EA017604B1 - Flexible grating (lattice) for construction and fencing, and building element based thereon - Google Patents

Abstract

The invention relates to construction and mainly concerns the devices that strengthens road pavement, especially on soft ground. It can also be used as a special reinforcing or enclosing element in other different building structures. A flexible grid (lattice) 1 (fig. 2) for construction and fencing is precurled into a roll. It contains orthogonally intersecting strands 3 and 4 from an extruded oriented polyolefin-based material to form windows 5 and knots 6 with thickenings 7 at the intersection of strands 3 and 4. Configuration of the windows is formed by curved lines 8 and 9 of the surfaces of strands and conjugations 10 of these lines. Cross-sections of the strands are of double T-iron shape and cross-section of bosses is drop-shaped. The reinforcing properties of the flexible grid (lattice) 1 are manifested in a construction element, consisting of a support cloth and a flexible grid (lattice) 1 laid thereon. Structural features of windows 5 and strands 3 and 4 of the flexible grid (lattice) 1 with said rounded forms which increase a support area of the flexible grid (lattice) 1 provide better retention from displacement of building structure sections in transverse and longitudinal directions. Draining properties of such flexible grid (lattice) 1 are also improved by reducing the pressure drop and by the forced diversion of water beyond a building structure through unique paths formed by strands 3 and 4 having double T iron shape and drop-shaped units with thickenings 7. During the construction of fences, where a flexible grid (lattice) is used, for example, temporary fences (not shown) the stability of such constructions is increased due to the above-mentioned reduction of hydraulic resistance of flexible grid (lattice) against wind gusts. According to the invention the use of a flexible grid (lattice) provides better working conditions for a labor by eliminating sharp edges and forming smooth transitions of its elements.

Description

The invention relates to the field of construction and relates mainly to devices that strengthen the pavement, especially on soft soils. It can also be used as a special reinforcing or enclosing element in various other building structures.

Known flexible lattice (mesh) for construction work and fencing [1] with the possibility of forming it into a roll containing orthogonally intersecting strands of extruded material with the formation of rectangular windows and bulges at the intersection of the strands. In this case, the strands are made of a material based on a polyolefin or a mixture of polyolefins.

The disadvantage of the analogue [1] is that the windows of the strands are rectangular, which is why the width of the strands is insufficient to strengthen the design of a flexible lattice (mesh). In addition, there are no elements in the grid to increase the adhesion of the flexible lattice (grid) with its supporting base, which reduces the efficiency and versatility of its use in building structures.

Known more efficient in operation and more versatile in its application, a flexible lattice (grid) for construction work and fencing [2], adopted as a prototype of a utility model. It has the ability to form into a roll and contains orthogonally intersecting strands of extruded and oriented polyolefin material with the formation of windows and nodes with thickenings at the intersection of the strands. The configuration of the windows is formed by straight lines of the surfaces of the strands and the conjugations of these lines through the oblique straight lines, while the cross sections of the strands and bulges are made in a rectangular shape.

However, the rectangularity and angularity of the shapes of the windows and strands of such a flexible lattice (mesh) contribute to increased hydraulic resistance during the removal of moisture from the building structure in which it is used, which reduces the drainage properties of the flexible lattice (mesh). In addition, this geometric drawback to some extent negatively affects the convenience of moving a flexible lattice (mesh) by a person who can injure his hands on its sharp edges.

A known building element [1], consisting of a support sheet and a geogrid (grid) laid on it, containing orthogonally intersecting strands of extruded material with the formation of rectangular windows and bulges at the intersection of the strands. In this case, the strands are made of a material based on a polyolefin or a mixture of polyolefins.

In this design of the building element, a flexible lattice (grid) does not contain elements to increase adhesion to the supporting canvas, which reduces the efficiency and versatility of the use of the building element in structures.

Known adopted for the prototype, a more efficient and versatile building element [2], consisting of a supporting canvas and a geogrid (grid) laid on it containing orthogonally intersecting strands of extruded and oriented polyolefin material with the formation of windows and nodes with thickenings at the intersection of the strands. The configuration of the windows is formed by straight lines of the surfaces of the strands and the conjugations of these lines through the oblique straight lines, while the cross sections of the strands and bulges are made in a rectangular shape.

The disadvantage of the prototype [2] is the increased hydraulic resistance during the removal of moisture from the building element, which reduces the drainage properties of the building in which this element is used. This is due to the strict rectangularity and angularity of the shapes of the windows and strands of the flexible lattice (mesh) of the building element.

Therefore, the objectives of the invention are to increase the drainage properties of a flexible lattice (mesh) by reducing its hydraulic resistance when used in building or protective structures, increasing the convenience of its transfer by a person by eliminating sharp edges and reducing the hydraulic resistance of a building element based on a flexible lattice (mesh) due to reducing the straightness of the forms of its elements.

The tasks are solved in that the flexible lattice (mesh) for construction work and fencing with the possibility of assembling it into a roll containing orthogonally intersecting strands of extruded and oriented polyolefin material with the formation of windows and nodes with thickenings at the intersection of the strands, has distinctive signs: configuration the windows are formed by arched lines of the surfaces of the strands and the conjugations of these lines, while the cross-sections of the strands are made in the I-beam shape, and the cross-section of the eny - teardrop shape.

The formation of the window configuration by arched lines of the strand surfaces and the conjugations of these lines is aimed at eliminating sharp edges and reducing the straightness of the shapes of the elements of such a flexible lattice (mesh), which will contribute to the technical result stated above to increase the drainage properties of the flexible lattice (mesh) and the convenience of its movement.

The implementation of the cross-sections of the strands of the I-shaped, as well as the execution of the cross-section of the thickenings - drop-shaped, will further increase the drainage properties of the flexible lattice (mesh). This will happen because, firstly, peculiar paths are formed to ensure during operation of the flexible lattice (mesh) the fast flow of water streams held within the surface of the strands and, secondly, the droplet-shaped form of nodal thickenings will have less resistance to such a flow encountered in the path of said trickles.

- 1 017604

Examples of the execution of elements of a flexible lattice (grid):

the thickness of the strands is 1-2.5 mm;

in the cross section, the droplet-shaped form of thickenings is characterized by a width of 6-11 mm and a thickness of 3-6 mm;

in a longitudinal section, the droplet-shaped form of thickenings is characterized by a width of 6-12 mm and a thickness of 3-8 mm;

the I-beam shape of the strands has a mating radius of its wall and shelves not exceeding 1 mm; the width of the orthogonally intersecting strands is different;

the width of the strands oriented in one direction is less than the width of the strands oriented in the other direction by 1.1-1.25 times;

the arcuate lines of the surface of the strands are formed by a radius of 140-150 mm; the polyolefin material includes light stabilizers;

carbon black was used as a light stabilizer;

the width of the flexible lattice (mesh) in the roll (2) is not more than 5 m, and its length is not more than 50 m, while its 1 m ² has a mass of 50-90 g.

The problem is also solved by the fact that the building element, consisting of a supporting canvas and a geogrid (grid) laid on it, has its limiting and distinctive features described above.

The essence of the utility model is illustrated by illustrations.

In FIG. 1 shows a general view of a flexible grid (grid) in a roll.

In FIG. 2 is a view A of a fragment of a flexible lattice (mesh) of FIG. one.

In FIG. 3-6 are sections of the nodal elements of the flexible lattice (mesh) and its strands according to FIG. 2.

In FIG. 7 is a general diagram of an example of using a building element with a flexible grid (grid) in a building structure.

In FIG. 8, 9 are fragments of such an application according to FIG. 7.

Flexible grid (mesh) 1 for construction work and fences pre-twisted into a roll

2. As an example: the width 8 of the flexible lattice (mesh) in roll 2 is not more than 5 m, and its length b is not more than 50 m, while its 1 m ² has a mass of 50-90 g.

Flexible lattice (mesh) 1 contains orthogonally intersecting strands 3 and 4 of extruded oriented polyolefin material with the formation of windows 5 and nodes 6 with bulges 7 at the intersection of strands 3 and 4.

It is desirable to include light stabilizers in the polyolefin material. It is recommended to use carbon black as a light stabilizer.

The configuration of the windows 5 is formed by arched lines 8 and 9 of the surfaces of the strands 3 and 4 and the interfaces 10 of these lines. Cross sections of strands 3 and 4 are made in the form of an I-beam (FIGS. 5 and 6), and the cross section of thickenings 7 is drop-shaped (FIGS. 3 and 4).

The following sizes and ratios of elements of a flexible lattice (mesh) are recommended.

The thickness 1 (Fig. 3-6) of strands 3 and 4 is 1-2.5 mm. In the cross section (Fig. 3), the droplet-shaped shape of the bulges 7 is characterized by a width a1 of 6-11 mm and a thickness L of 3-6 mm.

In a longitudinal section (Fig. 4), the droplet-shaped shape of the bulges 7 is characterized by a width a2 of 6-12 mm and a thickness of b2 of 3-8 mm. The I-beam shape (Fig. 5 and 6) of strands 1 and 2 has a mating radius (K3) of its wall and shelves not exceeding 1 mm.

It is assumed that the widths c and e of the orthogonally intersecting strands 3 and 4 can be different from each other. The width of the strands 4 oriented in one direction (Fig. 5) will be less than the width e of the strands 3 oriented in the other direction (Fig. 6), 1.1-1.25 times. The arcuate lines 8, 9 (Fig. 2) of the surface of the strands 3, 4 are formed by a radius K1 of 140-150 mm. These lines are smoothly conjugated along the radius K2.

Such a flexible lattice (mesh) can be used as a special reinforcing or enclosing element together with a supporting element in various building structures. As an example (Fig. 7 higher -9), such an application is shown in the construction of roads of the highest technical category.

In this case, the soil of the base 11 covers the base fabric made of geotextile 12, covered with a lower layer of sand 13. One piece of flexible lattice (mesh) 1 is laid on it, which constitutes a building element with the supporting canvas, on top of which the lower layer of granite crushed stone is poured 14. On this layer the upper five-centimeter protective layer of sand 15 is laid, in which the second piece of flexible grating (grid) 1 is located, with a second layer of granite crushed stone 16 being filled, on which layers of coarse and fine-grained asphalt concrete 17, 18 are laid. Slopes 19 of the embankment are on the roads reinforced by grass sowing. In both cases, backfill with crushed stone (14, 16) of the flexible grating (mesh), the lower fractions of this crushed stone (Fig. 9) are reliably locked in the windows of the flexible grating (mesh) 1, increasing the stability of the layers of pavement.

The reinforcing properties of the flexible lattice (mesh) 1 are manifested in the building structure in that the features of the windows 5 and strands 3 and 4 of the flexible lattice (mesh) 1 with the said rounded

- 2 017604 forms that increase the supporting area of the flexible lattice (mesh) 1, allow better to keep layers of the building structure from being displaced in the transverse and longitudinal directions. The draining properties of such a flexible lattice (mesh) 1 are also improved by reducing its hydraulic resistance and by forcibly draining water outside the building structure along peculiar paths formed by the I-beam form of strands 3 and 4 (Fig. 5, 6) and the drop-shaped form of nodes 6 with thickenings 7.

In the construction of fencing, where a flexible grating (mesh) 1 is used, for example, temporary fences (not shown), the stability of such structures is improved due to the aforementioned reduction in hydraulic resistance of the flexible grating (mesh) to wind gusts.

In all cases, the use of a flexible lattice (mesh) 1 according to a utility model increases the convenience of its movement by a person by eliminating sharp edges and the presence of smooth transitions of elements of its shape.

Ultimately, the efficiency of using such a building element based on a flexible lattice (mesh) for various building structures is increased.

Information sources.

1. Application I8 No. 20090214821, IPC В32В 3/10, В29С 55/14, С09К 3/00; Announced February 11, 2009; published 08/09/2009.

2. Certificate VI No. 83253, IPC Ό04Η 3/00, Β29Ό 28/00, Е04Н 17/00; priority of March 20, 2007, published May 27, 2009 (prototype).

Claims (12)

CLAIM 1. Roll-up flexible grid for construction works and fences containing orthogonally intersecting strands (3 and 4) of extruded oriented polyolefin material with the formation of windows (5) and nodes (6) with thickenings (7) of drop-shaped form at the intersection of strands ( 3 and 4), while the configuration of the windows (5) is formed by arcuate lines (8 and 9) of the surfaces of the strands (3 and 4) and conjugations (10) of these lines, characterized in that the cross sections of the strands (3 and 4) are I-shaped . 2. Grate according to claim 1, characterized in that the thickness (1) of the strands (3 and 4) is 1-2.5 mm. 3. Grate according to claim 1, characterized in that in the cross section the drop-like shape of the bulges (7) has a width (a1) of 6-11 mm and a height (S) of 3-6 mm. 4. Grate according to claim 1, characterized in that in the longitudinal section the drop-like shape of the bulges (7) has a width (a2) 6-12 mm and a height (b2) 3-8 mm. 5. Grate according to claim 1, characterized in that the I-form shape of the strands (1 and 2) has a pairing radius (B3) of its walls and shelves, not exceeding 1 mm. 6. The lattice according to claim 1, characterized in that the width of the orthogonally intersecting strands (3 and 4) is different among themselves. 7. The lattice according to claim 6, characterized in that the width of the strands oriented in one direction (s) is less than the width of the strands oriented in the other direction (b) 1.1-1.25 times. 8. Grate according to claim 6, characterized in that the arcuate lines (8, 9) of the surface of the strands (3, 4) are formed by a radius (KG) of 140-150 mm. 9. The lattice according to claim 1, characterized in that the polyolefin material includes light stabilizers. 10. Grate according to claim 9, characterized in that carbon black is used as a light stabilizer. 11. Grate according to claim 1, characterized in that its width (8) in a roll (2) is no more than 5 m, and its length (b) is no more than 50 m, while its 1 m ² has a mass of 50-90 g . 12. A construction element containing a support web on which a flexible grid is laid according to claims 1-10.