KR101109607B1 - Polymer strap for textile geogrid and methods for manufacturing thereof - Google Patents

Abstract

PURPOSE: A polymer strap for a textile geogrid is provided to improve tensile strength and elongation by attaching reinforcing fabric on the upper side of filaments. CONSTITUTION: A polymer strap for a textile geogrid comprises a yarn filament(10), and a strength-reinforcing fabric. The yarn filament is used as a weft and a warp, and comprises yarns with the yarn strength of 8.5g/denier or more. The strength-reinforcing fabric is attached to the one side of a rib, which is formed by the yarn filament. The strength-reinforcing fabric is sewn in order to have the constant width on the yarn filament. The strength-reinforcing fabric forms a sewing part. A net structure circular knitted fabric or a warp knitted fabric is used as the strength-reinforcing fabric. The width of the sewing part is proportional to the width of the rib. The distance between the sewing parts is 10-20mm.

Description

Polymer strap for textile geogrid and methods for manufacturing

The present invention relates to a polymer strip for textile geogrid and a method of manufacturing the same, and more particularly, a plurality of yarns made of yarn as warp or weft yarn in forming a geogrid used for reinforcing soil when performing civil engineering work. The present invention relates to a polymer strip for textile geogrid, and a method of manufacturing the same, by adding a mesh-shaped circular knit or warp knitted fabric to one side of the filament and improving various physical properties such as tensile strength, elongation and increased frictional force.

Recently, geosynthetics is applied to soil-related fields such as soft ground reinforcement, retaining wall protection, drainage, slope stability. Such geosynthetic fibers have been used a lot since they are easy to use, easy to transport, excellent in functionality and physical properties, and economically advantageous compared to poor construction such as gravel, sand, and giant, which have been conventionally used.

Geosynthetic fiber, a synthetic polymer product that was developed and applied in the early 1960s, has excellent durability, constructability, and economic feasibility, thus preparing new electricity in civil engineering. However, geotextile products such as woven and nonwoven fabrics, which have been used as reinforcement materials for various civil structures until the 1970s, have limitations in terms of tensile strength, tensile modulus, creep, etc. The application of has been limited. This problem was solved by the emergence of geogrid, a high-strength geotextile product developed in the United Kingdom in 1979. Since then, the geogrid has been rapidly developed as it is used for various purposes in various civil works around the world.

In Korea, the use of geogrids has been sought since the 1990s, and in 1993, geogrids were first applied to the design of reinforced earth retaining walls.In the late 1990s, the use of geogrids has become active as domestically produced soft-bonded geogrids have been coated. (Korea Institute of Construction Technology, 1999).

Geogrid is widely used as a reinforcement material in various civil works such as soft ground reinforcement, fill slope reinforcement, reinforcement soil retaining wall, but for this purpose, geogrid reinforcement applied to the site for a long time is not so long. There is still uncertainty regarding durability. The degree of degradation of the engineering properties (especially tensile strength) of geogrid stiffeners over time may vary depending on the material and shape of the geogrid, the environment around which the geogrid is laid, and external loads.

In addition, the damage of geogrids that may occur while laying and filling the backfill soil on top of the geogrid reinforcement when constructing the reinforcement soil structure may also have a significant impact on the long-term stability of the reinforcement soil structure. Particularly in Korea, granite weathering soil (mountain soil), which is widely used as backfilling soil, contains a lot of stones with large particle size, and it is difficult to supply high quality earth and earth and have a great amount of backfilling soil during site construction. As a result, soil containing a large amount of stone with a particle size of more than 19 mm (backfill selection criteria) is used, and there is a great concern for damage to the geogrid reinforcement.

Geotextiles can be broadly classified into extrusion moldings, geotextiles, non-woven fabrics. In the case of nonwoven fabrics, those manufactured by spunbonding are suitable. In particular, geotextiles include geogrids and geomats. These are mainly manufactured by weaving polyester yarns and then polyvinyl chloride (PVC) coating.

Geogrid has a lattice structure and improves the cohesion of soil by mutual affinity with soil in the ground, and prevents the collapse and settlement of the ground, and is used for soft ground reinforcement, retaining wall protection, and slope reinforcement.

Such a geogrid is a material with a lattice in the direction of warp and weft (primary and secondary ribs), which can vary the composition, cross-connection, or bonding method of the strip, and is used as structural reinforcement in the direction of load. do. Geogrids are made of plastic (sheet) geogrids and textile (fabric) geogrids.Plastic geogrids are manufactured by drilling holes in sheets of high-density polyethylene or polypropylene obtained through an extruder, and then uniaxially or biaxially stretching them. Is prepared by laminating or weaving a lattice into a resin such as polyvinyl chloride, acrylic, latex, rubber, and bitumen.

In particular, the textile geogrid is known to be relatively advantageous in terms of packaging, transportation, and construction because it is more economical in terms of manufacturing cost and more flexible than the plastic geogrid.

However, despite these advantages, the textile geogrid has some problems in its manufacturing process.

First, the process of knitting and knitting the synthetic resin using synthetic fibers is separated, so the problem is that the lattice shape of the fabric should be disturbed or limited to a certain amount of volume when transferring the knitted fabric to the coating process. In the case of coating work, there is a problem in that the economical efficiency is lowered because the loss (loss) generated at the start and end of each coating lot (lot) leads to a decrease in the production yield, which leads to a cost increase and a hassle of work.

In addition, since the component is a synthetic fiber, the original physical properties, i.e., modulus or elongation, are changed by the high temperature thermal history received in the coating process, and especially in the case of elongation, a significant rise in relation to heat shrinkage is achieved. There are problems such as being beyond the limiting elongation (usually less than 15%), or the tensile behavior is changed during tensile testing of the product, leading to a decrease in strength utilization.

Problems that occur in manufacturing a geogrid using conventional yarns are as follows.

When using low shrinkage yarns, the shrinkage stress is low, so the shrinkage stress is low, so there is little problem in the process of PVC coating.However, due to the low strength, the amount of yarn used is needed to express the required strength of the product. This is high, the problem of weaving is difficult due to the increase in the number of yarns used, which is difficult to express a certain level of strength. In addition, low shrinkage yarns have high elongation, making it difficult to express high-modulus (elastic modulus, which represents the ratio of stress and strain) in geogrid products.

If high strength yarns are used, the strength and modulus of the yarns are not a big problem.However, due to the high heat shrinkage force in the PVC coating process, the coating loss due to shrinkage is high, resulting in high manufacturing costs, and a high temperature PVC coating process. Due to the shrinkage force at the tenter pin or the grip may cause a process problem that the coating is impossible due to separation from the grip, the higher the shrinkage rate is more severe this tendency. In addition, even if there is no problem in the process, the physical properties of the yarn is severely changed due to the high shrinkage during the heat treatment, in particular, the elongation is greatly increased, the geogrid product is difficult to express the characteristics of high modulus.

Such products according to the prior art have a disadvantage in that the fabrication method and apparatus are very complicated and the tensile strength of the product is very weak in terms of the characteristics of the product, so that the original functionality of the geogrid serving as a reinforcing core material cannot be sufficiently achieved.

Accordingly, the present invention has been made to solve the above-mentioned conventional problems,

As a reinforcement core used to construct a textile geogrid reinforcement by sewing and fixing a reinforcement fabric such as mesh circular annular or warp knitted fabric to one side of the filament part made of filament which is a bundle of synthetic fiber yarn. The problem is to provide a polymer strip with improved physical properties such as tensile strength, frictional force, and elongation so as to be sufficient.

The polymer strip for textile geogrid of the present invention that solved the above problems is listed in the polymer strip for textile geogrid, the yarn filament and the yarn filament made of a yarn having a yarn strength of 8.5g / denier or more, listed as a plurality or more used as warp or weft. It is added to one side of the rib formed by, and consists of a strength reinforcement fabric made of a yarn having a certain strength, the strength reinforcing fabric is made by sewing to have a predetermined width in the yarn filament to form a sewing portion.

Here, the reinforcing fabric is characterized in that the mesh circular knit fabric or warp knitted fabric.

Here, the width of the sewing portion is proportional to the width of the number of the number of yarn filaments, the distance between the sewing portion and the sewing portion is characterized in that 10 ~ 20mm.

Here, the width of the reinforcement fabric of the strength reinforcing fabric forming the sewing portion is the same as the width of the rib, the width of the strength reinforcing fabric located between the sewing portion and the sewing portion compared to the width of the rib. It is characterized in that the relatively narrow width is formed.

In the present invention, the step of supplying the yarn to form a bundle filament, the filament arranged to form a predetermined width in the horizontal direction to supply; Supplying a reinforcing fabric to be positioned on an upper surface of the supplied filament; And a sewing step of fixing and fixing the filament and the reinforcing fabric to provide a method of manufacturing a polymer strip for textile geogrid.

Here, the strip formed after the sewing step is applied by impregnating the PVC resin solution, characterized in that it further comprises the step of forming the applied resin solution by drying.

The textile strip for textile geogrid provided according to the present invention lists the filaments of the yarn bundle form having a plurality of properties such as a plurality of constant tensile strength, elongation, and improve the tensile force by forming a reinforcing fabric to the top surface of the listed filaments, Shear load transfer, contact reinforcement and frictional force increase effect can be obtained. When manufacturing geogrid reinforcement used in building or civil engineering using the strip, the reinforcing effect is maximized after various properties and construction of geogrid reinforcement. You can get it.

1 is a block diagram showing an example of the polymer strip for textile geogrid of the present invention.
Figure 2 is a photograph illustrating a polymer strip for textile geogrid of the present invention.
Figure 3 is a partial configuration showing an example of a geogrid reinforcement produced using the polymer strip for textile geogrid of the present invention.
Figure 4 is a manufacturing process showing a manufacturing example of the polymer strip for textile geogrid of the present invention.

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

1 is a block diagram showing an example of the polymer strip for textile geogrid of the present invention, Figure 2 is a photograph showing an example of the polymer strip for textile geogrid of the present invention, Figure 3 is a polymer strip for textile geogrid of the present invention Figure 4 is a partial configuration showing an example of a geogrid reinforcing material manufactured using, Figure 4 is a manufacturing process diagram showing an example of manufacturing a polymer strip for textile geogrid of the present invention, Figure 5 is an extract of the main part of the manufacturing process diagram of Figure 4 This is an example.

In the following description of the present invention, the yarn filament portion will be described by rebrazing.

As shown in Figure 1, the polymer strip for textile geogrid 100 in accordance with the present invention is listed as a plurality or more used as warp or weft yarn, yarn filament portion 110 made of yarn having a yarn strength of 8.5g / denier or more ) And the one side of the rib formed by the yarn filament portion 110, and is composed of a strength reinforcing fabric 120 is served as a yarn having a certain strength, the strength reinforcing fabric 120 is a yarn filament It is made by sewing to have a predetermined width to form a sewing unit 130.

According to the present invention, the reinforcing fabric may be used in any form and any material as long as it can improve various physical properties. Preferably, it is used as a geotextile and is used for manufacturing a geogrid such as a certain strength, that is, tensile strength and elongation. It is advisable to use mesh circular knit or warp knitted fabrics that are woven with yarns that have more than the standard properties that can be used.

According to the invention, the width of the sewing portion is proportional to the width of the number of the number of the yarn filament, the distance between the sewing portion and the sewing portion is preferably sewn and fixed to have a distance of 10 ~ 20mm.

According to the present invention, the strength reinforcing fabric is preferably so that the width of the sewing portion and the width of the fabric located between the sewing portion and the sewing portion is formed different from each other. To this end, when the strength reinforcing fabric is sewn on the ribs, the end of the reinforcing fabric is tensioned so that the non-sewable part is shrunk to a certain width by shrinkage.

In addition, according to the present invention, by supplying a yarn to form a bundle of filaments, the filaments are arranged so as to form a predetermined width in the horizontal direction; Supplying a reinforcing fabric to be positioned on an upper surface of the supplied filament; And a sewing step of bonding and fixing the filament and the reinforcing fabric. Here, the strip formed after the sewing step may be applied by impregnating the PVC resin solution, and drying the applied resin solution to form.

The manufacturing method will be described in detail with reference to FIGS. 4 and 5, in which the filaments are pulled from the filament 10 bobbin 22, which is the warp or weft of the filament supply unit 20, through the induction roller unit 26. It is supplied to the guide part 30. At this time, the filament 10 is supplied through the first guide 30 and the second guide 33 are guided.

The first guide portion 30 and the second guide portion 33 is a portion for guiding the filament and the reinforcing fabric 120 supplied from the reinforcing fabric bobbin 24, the first guide portion The filament passing through the 30 is transferred to the weaving machine 40 through the induction roller portion 84, the reinforcing fabric 120 is transferred to the weaving machine 40 through the guide guide 88 to the filament ( 10) is joined to one side of the sewing machine is combined by the weaving machine.

The geotextile band combined with the reinforcing fabric to the filament 10 as described above is discharged through the discharge guide roller portion 46 is wound by the take-up roller 70, or as shown in Figure 4 attached to the discharge The bands conveyed through the induction roller part 46 are transferred to the coating bath 50 filled with the resin coating liquid 58 through the guide rollers 42 and 44 to make resin coating, and the bands made of the resin coating are induction. After being transported to the dryer 60 through the roller 56 and dried, it is transferred to the take-up roller 70 through the induction roller 72 via the turning roller 74 and finally wound.

The strip for textile geogrid 100 of the present invention manufactured through the manufacturing process as described above is completed in a structure as shown in the accompanying drawings.

2 is a strip prepared as shown in FIG. 2 may be used to prepare a geogrid coated with a resin alone, and the strip 100 of the present invention may be inclined or weft as shown in FIG. Consisting of a rectangular mesh structure can be used to complete the resin coating.

Reference numerals 28, 52, 54, 74, 80, 82, 86, etc. not described above are guide rollers for guiding the filament or the reinforcing fabric or the strip 100 of the present invention.

Hereinafter, the present invention will be described in more detail with reference to preferred embodiments. However, the present invention is not limited to the following examples.

[Examples 1 to 5]

To prepare a textile polymer strip to have the conditions of Table 1, and coated with a PVC resin to prepare a specimen. Tensile strength test of the prepared specimen was carried out, and the results are also shown in Table 1 below.

division Design strength
(ton / m) design
Elongation
(%) Denier Seen Wide tensile strength
(ton / m) Elongation
(%) Example 1 6 11-12 6,000 168 7.7 10.8 Example 2 8 11-12 6,000 210 9.5 11.7 Example 3 10 11-12 6,000 252 10.6 10.4 Example 4 15 11-22 9,000 252 17.9 10.1 Example 5 20 10-11 12,000 252 23.1 10.3

Standard tensile strength and elongation of the polymer strip used as textile geogrid should be designed to have a characteristic of 6 ~ 20ton / m, elongation 10 ~ 12%, as a result of Table 1, the reinforcing fabric according to the present invention As a result of measuring the tensile strength and elongation of the true polymer band, it was found that the standard physical properties were satisfactorily satisfied and the physical properties were higher.

As a result, when the textile geogrid is manufactured using the polymer strip according to the present invention, it will be possible to produce a geogrid having more efficient and superior physical properties than the conventional geogrid.

10: filament 20: filament supply portion
22: bobbin 26: induction roller unit
30: first guide portion 33: second guide
24: reinforcing fabric bobbin 40: weaving machine
46: discharge guide roller portion 50: coating tank
56: guide roller 58: resin coating liquid
60: dryer 70: winding roller
72: guide roller 74: turning roller
28, 42, 44, 52, 54, 74, 80, 82, 86: guide roller
100: Polymer strip for textile geogrid
110: yarn filament portion 120: reinforcing fabric
130: sewing

Claims (6)

In the polymer strip for textile geogrid,
It is used as warp or weft yarn and is listed in plural, and is added to one side of the rib formed by the yarn filament (10) and the yarn filament having a yarn strength of 8.5g / denier or more and served as a yarn having a certain strength. Consisting of the reinforced reinforcing fabric, the strength reinforcing fabric is made by sewing to have a predetermined width in the yarn filament to form a sewing portion,
The strength reinforcing fabric uses a mesh circular knit fabric or warp knitted fabric,
The width of the sewing portion is proportional to the width of the rib formed by the line of the yarn filament, the distance between the sewing portion and the sewing portion is 10 ~ 20㎜ polymer strip for textile geogrid.
delete delete The method of claim 1,
The width of the reinforcement fabric of the strength reinforcing fabric forming the sewing portion is the same as the width of the rib, the width of the strength reinforcing fabric located between the sewing portion and the sewing portion is relatively relative to the width of the rib. Polymer strip for textile geogrid, characterized in that the width is formed narrow.
Supplying yarn to form a bundle filament, and arranging the filaments so as to form a predetermined width in a horizontal direction;
Supplying a reinforcing fabric to be positioned on an upper surface of the supplied filament;
Sewing step of fixing the filament and the reinforcing fabric; And
The method of manufacturing a polymer strip for textile geogrid characterized in that it comprises the step of impregnating and applying the strip formed after the sewing step in the PVC resin solution, and drying the applied resin solution. delete

Images