RU2803491C1 - Woven geotextile - Google Patents

Abstract

FIELD: building materials.

SUBSTANCE: invention relates to building materials used in the construction of reinforced soil structures of roads, foundations and other earthworks. The technical result is an increase in the mechanical strength of the textile while providing the optimal area of the aero-transparent surface in places of bends, kinks and subsidence without significant changes in the permeability of the geotextile in other places. Geotextile is made by plain weave of warp threads from non-fibrillated film threads and weft threads from fibrillated film threads with optimal sizes of film threads in the textile.

EFFECT: increase in the mechanical strength.

1 cl, 1 dwg

Description

The claimed invention relates to building materials used in the construction of reinforced soil structures of roads, earthworks, foundations, etc., including for separating structural layers, for erosion protection, for retaining soil, as protective layers, etc.

An analogue of the claimed invention is a glass reinforcing mesh of leno weave of warp and weft complex threads with a cell size from 2.5x2.5 mm to 3.4x3.4 mm (see patent RU No. 53289, IPC D03D 15/00, 2006 ). The essential features of the analogue “interweaving of warp and weft threads” coincide with the essential features of the claimed invention.

The disadvantage of the analogue is the very large area of the aerotransparent surface, which makes it almost impossible to separate layers, retain soil, use it as a protective layer, etc.

Another analogue of the claimed invention is a mesh for reinforcing road surfaces, containing bundles of warp threads and bundles of weft threads of plain weave, as well as non-woven layers (see patent RU No. 94233, IPC D03D 15/00, 2010). The essential features of the analogue “warp thread, weft thread, plain weave” coincide with the essential features of the claimed invention.

The disadvantage of the analogue is also the large area of the aerotransparent surface of the woven mesh, which requires the mandatory use of additional non-woven layers for effective separation, soil retention, etc. This significantly increases the cost of the product, complicates its production and limits its scope of application.

The closest analogue of the claimed invention is frame fabric made of plain, twill or satin weave of warp and weft threads from polypropylene fibrillated threads of the same or different linear density (see patent RU No. 2177515, IPC D03D 15/00, 2001). The essential features of the closest analogue “plain weave, warp threads, weft threads made of fibrillated film threads” coincide with the essential features of the claimed invention.

The disadvantage of the closest analogue is the reduced mechanical strength of the fabric due to the use of fibrillated threads both as warp and weft threads, a significant increase in the area of the aerotransparent surface under any tensile load effects (and not just in places of bends, kinks and subsidence), which reduces the separation and the holding capacity of the geotextile. In addition, there are no optimal ratios between the sizes of longitudinal delaminations and connections between the fibrils forming the film thread, which also does not allow achieving the optimal area of the aerotransparent surface in places of bends, kinks and subsidence of the geofabric.

The problem to be solved by the claimed invention is to increase the mechanical strength of the web while ensuring the optimal area of the aerotransparent surface in places of bends, kinks and subsidence, and without significant changes in the permeability of the geofabric in other places, due to the combination of fibrillated film peelings with optimal sizes threads and non-fibrillated film threads in the fabric.

To achieve the specified technical result in a woven geo-fabric made by plain weave of warp threads and weft threads from fibrillated film threads, the warp threads are made of non-fibrillated film threads, the widths of the threads are selected from the ratio: H ₁ = 1.4÷1.6 H ₂ , where H ₁ is the width of the fibrillated weft threads, H ₂ is the width of the non-fibrillated warp threads, and the dimensions of the longitudinal delaminations and connections between the fibrils of the weft threads are selected from the ratio: L ₁ =0.4÷0.5L ₂ ; where L ₁ is the length of the bond between fibrils, L ₂ is the length of the separation between fibrils.

Essential features of the claimed invention “the main threads are made of non-fibrillated film threads, the width of the threads is selected from the ratio H ₁ = 1.4÷1.6 H ₂ , the dimensions of the longitudinal delaminations and connections between the fibrils of the weft threads are selected from the ratio L ₁ = 0.4÷ 0.5L ₂ "are distinctive from the characteristics of the closest analogue.

The drawing shows a section of fibrillated weft thread in a state stretched across its width (in this case, the film thread acquires a cellular structure). When not stretched across its width, the thread looks like a monolith.

Woven geo-fabric is made of plain weave of tape threads, for example from polypropylene, polyisopropylene or other polyolefins. The warp threads are not fibrillated, the weft threads are fibrillated, and the width of the weft threads is 1.4÷1.6 times greater than the width of the warp threads. The length of the delaminations of fibrils of weft threads is 2–2.5 times greater than the length of the bonds between fibrils.

A specific example of the claimed invention is a woven geo-fabric made from polypropylene film threads in a plain weave. The warp threads are not fibrillated and have a width of ≈2 mm; The weft threads are fibrillated and have a width of ≈3 mm. The length of bonds between fibrils is ≈4.5 mm, the length of separations between fibrils is ≈10.5 mm.

Making the main threads of the geofabric non-fibrillated increases the mechanical strength of the geofabric to deforming influences and provides a small area of aerotransparent surface in parts of the geofabric that are not subject to tensile effects (bending, bending, subsidence). As a result, the separating and holding capacity of the geotextile increases. At the same time, in places of bends, kinks and subsidence, where the geofabric is subjected to tensile loads, the area of the aerotransparent surface increases, which makes it possible to reduce and even eliminate additional hydrostatic pressure and other loads on the geofabric. As a result, the area of the aerotransparent surface of the geotextile increases only in those places where it is necessary.

Claims (1)

Geo-fabric woven, made by plain weave of warp threads and weft threads from fibrillated film threads, characterized in that the warp threads are made of non-fibrillated film threads, the widths of the threads are selected from the ratio: H ₁ = 1.4÷1.6H ₂ , where H ₁ - the width of the fibrillated weft threads, H ₂ is the width of the non-fibrillated warp threads, and the dimensions of the longitudinal delaminations and bonds between the fibrils of the weft threads are selected from the ratio: L ₁ =0.4÷0.5L ₂ , where L ₁ is the length of the bond between the fibrils, L ₂ - length of separation between fibrils.

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