KR20110116631A - Fabric form for slope construction - Google Patents

Abstract

The present invention relates to a fiber band for slope construction, such as to prevent scouring of slopes, slope protection, rapid recovery of collapsed slopes, in particular, to suppress the expansion of the lower fabric to the upper fabric to increase the ground area with the slope to significantly increase the safety factor It is related with the textile band for slope construction to improve.

Description

Fabric form for slope construction

The present invention relates to a fiber band for slope construction, such as to prevent scouring of slopes, slope protection, rapid recovery of collapsed slopes, in particular, to suppress the expansion of the lower fabric to the upper fabric to increase the ground area with the slope to significantly increase the safety factor It is related with the textile band for slope construction to improve.

Fabric form (Fabric Form) is a method of forming a concrete mat by injecting a flow of hard concrete or mortar with a high-pressure concrete pump between two layers of fabric woven from high-strength geotextiles.

This method is a formwork permeable cloth (cloth), the excess mixed water of the flowable concrete is discharged by the injection pressure, the water and cement ratio is reduced, so that the curing time is fast, it is possible to make a high-density high strength concrete hardened body.

The process can also be easily installed on land as well as in water, and formwork can be used to bond well in complex terrain with different gradients, resulting in an even thickness of concrete mat.

In the construction, the fabrics are prepared in advance according to the site topography, and concrete or mortar is injected into the concrete pump, so that a wide area can be constructed at a time, and a high-strength concrete mat can be obtained in a short time. Compared to the precast block hole, it is faster, safer, more efficient in construction and more economical, and it is particularly effective in underwater construction.

In addition, since the construction of a large area integrally compared to other construction methods, it is excellent in rigidity, there is little earth and earth scour, and there is no fear of defects.

Conventional fiber bands of this type are known from the patent literature.

As shown in Figs. 1 and 2, the conventional fiber band is made of a high strength polyester fabric or a polypropylene fabric. The fiber band consists of two layers of the upper fabric 1 and the lower fabric 2, and the two fabrics are joined to each other in a zigzag filter portion 4. The remaining part except the filter part 4 forms a space 5, and concrete or mortar is injected into the space 5. That is, the upper fabric 1 and the lower fabric 2 are joined in a zigzag filter portion 4 to form a bag-shaped formwork in the form of a mat.

By the way, when the concrete or mortar is injected into the fibrous band as shown in Figure 3, the upper fabric 1 and the lower fabric (2) is inflated to take some form of balloon.

When the upper fabric 1 and the lower fabric 2 are expanded in the same shape as described above, the lower fabric 2 is grounded almost in line contact or point contact with respect to the inclined surface, thereby reducing the ground area.

The ground area and friction coefficient between the fiber band and the ground (inclined ground) are important variables when examining the stability of the fiber band. If the friction coefficient of the ground and the fiber (grout) is the same, the stability of the fiber band decreases when the ground area decreases.

In addition, the expansion of the lower fabric (2) is also far away from the slope of the filter unit 4 as shown in Figure 3 (T), it does not serve as a drainage through the filter unit 4, the long-term fragile part is a hole is generated To lower the strength.

Korean Laid-Open Patent No. 1995-0027106 Korean Laid-Open Patent No. 1998-0082084

The present invention has been made to solve the above-mentioned problems, and because the lower fabric swelling of the lower fabric to the upper fabric to increase the safety factor to increase the ground area with the slope, so even if the thickness of the mortar to maintain the same safety factor The purpose is to provide a textile band for slope construction that enables economic construction.

In order to achieve the above object, the fiber band for slope construction according to claim 1 of the present invention,

Lower fabric laid on four sides; An upper fabric disposed over the lower fabric; Including a filter unit for bonding the upper fabric and the lower fabric to each other,

The lower fabric has a smaller expansion than the upper fabric.

According to the configuration of claim 1, the expansion of the lower fabric with respect to the upper fabric to increase the safety factor to increase the ground area with the slope, thereby enabling economic construction to maintain the same safety ratio even if the thickness of the mortar thin.

The fiber band for slope construction of Claim 2 of this invention,

The lower fabric has a greater modulus than the upper fabric.

The fiber band for slope construction of Claim 3 of this invention,

The lower fabric is made of polyester, and the upper fabric is made of polyester and polyurethane to realize a difference in modulus.

The fiber band for slope construction of Claim 4 of this invention,

 The seam of the lower fabric and the other lower fabric is deeper than the seam of the upper fabric and the other upper fabric.

According to the configuration of claim 4, since the lower fabric has to be pulled and bonded compared to the upper fabric, the lower fabric is pulled taut first so that the ground area can be increased because the upper fabric expands and then expands.

The fiber band for slope construction of Claim 5 of this invention,

The lower fabric is preferably woven into a high strength yarn having a greater tensile strength than the upper fabric.

The fiber band for slope construction of Claim 6 of this invention,

The lower fabric is preferably woven into a high strength yarn compared to the upper fabric.

The fiber band for slope construction of Claim 7 of this invention,

If the lower fabric has a higher weave density than the upper fabric, the ground fabric is increased by improving the strength (tensile strength) and modulus of the fiber.

The fiber band for slope construction of Claim 8 of this invention,

The lower fabric is preferably bonded in a more pulled state than the upper fabric.

As is apparent from the above description, the embodiment of the present invention has the following effects.

By weaving different amounts of expansion for the same pressure of the mortar into which the upper and lower fabrics are injected, the ground area with the slope is increased to maintain the same safety factor even with a thinner grout thickness, and the filter portion is also almost equal to the slope. It makes contact with water drainage smoothly and there is no loss of strength.

1 is a perspective view schematically showing a fiber band for a conventional slope construction.
2 is a partial plan view of FIG. 1.
Figure 3 is a side cross-sectional view showing a state in which the conventional fiber band is installed on the slope.
Figure 4 is a side cross-sectional view showing a state in which the fiber band is installed on the slope according to a preferred embodiment of the present invention.
Figure 5 is a side view showing the position of the joint in the fiber band of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings, where like reference numerals refer to like parts, and detailed description thereof will be omitted.

Figure 4 is a side cross-sectional view showing a state in which the fiber band is installed on the slope according to a preferred embodiment of the present invention.

As shown in Figure 4, the fiber band of the present embodiment is composed of the upper fabric 10, the lower fabric 20, the upper fabric 10 and the filter portion 14 in contact with the lower fabric 20, the upper fabric The amount of expansion of 10 and the lower fabric 20 is made differently. The space 15 between two layers except the filter part 14 is a mortar injection space.

That is, the lower fabric 20 placed on the slope as shown in FIG. 5 is implemented to be less expanded by the mortar injected at the same pressure than the upper fabric 10, thereby increasing the ground area with the slope.

Embodiments for varying the amount of expansion of the upper fabric 10 and the lower fabric 20 can be implemented by greatly different materials, different physical properties of the yarn, or different lengths.

First, when the material of the upper fabric 10 and the lower fabric 20 is different, the lower fabric 20 is woven from polyester yarns, the upper fabric 10 is a polyester and polyurethane composite This is the case of weaving.

The composite yarn is a yarn in which polyester is coated on polyurethane yarn.

The composite yarn imparts a smaller modulus (i.e., stretches better) than the polyester yarn, so that the upper fabric 10 swells more than the lower fabric 20 when injected at the same pressure, so that the lower fabric 20 Increased ground area with over slope can be secured.

On the other hand, when the physical properties of the yarn is different, when the upper fabric 10 and the lower fabric 20 is the same, the tensile strength of the yarn (fiber) or the modulus of the yarn is to be used.

For example, the upper fabric 10 is woven with a yarn of 9g / d tensile strength, the lower fabric 20 is used by weaving with a yarn 11g / d increased by about 22% tensile strength. Then, the upper fabric 10 is first expanded with respect to the pressure of the mortar to be injected, thereby increasing the amount of swelling.

In addition, the amount of expansion can be made different by varying the weaving density (the number of strands per unit area) affecting the tensile strength and modulus.

For example, the upper fabric 10 applies a weaving density of 22 × 21.5 and the lower fabric 20 applies a weaving density of 28 × 26.

That is, the lower fabric 20 is densely woven with a higher weaving density than the adult fabric 10, thereby improving the tensile strength and modulus to increase the ground area with the slope.

On the other hand, the same material may be different in the amount of expansion by varying the length of the upper fabric 10 and the lower fabric 20.

For example, when the lower fabric 20 is shorter in length than the upper fabric 10, when the lower fabric 20 is bonded to each other while the lower fabric 20 is pulled, the lower fabric 20 is pre-expanded so that the mortar into which the injecting mortar is injected is the upper fabric 10. ), The upper fabric 20 is further inflated upward.

The same effect can be obtained even when the upper fabric 10 and the lower fabric 20 have the same length and the lower fabric 20 is further pulled to contact each other.

Meanwhile, as shown in FIG. 5, the upper fabric 10 jointly connecting the upper fabric 10a and the other upper fabric 10b, and the lower portion jointly connected to the lower fabric 20a and the other lower fabric 20b. When the fabric 10 is in contact with each other, the expansion amount can be realized differently if the lower seam 21 is joined at a deep position (D> d) which overlaps more than the upper seam 11.

That is, if the upper fabric 10 and the lower fabric 20 is the same length and the same material, because the overlap depth (D) of the lower joint 21 is deeper than the overlap depth (d) of the upper joint 11 When the lower fabric 20 is shorter than the upper fabric 10, the lower fabric 20 should be pulled in the direction of the arrow when bonded to each other. Therefore, since the lower fabric 10 is pre-expanded by the amount pulled, the upper fabric 10 is first inflated by the mortar into which the upper fabric 10 is injected.

When the length of the same material is shorter, the lower fabric 20 may be thinner than the upper fabric 20 because it is in a stretched state first, but may be lower in terms of strength, but the materials of the upper fabric and the lower fabric may be different to reinforce the strength. It may be.

As described above, although described with reference to a preferred embodiment of the present invention, the present invention can be variously modified or modified without departing from the spirit and scope of the present invention described in the claims Those skilled in the art will appreciate.

The present invention is applicable to all cases where the bag is intended to vary the degree of expansion for the same pressure being injected.

1, 10: upper fabric 2, 20: lower fabric
4, 14: filter part 5, 15: filling space
11, 21: seam

Claims (8)

Lower fabric laid on four sides;
An upper fabric disposed over the lower fabric;
Including a filter unit for bonding the upper fabric and the lower fabric to each other,
The lower fabric is a fiber band for slope construction less than the upper fabric.
The method of claim 1,
The lower fabric is a fiber band for slope construction having a larger modulus than the upper fabric.
The method of claim 2,
The lower fabric is made of polyester,
The upper fabric is a fiber band for slope construction is a composite material of polyester and polyurethane.
The method of claim 1,
And the seam of the lower fabric and the other lower fabric is deeper than the joint of the upper fabric and the other upper fabric.
The method of claim 1,
The lower fabric is a fiber band for slope construction greater than the upper fabric.
The method of claim 5,
The lower fabric is a fiber band for slope construction woven with a higher strength yarn than the upper fabric.
6. The method according to claim 2 or 5,
The lower fabric is a weaving fiber band having a higher weave density than the upper fabric.
The method of claim 1,
The textile fabric for slope construction bonded to the lower fabric is pulled more than the upper fabric.

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