CZ306300B6 - Stabilized soil structure - Google Patents

Abstract

In the present invention, there is disclosed a stabilized soil structure comprising reinforcing and face nets (1, 2), being mutually interconnected by steel coils (6). At least one depression (4) is performed on at least one vertical element of the face net (2) second section (2.2), which forms the face of the stabilized soil structure. The depressions (4) are performed on elements of this face net (2) second section (2.2) in at least one row all over the net length or they are performed irregularly. The depressions (4) are performed such that their apexes direct from the plane of the face net (2) copying the structure face in the direction away from the fill, whereby horizontal rod of the face net (2) passes through the apex of the depression (4).

Description

Reinforced soil construction

Field of technology

The invention relates to reinforced soil structures which are used for the construction of retaining walls, steep slopes, embankments, bridge abutments, they can also be used in new constructions of earth bodies of transport roads, for the remediation of landslides and for landscaping. These structures with a compacted earth body and a system of inserted reinforcements have recently replaced expensive, massive concrete support structures. The purpose of these structures is to reduce the active forces that lead to the failure of the earth body and to increase the passive forces that prevent this failure. The structure of reinforced soil consists of three basic components, reinforcement and face mesh and loose - soil, which compacts after pouring, while the nets are formed by horizontal and vertical bars. Tensile reinforcement nets or geogrids with their tensile strength resist the shear stress of the soil, they are arranged horizontally in the entire width of the potential area of shear collapse. Facing nets - metal nets retain the soil of the embankment at the front of the structure, shape its outer face, complete the aesthetic character, and contribute to the overall compactness of the entire structure. A retaining and protective layer is inserted between the face net and the loose material. The interaction of face and reinforcement elements is ensured by means of connecting and reinforcement elements. The loose structure is made of soil.

Prior art

Until now, reinforced soil structures are known, usable for the purposes mentioned in the paragraph of the technical field, consisting of three basic components, reinforcing and facing nets of horizontal and vertical bars and loose material, in which reinforcing metal nets or geogrids are arranged horizontally, facing nets are metal, consisting of two parts formed by bending the net at an angle less than or equal to 90 °, one part of this net being arranged horizontally in the compacted embankment and the other part of this net forming the front of the reinforced embankment, the mutual position of both parts of this net being stabilized by reinforcing elements . A retaining and protective layer is inserted between the face net and the loose material. The loose soil is compacted after pouring. Large-sized reinforced soil structures are formed from several compacted soil layers on top of each other, these layers being separated by reinforcing nets and the reinforcing nets and face nets being systemically interconnected.

In the known known reinforced earth structures using said facing metal nets, these have a low bending stiffness, which causes great problems, especially in the construction of the reinforced earth structure itself. Facing nets generally collapse, bending, especially at longer dimensions, which causes difficulties in backfilling and compacting the soil. Facing nets must therefore be supported, for example by another supporting rigid net, which is formed without corrosion protection. The construction of these structures of longer dimensions is then more time-consuming and also more expensive with the supports used; the conditions for compaction are poor due to the bending front network.

FR 2 758 578 discloses a solution which uses nets with recesses formed on the longitudinal members of the net for reinforced earth structures, with rods arranged between the vertical part of the net and the horizontal part of the net, which define an angle of inclination between the horizontal and the vertical / oblique part of the network. The vertical part of this network does not have the necessary bending strength, in the parts between the recesses in a row above each other it is still collapsing.

In addition, in the fold of both parts of the net, the recesses have a bending resistance and the upper and lower parts of the net join poorly due to the recesses.

Previously known and used reinforcing soil structures are also characterized by complex means for connecting structural units. In particular, networks between the individual layers of the structure are complicatedly connected, for example in the solution according to the invention GB 2 140 488. Even in the solution according to the invention

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U.S. Pat. No. 4,117,686 is very laborious to connect face nets between the individual layers of the reinforced embankment.

The essence of the invention

The above-mentioned shortcomings are substantially eliminated by the structure made of reinforced soil, which consists of steel, spot-welded nets of horizontal and vertical bars, the surface of which is provided with an anti-corrosion protective layer of ZnAl alloy, namely horizontal reinforcing tensile nets and face nets. Between the face nets and the loose soil, which compacts after pouring, trapping and protective layers, for example coconut mats, are inserted. Each face net consists of two parts formed by bending the net at an angle less than or equal to 90 °, the first part of the face net being arranged horizontally in the compacted embankment and the second part of the face net forming the front of the reinforced embankment, the mutual position of the two parts at least one reinforcing element and at least one expansion element, the two types of nets are systemically interconnected, the essence of the new structure of reinforced soil lies in the fact that at least one vertical bar of the second part of the face network forming the front of the reinforced embankment the recesses being formed in at least one row of the whole network or may be formed irregularly, the recesses being formed so that their vertices point from the plane of the face net copying the front of the structure towards or towards the embankment, the apex of the recesses being formed the horizontal bar of the other part of the face net passes in one row. The face net formed with the above-described recesses has a high rigidity and thus a high dimensional stability, especially when assembling the whole structure, no supports need to be used, for example support nets, and the whole assembly is shortened in time. The dimensional stability of the second part of the face net, caused by the higher rigidity of the net with the recesses made on their vertical bars, was demonstrated during the test assembly of this net in a structure made of reinforced soil.

To support the demonstration of the influence of the cross-sections and their position created on the vertical bars of the second part of the face net, in one or two horizontal rows of the net, to reduce structural deformations, calculations were performed using SCIA ESA PT 5.2.324 software, according to ČSN EN 1991. structures, calculations of steel structures, ČSN EN 1993-1-1. The subject of the static calculation was the design and assessment, resp. comparison, of the existing and newly proposed solution, face nets (hereinafter only nets) of the structure made of reinforced soil.

The relative values of deformations of nets made of steel bars R (10 505) with meshes 50/100 mm, wires 04 mm according to the specified geometry and load were compared. Real construction: angle of bending of the net 70 °, height 750 mm, base width 250 mm, connected to the tensile net, with one reinforcing recess at a distance of 250 mm below the top, resp. double cross-section with a mutual axial distance of 4 meshes (approx. 200 mm) of the net. The nets are reinforced by inserting pairs of buckles of 0.5 m each. For the calculation, the support was simplified to a linear one of 0.5 m. Furthermore, the net was supported on three sides, the upper edge was considered free. The structure was modeled only in the plane, 6.0 m long, which allows the assessment of the "endless" strip with the neglect of the effect of termination. The unit load was chosen to be 1.0 kNm ' ² , with a uniform distribution on the vertical bars of the net (entered as a linear 0.1 kNm ¹ ). The calculation compares the ratios of deformations corresponding to the relative stiffness of individual solutions.

The following table compares the values of deformations in the field, ie in the area of the network and at its upper free edge. The size of the deformations in the individual parts is significantly influenced by the position of the reinforcing recesses. By modifying the network by making one, resp. relative deformations in the range of about 10 to 40% can be reduced of the two protrusions.

_ 7.

REINFORCEMENT DISTANCE deformation 0.5 m TYPE OF ADJUSTMENT IN THE AREA UPPER EDGE ABSOLUTELY RELATIVELY ABSOLUTELY RELATIVELY (mm) (mm) NO ADJUSTMENT POSITIVE 2.8 1.00 2.9 1.00 ONE GEAR (tooth height 35 mm) POSITIVE 2.4 0.85 2.4 0.85 DOUBLE GEAR (tooth height 35 mm) POSITIVE 1.9 0.68 2.4 0.85

Tab. 1

The central moments of inertia in the direction perpendicular to the planes of reinforcement vary for individual solutions when considering the interaction of 13 bars, near the recesses, from 163 mm ⁴ for a simple, toothless mesh, to 7260 mm ⁴ for a mesh with one toothing, respectively. 13 167 mm ⁴ for double toothed net. However, due to the subtlety of the cross-sections of the member, it is necessary to consider together with the bending stiffness of the mesh with the effect of the membrane effect. The table shows that the size of the deformations in the individual parts is also significantly affected by the position of the reinforcing recesses.

The steel spot welded reinforcing mesh is connected to the first part of the face mesh, which is arranged horizontally in the compacted embankment by steel spirals, which are formed as slightly corrugated steel wires for easy insertion, and which are surface treated as anti-corrosion as the reinforcing and facing mesh. the spirals are passed through the meshes of both nets alternately with only a slightly rotating movement. The upper edge of the first part of the face net of each lower row is further connected by means of a spiral to the lower edge of the second part of the face net of each upper row. The spirals also connect the other parts of the face nets at their side edges at the front of the structure in each embankment layer, the individual embankment layers being separated by reinforcing horizontal tensile nets, these joints being made so that they are one layer above each other, thus increases the strength of the whole structure. The connection by means of spirals is simple, the nets do not have to be equipped with any other handles. It is a fast and very strong network connection.

A retaining and protective layer, formed for example by a coconut mat, is inserted between the face net and the soil loose.

The reinforced soil structure consists of a reinforcing net and a face net, a catching and protective layer, for example a coconut mat, being placed behind the second part of the front wall from the slope, behind which a humus layer for hydroseeding is arranged in front of the bulk to green the front construction.

The reinforced soil structure may consist of a reinforcing mesh and two facing nets within one layer of the structure, the two facing nets being arranged parallel to each other at a given distance from each other, for which a spacer is used and the resulting space between the two facing nets is filled. aggregate, the retaining protective layer being inserted behind the second face screen from the front of the structure. The aggregate front created in this way has an aesthetic effect and the natural look fits into the landscape.

The solution according to the invention, with the use of recesses, connecting spirals, reinforcing elements, spacers, including arranging the blocks of the structure so that the joints at the front of the structure are one layer apart, achieves high stability of the structure, better soil compaction, the structure achieves greater stability, steeper slopes can be built, the structure has a longer service life. The solution also brings material savings, namely the use of weaker bars in the nets, by omitting the supporting elements of the front of the net, construction is more economical. By using the solution according to the invention, a short construction time of the structure from the reinforced soil is achieved, the solution is technically variable, suitable for terrain modeling. It is also possible to green the face, even at high slopes it does not interfere, creates natural conditions for flora and fauna, the face fits into the landscape, in general it can be stated that the structure has a natural appearance. Another use of the structure is in the repair of landslides, when it is possible to reuse the collapsed earth material and thus eliminates the need for a new embankment. The construction is environmentally friendly, recyclable and environmentally friendly.

The construction of the structure from reinforced soil is carried out in such a way that the horizontal reinforcing nets of the system are placed on the pre-prepared and compacted foundation joint and leveled. Facing nets are attached and connected to each other by spirals with reinforcing nets. Thus, from the inside of the face net, a retaining and protective layer, such as a coconut mat, is attached behind the face net from the inside of the face net so that the face net protrudes from both sides, on top and bottom, and the flatness of the face net and reinforcement net is checked, and it is secured against shifting by hammering nails into the compacted soil and otherwise no supports, such as support nets. The soil is spread on the structure prepared in this way, a partial compacted backfill of the layer is carried out almost to the front wall up to the end of the reinforcing mesh. This operation secures the position of the structure. By means of spacers, reinforcing elements are arranged at a given distance along the face web. The soil is backfilled to the face network of the structure and at the same time the spread materials are compacted. Due to the spatial arrangement of the reinforcing elements, a small compaction mechanization is used in the vicinity of the face network of the structure. Heavier compaction mechanization is used on the free surface of the reinforcement nets. Following the compaction of the first soil layer, backfilling and compaction of the second soil layer is performed. The total height of the compacted layer corresponds to the height for depositing the next layer of reinforcing nets. Using the spirals, the face net of the next row is attached to the upper edge of the previous face net. The further reinforcing mesh is unfolded, connected to the spirals to the face web and proceeded identically in the other layers, the side edges of the second part of the spiral face web being joined to the other applied second part of the face web in one row, these joints being made so that arranged one above the other in a row.

Reinforced soil structures designed in this way are very load-bearing and can be designed for both high heights and high loads, even dynamic loads, arising from traffic. They can achieve an inclination of up to 90 °. 1 Despite these increased demands, reinforced soils have a high stability and safety factor. Their construction is simple and fast. This construction also shows cheaper costs.

Explanation of drawings

The invention is further elucidated in the accompanying drawings, where Fig. 1 shows a section of a net from a model with indentations in two rows, Fig. 2 shows the shape of a deformed structure without indentations, Fig. 3 shows the deformation values of a structure without indentations. Fig. 4 shows the shape of a deformed structure with indentations in one row, Fig. 5 shows the deformation values of a structure with indentations in one row, Fig. 6 shows the shape of a deformed structure with indentations in two rows, Fig. 7 shows values of deformations of the structure with recesses in two rows, Fig. 8 shows the spatial design of the face network, Fig. 9 shows the layout of the face network, retaining and protective layers - coconut mats and reinforcing nets including spirals in an exploded state, Fig. 10 shows a three-dimensional connection of face nets in rows with spirals, including reinforcing elements, Fig. 11 shows a three-dimensional soil structure with three rows of sh umous layer and vegetation at the front of the structure, including reinforcing elements, Fig. 12 shows in a spatial embodiment a structure made of reinforced soil with two face nets in one row, with the space between them filled with aggregate, including spacers and reinforcing elements.

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Examples of embodiments of the invention

The reinforced soil structure shown in the accompanying drawings, Figs. 8 to 12, shows exemplary embodiments. Fig. 11 shows the whole structure of reinforced soil in the embodiment with a green face. The structure consists of steel, spot welded nets of horizontal and vertical bars with a thickness of 4 mm with a tensile strength of min. 400 N / mm2, elongation> 8% and ZnAl alloy coating min. 300 g / m2. All elements are UV resistant. The structure consists of horizontally arranged reinforcing nets 1 with a mesh size of 10x10 or 10x5 cm and a face net 2. The face nets 2 are formed in a shape formed by bending the net in this case at an angle of 70 °, the length of one net 100 cm, the first part 2.1 of the face net 2 is arranged horizontally in a compacted embankment, 50 cm long, and the second part 2.2 of the face net 2 forms the front of the reinforced embankment, 70 cm high, the mutual position of both parts of this net 2 being stabilized by at least one reinforcing element 3; both types of nets are systemically interconnected, on each vertical bar of the part 2.2 of the face net 2, which forms the front of the reinforced embankment, a recess 4 is formed in the upper part, the apex of the recess facing from the plane of the second part 2.2 of the net 2 are formed in one row along the entire length of the second part 2.2 of the face net 2, the horizontal rod of the second part 2.2 of the face net 2 passing through the apex of the cross-section. The structure of reinforced soil is further formed by a catching and protective layer 5 in the form of a coconut mat, which copies the shape of the face net 2 including the recess 4 and is arranged between the face net 2 and the embankment. Both types of nets are systemically interconnected, namely the reinforcing tensile net 1 is connected to the first part 2.1 of the face net 2, by long steel spirals 6 which are longer than the length of one face net 2 and which are surface treated as anti-corrosion as the reinforcing net 1. face net 2, the spirals 6 passing alternately through the meshes of both nets. The spirals 6 themselves are formed with only slight undulations in order to fit well into the meshes of the net - see Fig. 9. For larger nets, these two nets, which overlap each other, can be connected by two parallel spirals 6. By means of the spiral 6 it is further connected the upper edge of the first part 2.1 of the face net 2 of each lower row of the embankment structure with the lower edge of the second part 2.2 of the face net 2 of each upper row of the embankment structure. By means of the spirals 6, the second parts 2.2 of the face nets 2 are also connected to each other at their side edges at the front of the structure in each layer of the embankment structure. These joints at the front of the structure are made so that they are below each other in a row. The embankment in this construction is formed by compacted soil, i.e. compacted loose material 7, while just behind the catch and protective layer 5, i.e. behind the coconut mat, a humus layer 10 is placed, in order to subsequently green the slope face. The reinforced soil structure in Fig. 12 is formed with two face nets 2 within one layer of the structure, the second parts 2.2 of these two face nets 2 being arranged parallel to each other at a given distance from each other, for which a rectangular spacer 8 is used. and the resulting space between these second parts 2.2 of these two face nets 2 is filled with aggregate, the catching and protective layer 5 in the coconut mat embodiment being inserted behind the second face net 2 from the front of the structure.

The construction of the structure from the reinforced soil in the exemplary embodiment is carried out in such a way that the reinforcing tensile nets of the system are placed on the pre-prepared and compacted foundation joint and aligned in the horizontal plane. The face nets 2 are attached and connected to each other by means of spirals 6 with reinforcing nets L. By means of a binding wire, a catch and protective layer 5, in the design of a coconut mat, is attached behind the face net 2 from the inside of the face net 2. In order for the face net 2 to protrude by approx. 20 cm from both sides, on the mountain and at the bottom, and the flatness of the face net 2 and the reinforcing net 1 to be checked is secured against slipping by hammering nails into compacted soil, otherwise no supports, e.g. The soil is spread on the structure prepared in this way, a partial compacted backfill of the layer is performed, approx. 1 m from the face net 2 to the end of the reinforcing net 1 with a thickness of approx. 300 mm, this operation securing the position of the structure.

At a spacing of 60 cm along the face net 2, 30 cm long reinforcing elements 3 are inserted, which alternate with 60 cm long reinforcing elements 3 or the same triangular reinforcing elements are used, which are fastened to the face net by means of clips 9. the soil is backfilled to the face network 2 of the structure and at the same time the spread materials are compacted. The backfill will be compacted according to the project requirements. In the vicinity of the face net 2, the structure must be used, due to the spatial arrangement

-5EN 306300 B6 reinforcing elements 3, small compaction mechanization. A ground vibrating roller is used on the free surface of the reinforcing nets 1. The compaction layer is 20 to 30 cm. Following the compaction of the first layer of soil, backfilling and compaction of the second layer is performed. The total height of the compacted soil layer corresponds to the height for laying the next layer of reinforcement nets 1. Using the spiral 6 connect the face nets 2 of the next row of construction to the upper edge of the lower face nets 2. The other reinforcement nets 1 are distributed. and proceeds identically to the next floor of the structure. The interconnection of the second parts 2.2 of the face nets 2 at the front of the structure is performed so that the joints are one above the other.

Industrial applicability

Solution according to the invention - reinforced soil structures can be used for the construction of retaining walls, steep slopes, embankments, bridge abutments, they can also be used in new constructions of road bodies, for remediation of slope landslides and for landscaping.

Claims (4)

PATENT CLAIMS 1. Structure made of reinforced soil, which consists of steel, spot-welded nets (1), (2) of horizontal and vertical bars, the surface of which is provided with an anti-corrosion protective layer of ZnAl alloy, namely horizontal reinforcing tensile nets (1) and face nets (2), wherein the face net (2) consists of two parts formed by folding the net at an angle less than or equal to 90 °, the first part (2.1) of the face net (2) being arranged horizontally in the compacted embankment and the second part (2.2) the face nets (2) form the front of the reinforced embankment and the mutual position of both parts of this net is stabilized by at least one reinforcing element (3) and both types of nets are systemically interconnected and a catch and protection is inserted between the face net (2) and the loose (7) layer (5), characterized in that at least one recess (4) is formed on at least one vertical bar of the second part (2.2) of the face net (2), which forms the front of the reinforced earth structure, or the recesses (4) are formed in at least one row the entire length of the net or are formed irregularly, the recesses (4) being formed so that their vertices point from the plane of the face net (2) towards the embankment and the top of the recesses (4) arranged in one row runs a horizontal bar of the face net (2). . Reinforced soil structure according to Claim 1, characterized in that the horizontal reinforcing nets (1) and the first parts (2.1) of the face nets (2) are in each case connected by at least one steel spiral (6), as well as by steel spirals. (6) the upper edges of the second parts (2.2) of the face net (2) of one row are connected to the lower edges of the second parts (2.2) of the net of the following row of construction and also the other part (2.2) of the net (2) in one row are connected by steel spirals (6), these joints being made one on top of the other. Reinforced soil structure according to claims 1 and 2, characterized in that it is formed with another face network (2) within one layer of the structure, the second parts (2.2) of the two face networks (2) being arranged parallel to each other in a certain distances from each other, this distance being defined by a spacer element (8) and the resulting space between these second parts (2.2) of the face nets (2) is filled with aggregate, the retaining and protective layer (5) being inserted behind the second face net (2) from the front of the structure. Reinforced soil structure according to Claim 1 and 2, characterized in that a humus layer (10) is arranged behind the retaining and protective layer (5), behind which a loose (7) is only arranged.