an apofema (123) of 4.5 mm, the tolerance for these values being ± 0.5 mm. 4. The protective-drainage membrane (10) according to claim 3, characterized in that it has a total height (H2) of 6 mm, the spike height (H1) of 5.5 mm and the thickness of said sheet (110) being 550 microns at a density of 500 g / m ² ; wherein said spikes (111) are arranged in a square matrix with a constant pitch (P) of 26 mm and with a total number of spikes of approximately 1600 / m ² ; moreover, these arcs (124) have a concavity on the outside with a specified radius (R1) of 4.39 mm and a chord (130) of 4.76 mm; wherein said arcs (125) have a concavity from the inside with a specified radius (R2) of 7.99 mm; moreover, the surface area of the specified upper part (112) is 67.5 mm ² without taking into account the specified rounding of the edges, so that between the common supporting surface on the waterproofing layer and the common surface of the membrane (10) the specified ratio is obtained, equal to at least 1/10; moreover, the indicated arcs (124, 125) and the indicated chord (130) are bounded by an angle of 14 ° with the same center (118) as the indicated octagons (116, 117), and with a bisector on the indicated edges (121) and vertices ( 120); moreover, the tolerance on the magnitude of the indicated heights (H1, H2) is ± 1 mm, and the tolerance on the other indicated dimensions is ± 5%. 5. Protective-drainage membrane (10) according to any one of paragraphs. 1-4, characterized in that at least along one edge it contains an overlapping side strip that does not contain these spikes (111), so that partial overlap between adjacent membranes is ensured, which contributes to the continuity of protection and drainage. 6. The protective-drainage membrane (10) according to claim 5, characterized in that said overlapping side strip is smooth and has a width of 5 cm with a tolerance of ± 20%. 7. A protective-drainage membrane (10) according to claim 5, characterized in that said overlapping side strip is present on both opposite sides of said membrane (10) and contains protrusions serving as fastener buttons, with male elements being located on one side fasteners, and on the other side - covering the fastener elements, while these protrusions have a corresponding response shape on two opposite sides of the same membrane (10); and the width of the specified overlapping side strip is 18 cm with a tolerance of ± 5 cm. 8. A protective-drainage membrane (10) according to claim 6 or 7, characterized in that on and parallel to the aforementioned overlapping side strip there is a safety strip that may contain a sealant and / or a sealing gasket, such as a double-sided adhesive tape. 9. The protective-drainage membrane (10) according to any one of paragraphs. 1-8, characterized in that said sheet (110) is made of primary or recycled plastic, preferably a polyolefin type, such as HDPE, or PP, or a mixture thereof.

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