RU2166025C1 - Earth-consolidation framework - Google Patents

Abstract

FIELD: construction engineering. SUBSTANCE: framework may be used for consolidation of slopes, overpass cones, coastline slopes, and beds of reservoirs and for reinforcement of road bases, airdromes, industrial and civil engineering structures. Earth-consolidation framework has cellular structure assembled of flexible polymeric bands placed on ribs and welded together in staggered manner. Novelty is that polymeric bands are joined together by means of linear seams under compression with staggered clamping points; size of clamping points and distances between them are from 2 to 5 mm, area of clamping points is 15-30 % of joint area. Framework is noted for high strength of welds, uniform distribution of thrusts on structural members of each cell and redistribution of these thrusts on adjacent cells due to interaction among filler materials of adjacent cells by means of holes in their walls. EFFECT: improved strength of framework and water-tightness of cell walls; enhanced reinforcing effect. 9 cl, 4 dwg

Description

 The invention relates to the field of construction and can be used to strengthen slopes, cones, overpasses, slopes of coastlines and channels of water bodies, as well as for reinforcing the foundations of roads, airfields, industrial and civil construction.

 A device for strengthening soils in the form of a geogrid of a cellular structure made of flexible polymer strips interconnected by welds in such a way that when tensile they form a cellular structure (see US patent N 4717283, CL E 02 B 3/72, 1988 g.). Known technical solution has the following disadvantages. Firstly, the structural strength is not ensured due to the low strength of welds made without taking into account the optimal ratio of temperature, conditions of pressing strips and welding time. Secondly, the cell walls are solid waterproof, which violates the natural hydrological conditions and the drainage of water down the slope. The root system of plants is to some extent isolated by the cell, which complicates the conditions for the formation of a stable sod layer on the protected surface.

 Known geogrid with a cellular structure for strengthening the soil surface, made of flexible polymer strips mounted on the ribs and connected to each other in a checkerboard pattern with welds. Flexible polymer strips are perforated from a mixture of polyamide and polyethylene, with a perforation step in the longitudinal and transverse directions from 15 to 70 mm, and hole sizes from 3 to 16 mm (see RU 2136817, 09/10/1999). However, the known geogrid with a cellular structure has insufficient resistance to the aggressive effects of the soil environment, since the material of the polymer strips contains polyamide. This geogrid also has a low strength of welds, the dimensions of which are selected without taking into account the optimal ratio of the heating temperature, the clamping parameters of the strips and the welding time. The cell walls of the known device have insufficient rigidity, since the size of the holes varies from 3 to 16 mm, and the perforation pitch from 15 to 70 mm. Due to the non-optimal size of the holes and their irrational location on the surface of the cells, deformation (crushing) of the walls is possible when laying soil in them. In addition, the tensile strength of the strip along the line of holes may be less than the strength along the line of the weld, the highest value of which (as shown by experimental studies) is 40-60% of the strength of a continuous strip. The size of the holes is not related to the granulometric composition of the soil, which can lead to suffusion (leaching) of soil grains from the cells through the holes in the walls in case of strengthening clay and sandy soils, or vice versa, insufficient communication of the cell cavities when laying crushed stone or concrete in them.

 The closest technical solution is a geo-frame of a cellular structure made of flexible polymer tapes mounted on the ribs and interconnected by welds located in a checkerboard pattern (see RU 2129189, 04/20/1999).

 The problem to which the present invention is directed, is to increase the strength of the weakest structural element, namely the weld, as well as increase the service life and strength of the cellular structure under the influence of the soil environment.

 The problem is solved due to the fact that in the geocarcass of a cellular structure made of flexible polymer tapes mounted on the ribs and interconnected by welds located in a checkerboard pattern, polymer tapes are interconnected by linear seams under pressure when they are compressed with the location of the pressure points in a checkerboard pattern, with the size of the pressure points and the distance between them being from 2 to 5 mm, and the area of the pressure points is 15-30% of the seam area.

 The problem is also solved due to the fact that the polymer tape can be made from a mixture of high pressure polyethylene and low pressure polyethylene in a ratio of 1: 1 to 1: 5.

Also, the cell walls can be perforated, with the holes being uniformly distributed over the cell wall area, and their size (d) is determined from the relation: d = k · d ₃ , where d ₃ is the largest grain size of the soil, and k is the experimentally established coefficient selected from the range: for clay and sandy soils from 1 to 4; for gravel, gravel, sand and gravel and concrete - from 0.5 to 1.0, while in any vertical section of the cell wall, the sum of the size of the holes should be no more than 40% of its height.

 Also, the cell walls can be made non-perforated.

 Light stabilizers or pigments can be introduced into the material of the polymer tape, and its thickness is from 0.5 to 2.0 mm, and when stretched, the length of the geocarcass is from 4 to 12 m, width is from 0.5 to 3.0 m, height from 0.05 to 0.3 m, cell size from 0.10 to 1.0 m.

 In this case, the welds can be located perpendicular or inclined with respect to the base of the geocarcass, and the pressure points are formed using two clamps, one of which has a flat contact surface, and the other a contact surface in the form of two or more rows of staggered stitches , as well as the walls of the cells can be fixed between themselves and with the surface being strengthened by means of connecting elements passed through holes in the walls of the cells.

 The technical result is to ensure maximum values of the strength of the geogrid, the permeability of the cell walls and the reinforcing effect due to the increased strength of the welds, the uniform distribution of loads on the structural elements of each cell and the redistribution of these loads to neighboring cells through the interaction of the filler material of adjacent cells using holes in their walls , as well as due to the optimal location of the holes in the walls of the geocarcass and the optimal size of the holes selected with taking into account the granulometric composition of the strengthened soil.

Polymer tapes can be made of a mixture of high pressure polyethylene and low pressure polyethylene in a ratio of 1: 1 to 1: 5. The optimal composition of the mixture is selected empirically and corresponds to the maximum pull-out force (P _o ) of two tapes, welded together by a linear seam under pressure. Experimental studies have shown that the best results by the criterion P _{о are} achieved when compressing the welded strips by means of two clamps, one of which contains point protrusions, and the other has a flat contact surface, while the area of the pressure points is 15-30% of the weld area, and the points the clamps are staggered in at least two rows. The size of the pressure points and the distance between them are selected in the range from 2 to 5 mm. To increase the reinforcement effect, welds are placed perpendicular to the base of the geoframe in the case of strengthening horizontal soil layers or obliquely in the case of reinforcing slopes or other inclined surfaces. Welds can have a gap zone equal to from 0.2 to 0.5 of the height of the geoframe. When the geocarcass is stretched to the operating state, the weld gap zones open, forming slotted holes, which improves drainage conditions and the communication of cavities of adjacent cells.

The holes in the cell walls are evenly distributed over its area and outside the weld zone. The width of the area free from holes is equal to three times the width of the weld. In any vertical section of the cell wall outside the weld zone, the sum of the hole sizes should be no more than 40% of its height. When this condition is met, the tensile strength of the tape along the line of holes will be approximately equal to the strength of the weakest element of the geoframe, namely the strength of the weld, which meets the criterion of equal strength design. The optimal hole size (d) in the cell walls is determined from the relation: d = k · d ₃ ≥ 1 mm, where d ₃ is the largest grain size of the soil, and k is the experimentally established coefficient selected from the range: for clay and sandy soils from 1 up to 100; for crushed stone, gravel, sand and gravel and concrete from 0.5 to 1.0.

 In the manufacture of geoframes for reinforcing fine-grained (clay) soils, when, in accordance with the formula, the optimum hole sizes are less than 2 mm, it is advisable to also perforate the weld zone, provided that their strength is not less than 40% of the tape strength.

 In the manufacture of geo-frames to strengthen clay and sandy soils at facilities where hydrological conditions do not affect its functioning, for example, in areas with an arid climate, it is advisable to carry out structures from non-perforated polymer tapes.

 The surface of the welded tapes can be smooth or embossed to increase the coefficient of adhesion of the soil material to the cell walls.

 To increase the stability of the geocarcass to the action of solar radiation, a light stabilizer, for example carbon black (up to 2 wt.%), Can be added to the material of a flexible polymer tape. In order to improve the appearance - the design of the geocarcass, dyes - pigments can be added to the material. To achieve maximum strength and rigidity of the geocarcass at its lowest cost, wall thickness is selected from the range from 0.5 to 2.0 mm.

 The dimensions of the geocarkas in the extended state are: length from 3 to 12 m, width from 0.5 to 3.0 m, height from 0.05 to 0.3 m, mesh size from 0.1 to 1.0 m, which will allow reduce the number of butt joints between adjacent geoframes and create optimal conditions for compaction of soil material in the cells and thereby increase the reinforcing effect of the structure.

The invention is illustrated by the description and drawings, where:
in FIG. 1 shows a general view of a geocarcass in an extended working condition;
in FIG. 2 - general view of the geocarkas in the folded transport state;
in FIG. 3 is a view A in FIG. 2 (arrangement of pressure points of the weld and perforations in the cell walls);
in FIG. 4 is a section AA in FIG. 3.

The drawings indicate the following notation:
And - the length of the geocarcass in the extended (working) condition, equal to 3-12 m;
And ₀ is the length of the geocarcass in the folded (transport) state, equal to 0.08-0.2 m;
In - the width of the geocarkas in the extended state, equal to 0.5-3.0 m;
In ₀ - the width of the geocarcass when folded, equal to 0.7-4.2 m;
a = b - the width of the geocarcass cell in the extended state, equal to 0.1-1.0 m;
in ₀ - the width of the cell when folded, equal to the distance between the welds of 0.14-1.4 m;
H is the height of the geocarcass equal to 0.05-0.3 m;
b - tape thickness equal to 0.5-2.0 mm;
C is the width of the weld and heat-affected zones;
d _c is the size of the pressure points equal to 2-5 mm;
t is the distance between the pressure points equal to 2-5 mm;
d is the diameter of the perforations;
l is the distance between the perforations.

 The invention is realized by joining polymer tapes 1 with welded linear seams 2 located in a checkerboard pattern (Fig. 1,2). To increase the strength of the structure and to increase the strength of fastening (anchoring) it on the soil surface, the geo-frame can be equipped with connecting elements 3, for example, polymer cables, passed through holes in the walls of the cells and fixed on the first and last tapes. The number of elements 3 is selected in accordance with the characteristics of the surface to be reinforced.

 For the manufacture of tapes, a mixture of high pressure polyethylene and low pressure polyethylene is used in a ratio of 1: 1 to 1: 5 with the addition of a light stabilizer, for example carbon black or pigment, which allows to obtain a high strength of the weld while ensuring the required rigidity of the cell walls. The thickness of the tapes is chosen from 0.5 to 2.0 mm.

Preliminary, the tapes are perforated, having holes 4 with a diameter d (Fig. 3) uniformly in area outside the weld zone, while the distance between the holes (1) is 1 = (1-2) · d. The size of the holes d is determined by the formula depending on the grain size of the soil material. With hole sizes d≤2 mm, the weld zone can also be perforated. Then the tape is cut into a size corresponding to the width of the geoframework when folded B ₀ = 0.7 - 4.5 m (Fig. 2).

Tapes 1 (Fig. 1,2) are welded together by introducing a hot solid (wedge) into the contact zone, bringing the contact surfaces of the welding zone to a viscoplastic flow, removing the hot body from the welding zone and then compressing the tapes with pressure using two clamps . One clamp has a flat contact surface, and the second clamp has a contact surface in the form of two or more rows of protrusions (dots) arranged in a checkerboard pattern. The size of the pressure points 5 (d _c ) and the distance between them (t) is 2-5 mm (Fig. 3.4). When connecting the tapes, the welds 2 are staggered perpendicularly or inclined to the base of the geocarcass (Fig. 1,2). The distance between the welds (at ₀ ) is 0.14-1.4 m (Fig. 2).

Heating contact staggered stitches. The size of the pressure points 5 (d _c ) and the distance between them (t) are 2-5 mm (Fig. 3.4). When connecting the tapes, the welds 2 are staggered perpendicularly or inclined to the base of the geocarcass (Fig. 1,2). The distance between the welds at ₀ is 0.14-1.4 m (Fig. 2).

 The contact surfaces of the welded tapes are heated to the state of viscoplastic flow by also supplying hot air to the weld zone.

 The strength of the resulting weld is at least 50% of the strength of the material of the tape.

 When performing reinforcing work, the geo-frame is stretched to a working state in size A x B (Fig. 1) and installed on a previously prepared soil surface. Then the geo-frame is fixed on the reinforced layer by means of anchors. In a similar way, next to the first geocarcasses are installed close to the first, connecting them with each other and with the lower layer by L-shaped anchors. After that, soil material, gravel, gravel, a sand-gravel mixture or concrete are laid in the cells, depending on the purpose of the object.

 In the process of operation of the object, the geoframe works as follows.

 Soil material - the aggregate of cells perceives compressive loads, and the cell walls perceive tensile (shear) stresses. External loads are distributed evenly over the surface to be strengthened due to the communication between the cell cavities, anchoring and additional connecting elements 3. The optimal size and optimal location of the perforation holes on the cell walls ensures reliable drainage of the reinforced soil layer.

Claims (9)

 1. Geo-frame cellular structure made of flexible polymer tapes mounted on the ribs and interconnected by welds located in a checkerboard pattern, characterized in that the polymer tapes are interconnected by linear seams under pressure when they are compressed with the location of the pressure points in a checkerboard pattern moreover, the size of the pressure points and the distance between them are 2 - 5 mm, and the area of the pressure points is 15 - 30% of the seam area.  2. Geoframework according to claim 1, characterized in that the polymer tape is made of a mixture of high pressure polyethylene and low pressure polyethylene in a ratio of 1: 1 to 1: 5. 3. The geoframe according to claim 1, characterized in that the cell walls are perforated, while the holes are evenly distributed over the cell wall area, and their size (d) is determined from the relation: d = kxd ₃ , where d ₃ is the largest grain size of the soil , and k is the experimentally established coefficient selected from the range: for clay and sandy soils 1 - 4; for crushed stone, gravel, sand and gravel and concrete 0.5 - 1.0, while in any vertical section of the cell wall, the sum of the size of the holes should be no more than 40% of its height.  4. Geoframework according to claim 1, characterized in that the cell walls are made non-perforated.  5. Geoframework according to any one of claims 1 to 4, characterized in that light stabilizers or pigments are introduced into the material of the polymer tape, and its thickness is 0.5 - 2.0 mm.  6. Geoframework according to any one of claims 1 to 5, characterized in that when stretched, its length is 4-12 m, width 0.5-3.0 m, height 0.05-0.3 m, mesh size 0 , 10 - 1.0 m.  7. Geo-frame according to any one of paragraphs.1 to 6, characterized in that the welds are perpendicular or inclined with respect to the base of the geo-frame.  8. Geoframework according to any one of claims 1 to 7, characterized in that the pressure points are formed using two clamps, one of which has a flat contact surface and the other a contact surface in the form of two or more rows of staggered stitches.  9. Geoframework according to any one of claims 1 to 8, characterized in that the cell walls are fixed to each other and to the surface to be strengthened by means of connecting elements passed through holes in the cell walls.

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