KR102085762B1 - Textile geogrid - Google Patents

Abstract

The present invention relates to a textile geogrid. In particular, first threads are formed by forming repetitive loops in multiple layers at a predetermined interval with a high-strength polyester yarn, and second threads are formed by sequentially tying the yarn into loops to form small pillars between one unit of the first threads knitted in multiple layers, and are linked with the first threads to form big pillars at a predetermined interval, wherein, at the predetermined interval, the small pillars and loops of the first and second threads formed in multiple layers are formed of weft portions, and the big pillars of the second threads formed at the predetermined unit are formed of warp portions intersecting each other, forming pores. By alternatively tie knotting the weft portions and the warp portions, the loops of the first and second threads are knitted into a mesh structure having a plurality of unit lattices, which is then processed by a heat treatment, such that the process of forming the sheath with a resin coating solution can be eliminated. Therefore, the textile geogrid has a simple manufacturing process and has a strong structure, and thus can enhance a ground enhancing strength.

Description

Textile Geogrid {TEXTILE GEOGRID}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to textile geogrids, and more particularly, to textile geogrids of knitted fabric structures in which the coating process of the resin coating liquid can be omitted.

In general, geogrid is a reinforcing material used for retaining wall reinforcement, slope reinforcement, fill reinforcement, and asphalt reinforcement in civil works.

Geogrids require high tensile strength and low tensile strain in addition to their properties such as durability and friction.

Geogrids can be divided into plastic geogrids and textile geogrids according to the manufacturing method and materials.

Plastic geogrids are generally manufactured by passing a polymer sheet through an extruder through a roller, punching holes in a grid-like grid, and then stretching them uniaxially or biaxially.

However, these plastic geogrids have a problem in that creep deformation occurs greatly when a load is applied for a long time due to a material property, and tensile strength is lowered, thereby decreasing stability of the reinforcing structure.

Textile geogrid 102 is, as shown in Figure 1, to supply a high strength polyester fiber in the direction of the weft, weft 106, 104, respectively, to form a grid-like fabric, polyvinyl chloride to give shape stability and durability It is prepared by coating the surface with a resin coating liquid such as eyelid, bitumen, acrylic, latex and rubber resin.

The textile geogrid 102 is economical in terms of manufacturing cost and excellent in tensile and creep properties compared to the plastic geogrid, and the product itself has flexibility and is advantageous in terms of packaging, transportation, and construction.

However, the textile geogrid 102 has a disadvantage in that the process of forming the coating of the resin coating liquid is complicated and takes a long time, and since the dioxin component is discharged from the resin coating liquid, it is not environmentally friendly when constructed on the soil.

 In addition, the textile geogrid has a disadvantage in that the warp 106 of the radial rib constituting the lattice during use is widened and the reinforcing effect is lowered, and the construction resistance is lowered as compared with the plastic geogrid.

In the embodiment of the present invention, instead of omitting the process of forming the coating of the resin coating solution, weaving into a knitted fabric formed of a hollow knot, followed by heat treatment, the manufacturing process is simple and the structure is more robust and longer life, frictional force with the ground This increase is to strengthen the reinforcement and to integrate with the soil layer to provide a geogrid without separation phenomenon.

In one or more embodiments of the present invention, in the textile geogrid, a small yarn is formed between a first yarn in which a plurality of layers of repetitive loops are formed of a high strength polyester yarn in a predetermined unit and a unit of the first yarn knitted in the plurality of layers. Small columns of the first chamber and the second chamber formed of the plurality of layers in each of the predetermined units form a second chamber, which is woven in a sequential order and is woven in a loop, and makes a first column and an air column. And the ring is formed by the weft part, the air column of the second chamber formed for each predetermined unit is formed by the inclined portion with the gaps intersected with each other, the loops of the first chamber and the second chamber are knotted to hold the weft portion and the inclined portion To provide a textile geogrid, which is woven into a network having a plurality of unit grids and then heat treated. There.

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Here, the network may be knitted by a knitting machine including a double ratsel machine, a ratsel flange.

Embodiments of the present invention by omitting the process of forming a coating of the resin coating solution is more simple and economical manufacturing process, there is an effect that it is environmentally friendly by not using a resin coating solution.

In addition, after weaving into a knot knot kneading through the heat treatment process the weft and the slope is not loosened, the structure is more solid, holding the soil firmly to prevent the soil out of sediment has the effect of strengthening the reinforcement of the ground.

In addition, the arrangement between the slopes is formed to increase the porosity, so that the soil layer of the upper and lower geogrid is integrated to improve the characteristics as a reinforcing material without causing separation.

1 is a plan view of a textile geogrid according to the prior art.
2 is a block diagram of a knitting method of the textile geogrid according to an embodiment of the present invention.
3 is a plan view of a textile geogrid according to an embodiment of the present invention.
4 is a photographic representation of a textile geogrid according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The textile geogrid 2 according to the embodiment of the present invention is manufactured in a firmly knit fabric formed of a hollow knot, instead of omitting the process of forming a coating of the resin coating solution, and firmly fixed by heat treatment to simplify the manufacturing process. It is made.

2 is a block diagram of a knitting method of a textile geogrid according to an embodiment of the present invention, Figure 3 is a plan view of a textile geogrid according to an embodiment of the present invention, Figure 4 is a textile geogrid according to an embodiment of the present invention Is also a picture.

The textile geogrid 2 according to the embodiment of the present invention shown in FIGS. 2 to 4 is knitted into a network having a unit grid 10 by weaving the weft portion 12 and the inclined portion 14 by a tie knot. It is constructed.

The textile geogrid 2 according to the embodiment of the present invention can be knitted using a knitting machine including a double ratsel machine and a ratsel flange.

As shown in FIG. 2, the weft portion 12 and the inclined portion 14 of the textile geogrid 2 continuously form a loop C1 and are knitted up and down and the first yarn 4 and the small pillar P2. And the second chamber 6, which is made of the air column P3 and the rings C2 and C3, and is woven with the first yarn 4 and the hold-up knot.

The yarns 4 and 6 used in the textile geogrid 2 according to the embodiment of the present invention may be formed of a high strength polyester yarn. When the textile geogrid (2) is formed of a high strength polyester yarn, there is an advantage that the structure is tough and robust.

Meanwhile, the textile geogrid 2 is knitted into a network having a unit grid 10. In order to form the unit grid 10, the first chamber 4 and the second chamber 6 have a repetitive pattern for each unit. To form.

The first yarn 4 of the textile geogrid 2 may be knitted up and down while continuously forming the hook C1 of the hold-up knot, and may be knitted by forming a plurality of layers in a predetermined unit.

The second chamber 6 is knitted by making small pillars P2 and rings C2 and atmospheric columns P3 and rings C3 between the first chambers 4 every predetermined unit. More specifically, the second chamber 6 forms a small pillar P2 between the first chamber 4 of the plurality of layers of one unit and is interwoven with the ring C2 in the first chamber 4. The first chamber 4 and the air column P3 of the upper and lower units are made for each unit, and the first chamber 4 is woven with a ring C3.

In the embodiment of the present invention, the small pillar P2 of the second chamber 6 is formed for each of the first chambers 4 of two floors in one unit, and the atmospheric column P3 of the second chamber 6 is the vertical unit. And each of the first chambers 4 of each of the four layers.

At this time, the small pillar P2 and the ring C2 of the first chamber 4 and the second chamber 6 formed in a plurality of layers every predetermined unit are formed of the weft part 12 woven in a chain shape. The air column P3 of the second chamber 6 formed in each unit and two units is formed by the inclined portion 14 in which the spaces R1 and R2 are staggered from each other.

The ring C3 of the first chamber 4 and the second chamber 6 is formed by a webbing knot of the weft portion 12 and the inclined portion 14. Tighten knot to hold the position so that the weft portion 12 and the inclined portion 14 does not push each other, there is an effect to firm the network tissue is not loosened. In addition, there is an advantage in improving the construction resistance, such as holding the soil firmly in use and preventing soil from escaping during soiling.

In the example of the present invention, the yarns forming the small pillars P2, the atmospheric pillars P3, and the rings C2 and C3 have been described as being limited to one type of the second chamber 6, but as two modifications, two types It can form in multiple types, such as three types and four types.

In addition, in the example of the present invention, the small pillar P2 of the second chamber 6 is formed for each of the first chambers 4 of two layers in one unit, and the atmospheric column P3 of the second chamber 6 is Although it is formed for every 1st chamber 4 of an up-and-down unit and four floors, the space | interval which makes small pillar P2 and atmospheric pillar P3 can be adjusted freely.

As shown in FIGS. 3 and 4, the weft portion 12 of the textile geogrid 2 is knitted to form continuously in a chain form. In addition, since the inclined portion 14 is knitted with the air column P3 of the second chamber 6 staggered vertically for each unit lattice 10 of the network structure, to form the void R1 and the void R2, the net Not only do they make the organization robust, they also increase the porosity.

Increasing the porosity of the network structure has the effect of improving the characteristics as a reinforcing material that does not cause the separation phenomenon due to the integration of the soil layer of the upper and lower textile geogrid (2).

In the example of the present invention, the inclined portion 14 is alternately explained so that the voids R1 and R2 are formed. However, the inclined portion 14 also has a hollow knot such that the chain shape is continuously formed like the weft portion 12. You can weave and knit.

The textile geogrid 2 according to the embodiment of the present invention manufactured by the above method is subjected to heat treatment at 130 to 180 ° C. in a tenter.

The textile geogrid 2 according to the embodiment of the present invention is firmly fixed while undergoing heat treatment. The heat treatment can control the temperature within 130 ~ 180 ℃ to control the heat treatment strength.

If the temperature of the tenter does not reach the lower limit within the above range, the texture is soft and there is no strength, and thus the construction resistance of the textile geogrid (2) is lowered. .

While undergoing heat treatment, the hollow knot portion of the textile geogrid 2 is further protruded, thereby increasing the frictional force with the ground, thereby increasing the reinforcement of the ground.

By the above configuration, the textile geogrid 2 according to the embodiment of the present invention can variously adjust the size and shape of the unit grid 10. In addition, the weft portion 12 and the inclined portion 14 are not pushed without coating with a resin coating liquid in order to give shape stability and durability, it is possible to manufacture a textile geogrid (2) sufficiently strong, economical and excellent construction resistance There is this.

Although one embodiment of the present invention has been described above, the present invention is not limited to the above embodiment, and is easily changed by those skilled in the art to which the present invention pertains. It includes all changes to the extent deemed to

2: Geogrid 4: Room 1
6: 2nd chamber P2: Small pillar
P3: atmospheric column C1, C2, C3: ring
10 unit grid 12 weft
14: inclined portion R1, R2: void

Claims (4)

For the textile geogrid,
The first yarn is formed of a high strength polyester yarn in a plurality of layers per repetitive unit and the first yarn of one unit knitted in the plural layers is sequentially intertwined and looped, and the first unit is fixed for each unit. To form a thread and atmospheric column, to form a second thread,
Small pillars and rings of the first chamber and the second chamber formed of the plurality of layers in each of the predetermined units are formed of a weft thread, and atmospheric pillars of the second chamber formed of the predetermined units are formed of an inclined portion having a gap therebetween. The textile geogrid of the first yarn and the second yarn is woven by weaving the weft thread and the inclined portion with a hollow knot, which is knitted into a network having a plurality of unit grids and then subjected to heat treatment. delete delete The method of claim 1,
The network is a textile geogrid, characterized in that knitting with a knitting machine comprising a double ratsel machine, a ratsel flange.

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