JP6653346B2 - Fabric formwork, slope protection structure and slope protection method - Google Patents

Description

  The present invention relates to a cloth mold, a slope protection structure and a slope protection method using the same.

The slope protection structure is made of cloth, which is less expensive than the conventional upholstery block method, because it does not require the placement of foundation concrete or the laying of backfill crushed stones, and the work can be performed by a small number of people. The formwork method has become widespread in recent years.
This method is a method of laying a cloth mold having a bag portion prepared in advance on, for example, a slope or the like, and injecting mortar into the inside to harden (see Patent Document 1).

When pouring the mortar into the cloth mold, the mortar is poured in a state of containing a large amount of water in order to spread the mortar evenly in the bag portion. Excess water seeps out of the cloth during the solidification process and is discharged. At this time, part of the mortar component also precipitates on the cloth. If an excess mortar component (slag) remains on the cloth, it solidifies and closes the cloth, resulting in reduced water permeability.
Further, when the mortar component precipitated on the cloth is solidified, the mortar sticks white and impairs the appearance, particularly when the color of the cloth is green or black.

For this reason, the mortar component deposited on the cloth is removed by rinsing the entire protective structure (mat) with water after pouring the mortar.
In the conventional cloth mold, when a large amount of mortar component precipitates on the surface, particularly on the upper surface of the mat, there is a problem that it takes a long time to clean the mortar component, which leads to a troublesome work, a construction time and a labor cost.

JP 2006-037445 A

  The present invention has been made in view of the above-described conventional circumstances, and provides a fabric form, a slope protection structure, and a slope protection method in which leaching of a mortar component onto a mat upper surface is reduced. Aim.

The present inventors have conducted intensive studies to achieve the above object, and as a result, have conceived that the above problem can be solved by making the upper layer cloth and the lower layer cloth different in air permeability, and completed the present invention. I came to.
That is, the present invention is as follows.
[1]
A cloth formwork having a bag portion made of a two-layer fabric of an upper fabric and a lower fabric,
The bag portion, wherein the upper layer cloth has a Frazier permeability of 30 cm ³ / cm ² · second or less,
The Frazier permeability of the lower fabric is greater than the Frazier permeability of the upper fabric, and the difference in Frazier permeability between the upper fabric and the lower fabric is 10 cm ³ / cm ² · sec or more. To do, fabric formwork.
[2]
The fabric mold according to [1], wherein the cover factor of the upper fabric is 750 or more.
[3]
The fabric form according to [1] or [2], wherein the upper layer fabric is a plain weave.
[4]
The fabric form according to any one of [1] to [3], wherein the lower layer fabric is a weft weave or a mixed weave of a weft and a plain weave.
[5]
The fabric mold according to any one of [1] to [4], further including a plurality of filter portions made of a single layer of fabric formed in an island shape at predetermined intervals inside the bag portion.
[6]
A slope protection structure, wherein the fabric mold according to any one of [1] to [5] is used, and the fabric mold is arranged with the upper fabric side facing upward.
[7]
The following steps:
(1) laying the fabric form according to any one of [1] to [5] on a slope with the upper fabric side facing upward;
(2) a step of casting mortar or concrete inside the bag portion of the cloth mold; and (3) a step of dehydrating surplus water contained in the mortar or concrete through the texture of the cloth mold, and (4) washing the surface of the cloth mold with water after dehydrating excess water contained in the mortar or concrete;
Slope protection construction method.

  Advantageous Effects of Invention According to the present invention, it is possible to provide a fabric form, a slope protection structure, and a slope protection method in which the mortar component is less likely to seep into the upper surface of the mat. As a result, the burden of the cleaning operation can be reduced, and the construction time and cost can be reduced. Further, the thickness of the mat can be made uniform.

FIG. 1 is a plan view showing a configuration example of a cloth mold according to the present invention. Sectional drawing of the cloth mold after casting mortar. Sectional drawing which shows typically the slope protection structure using the cloth mold of this invention. FIG. 6 is a cross-sectional view schematically showing a state of collecting dehydration from the lower layer cloth in the example. FIG. 4 is a perspective view schematically showing a state of collecting dehydration from the upper layer cloth in the example.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a plan view showing one configuration example of a cloth mold of the present invention, and FIG. 2 is a sectional view of the cloth mold after mortar 10 is cast. FIG. 3 is a cross-sectional view schematically showing a slope protection structure using the fabric mold of the present invention.

In the following description, a case where the mortar 10 is filled and solidified inside the bag portion 2 will be described as an example, but the present invention is not limited to this, and for example, concrete may be filled. .
The fabric form 1 of the present embodiment has a bag portion 2 composed of a two-layer fabric 5 of an upper fabric 3 and a lower fabric 4. In the fabric form 1, in the bag portion 2, the upper fabric 3 has a Frazier permeability of 30 cm ³ / cm ² · sec or less, and the lower fabric 4 has a higher Frazier permeability than the upper fabric 3. In addition, a difference in the Frazier permeability between the upper fabric 3 and the lower fabric 4 is 10 cm ³ / cm ² · sec or more.
In the present embodiment, the upper fabric 3 and the lower fabric 4 constituting the bag portion 2 have different Frazier air permeability. Specifically, by making the Frazier permeability of the lower fabric 4 greater than the Frazier permeability of the upper fabric 3, the water permeability from the lower fabric 4 is made larger than the water permeability from the upper fabric 3. In other words, by reducing the water permeability of the upper fabric 3, the amount of mortar component (slag) oozing into the upper fabric 3 can be reduced, and the labor and time of the cleaning operation after filling the mortar can be greatly reduced.

In this fabric form 1, the bag 2 is made of a two-layer fabric 5. The two-layer fabric 5 is composed of an upper fabric 3 and a lower fabric 4, and is usually obtained by weaving in a bag weave. A mortar 10 and the like are cast in the gaps of the two-layer fabric 5. The fabric mold 1 is laid on, for example, a slope 20 with the upper fabric 3 side facing upward (front side) (see FIG. 3).
An injection port (not shown) is provided in the bag portion 2, from which a mortar 10 or the like is poured into a gap formed by the upper fabric 3 and the lower fabric 4 of the bag portion 2.

In the fabric mold 1 of the present embodiment, the Frazier air permeability of the upper layer fabric 3 is 30 cm ³ / cm ² · second or less. If the Frazier air permeability of the upper fabric 3 is larger than 30 cm ³ / cm ² · second, the water permeability of the upper fabric 3 becomes large, and the amount of dehydration from the upper fabric 3 is not sufficiently reduced.
By setting the Frazier air permeability of the upper fabric 3 to 30 cm ³ / cm ² · second or less, the amount of dehydration from the upper fabric 3 can be sufficiently reduced. However, if the Frazier air permeability is too low, the water permeability will also decrease and the water drainage will worsen. Therefore, the Frazier air permeability is preferably 1 cm ³ / cm ² · sec or more.
The Frazier permeability is measured by a method based on JIS L1096A method (Fragile method).

Further, the Frazier permeability of the lower fabric 4 is greater than the Frazier permeability of the upper fabric 3, and the difference of the Frazier permeability between the upper fabric 3 and the lower fabric 4 is 10 cm ³ / cm ² · second or more.
If the difference in the Frazier permeability between the upper fabric 3 and the lower fabric 4 is less than 10 cm ³ / cm ² · second, the difference in water permeability between the upper fabric 3 and the lower fabric 4 is provided, and the amount of dehydration from the upper fabric 3 Is not sufficiently obtained. When the difference in the Frazier permeability between the upper fabric 3 and the lower fabric 4 is 10 cm ³ / cm ² · second or more, the function and effect of the present invention can be sufficiently obtained.

It is preferable that the cover factor (cloth filling degree) of the upper layer cloth 3 is 750 or more. By setting the cover factor to 750 or more, it is possible to reduce the Frazier breathability of the upper fabric 3 and thus the water permeability. However, if the cover factor is too large, the air permeability and, consequently, the water permeability will be small, and the drainage will be poor, so the cover factor is preferably 1000 or less.
The cover factor can be obtained by calculation from the yarn count and the fabric density. Specifically, the warp direction cover factor is (√total weft size (dtex) × weft density (line / 2.54 cm)), and the weft direction cover factor is (√total weft size (dtex) × weft density). (Book / 2.54 cm)). The densities of the warp and weft woven fabrics are measured per inch (2.54 cm).

The upper cloth 3 is preferably a plain weave. By making the upper fabric 3 plain weave, the weaving density can be increased and the cover factor can be increased. The lower layer cloth 4 is preferably a weave or a mixed weave of a weave and a plain weave.
By changing the weaving specification between the upper fabric 3 and the lower fabric 4, the Frazier breathability and, consequently, the water permeability between the upper fabric 3 and the lower fabric 4 can be made different.

  As shown in FIG. 1, the fabric mold 1 may have a plurality of filter portions 6 formed of a single-layer woven fabric 7 and formed in an island shape at predetermined intervals inside the bag portion 2. By having the filter part 6, drainage becomes good and workability | operativity improves. Further, the necessity of the filing work after the construction can be reduced, and the labor and the labor cost of the work can be reduced. Also, in the protective structure after construction, the effect of releasing rainwater and the like from the slope can be sufficiently obtained.

The lower layer cloth 4 and the upper layer cloth 3 are connected to each other in an island shape at a predetermined interval, as shown in FIG. That is, the warp and the weft constituting the lower fabric 4 and the upper fabric 3, respectively, are partially woven as a woven fabric 7 to form the filter portion 6.
As shown in FIG. 1, the filter portions 6 are provided in an island shape on the two-layer fabric 5, and are arranged at specific intervals. The size, number, and arrangement of the filter portions 6 are not particularly limited and are appropriately selected according to the construction site or the like. However, a narrower spacing provides a more planar casting surface. For example, in FIG. 1, the filter units 6 are arranged vertically and horizontally in parallel, but the present invention is not limited to this.

  As described above, in the fabric mold 1 of the present invention, the amount of dewatering from the upper fabric 3 is reduced, so that the mortar component leaching (slipping) onto the upper surface of the protective structure (mat) can be reduced. As a result, the burden of cleaning work after construction can be reduced, and thus construction time and cost can be reduced. Further, the thickness of the mat can be made uniform.

Such a fabric form 1 is manufactured, for example, as follows.
The bag 2 forming the fabric form 1 is obtained by weaving a two-layer fabric 5 composed of an upper fabric 3 and a lower fabric 4 woven by warp and weft.
At this time, by changing the weaving specifications of the upper fabric 3 and the lower fabric 4, the Frazier breathability and, consequently, the water permeability of the upper fabric 3 and the lower fabric 4 can be made different.
The upper cloth 3 is preferably a plain weave. By forming the upper layer cloth 3 into a plain weave, the weaving density can be increased, the cover factor can be increased, and the air permeability can be reduced. The lower layer cloth 4 is preferably a weave or a mixed weave of a weave and a plain weave.

There is no particular limitation on the thread material used for the bag portion 2, and for example, nylon 6, nylon 66, polyamide, polyester, vinylon, polypropylene, polyvinylidene chloride and the like are used. Further, the thickness and the yarn density of the yarn are selected within a range in which the strength of the bag portion 2 at the time of driving and the excess water of the slurry after the driving can be squeezed out. For example, the thickness of the yarn is 400 to 3300 decitex ( dtex) and the yarn density are selected within the range of 40 to 7 yarns / inch (16 to 27 yarns / cm) for both the warp and the weft.
The warp and the weft may be of the same material and color, or of different materials and colors. In addition, it is preferable to use a yarn having almost the same characteristics for both the warp and the weft as the strength and elongation of the yarn. This is to make the extension deformation of the bag portion 2 substantially the same at the time of casting. In general, the fabric strength of the bag portion 2 can be obtained at the casting site by designing the fabric and controlling the production with the fabric strength at the lower limit of 150 kg / 3 cm width.
When weaving the two-layer fabric 5 composed of the upper fabric 3 and the lower fabric 4, a plurality of filter portions 6 may be formed by forming a plurality of single-layer fabrics 7 at predetermined intervals in an island shape. .

The upper layer cloth 3, the lower layer cloth 4, and the filter section 6 can be woven by a rapier loom incorporating an electronic jacquard device or other known looms such as dobby, tappet, mechanical jacquard, jet loom and the like.
When the mortar 10 is injected into the inside of the fabric mold 1, the fabric mold 1 shrinks somewhat. Therefore, the size of the fabric mold 1 (bag portion 2) is designed in consideration of the shrinkage.

Next, a slope protection method using such a fabric form 1 of the present invention will be described.
The slope protection method of the present invention is a slope protection method using the above-described cloth form 1 and includes the following steps:
(1) laying the fabric mold 1 on the slope 20 with the upper fabric 3 side facing upward;
(2) a step of casting a mortar (or concrete) 10 inside the bag portion 2 of the fabric form 1;
(3) a step of dehydrating the amount of excess water contained in the mortar (or concrete) 10 through the texture of the cloth form 1; and (4) a step of dehydrating the amount of excess water contained in the mortar (or concrete) 10 and then forming the cloth form. 1) washing the surface with water.
The details will be described below.

(1) The fabric mold 1 is laid on the slope 20 with the upper fabric 3 side facing upward.
First, the fabric mold 1 is laid on the slope 20 with the upper fabric 3 side facing upward (front side) (see FIG. 3).
Before laying the fabric mold 1 on the slope 20, it is preferable to form the slope 20 at the construction site. In the slope molding, for example, in the case of a bank, for example, cut and embankment are performed based on a planned cross-sectional view to eliminate unevenness of the ground and remove trees, grass, roots, and the like.
In addition, when the slope 20 to be protected is larger than a certain size, a plurality of units of the cloth form 1 having a predetermined size are prepared and transported to the construction site, and while checking the shape of the construction site on the spot, The units of the fabric form 1 may be appropriately combined to form the fabric form 1 in accordance with the size and shape of the slope 20 at the construction site.
While positioning, for example, a single pipe for suspension support is cast at the top of the slope, and the single-pipe is suspended through the cloth mold 1 on the slope by a predetermined method. Lay and fix.

(2) A mortar (or concrete) 10 is cast inside the bag 2 of the cloth mold 1.
After the laying step, a fluid (unsolidified) mortar 10 is injected between the upper fabric 3 and the lower fabric 4. Thereafter, the mortar 10 is solidified by maintaining the site until the mortar 10 poured into the cloth mold 1 is solidified, and managing the temperature and waterproofing necessary for the solidification.

(3) The excess amount of water contained in the mortar (or concrete) 10 is dewatered through the texture of the fabric form 1.
Excess water contained in the mortar 10 is discharged through the fabric of the fabric form 1 in the process of solidification.
At this time, in the fabric form 1 of the present embodiment, by providing a difference in air permeability and thus in water permeability between the upper cloth 3 and the lower cloth 4, the amount of dehydration from the upper cloth 3 is reduced. As a result, the amount of seepage (slipping) of the mortar component from the upper fabric 3 is reduced.

(4) After dehydrating an excess amount of water contained in the mortar (or concrete) 10, the surface of the cloth mold 1 is washed with water.
After the mortar 10 has been sufficiently drained, the entire protective structure (mat) is washed with water. Since the amount of seepage (slipping) of the mortar component from the upper layer cloth 3 is reduced, the labor for cleaning can be reduced. Thereby, construction time and cost can be reduced. Further, the thickness of the mat can be made uniform.

Further, when the fabric form 1 has the filter portion 6, drainage becomes good, and workability is improved. Further, the necessity of the filing work after the construction can be reduced, and the labor and the labor cost of the work can be reduced. Also, in the protective structure after construction, the effect of releasing rainwater and the like from the slope can be sufficiently obtained.
In this way, a slope protection structure as shown in FIG. 3 is constructed.

  Although the embodiments of the present invention have been described above, the present invention is not limited to these embodiments, and can be appropriately changed without departing from the spirit of the invention.

In the examples described below, in order to confirm the effects of the present invention, they were manufactured and their water permeability was evaluated.
In the following examples, the air permeability was measured on the ground surface of the cloth mold (excluding the reinforcing portion) according to JIS L1096A (Fragile method).
Warp / weft fabric density: Measured with a densimeter (number per inch).
The warp direction cover factor is (√total weft fineness (dtex) × the warp weave density (line / 2.54 cm)) The weft direction cover factor is (√the weft total fineness (dtex) × weft weave density (line / 2.54 cm) ).

(Example 1)
As the woven yarn, a polyester yarn having a yarn fineness of 1100 dtex / 192f was used.
As shown in FIG. 1, a cloth mold having a width of 1 m and a length of 4 m and having a double weave portion and a single weave portion was produced by bag weaving in which the upper fabric was plain weave and the lower fabric was oblique weave. The weaving density (ground yarn only) was 26.6 warps / inch and 23.0 wefts / inch.

The cover factor of the obtained fabric mold was 881 for the warp and 763 for the weft. The Frazier air permeability, the upper layer fabric 6.6cm ³ / cm ² · sec, the lower layer fabric is 37.9cm ³ / cm ² · sec, the difference was 31.3cm ³ / cm ² · sec.

(Example 2)
As the woven yarn, a polyester yarn having a yarn fineness of 1100 dtex / 192f was used.
A cloth mold having a double woven portion and a single woven portion, having a width of 1 m and a length of 4 m, was produced by bag weaving in which the upper fabric was a plain weave and the lower fabric was a mixed weave of a plain weave and a slope weave. The weaving density (ground yarn only) was 26.6 warps / inch and 23.0 wefts / inch.

The cover factor of the obtained fabric mold was 881 for the warp and 763 for the weft. The Frazier air permeability, the upper layer fabric 6.8cm ³ / cm ² · sec, the lower layer fabric is 20.7cm ³ / cm ² · sec, the difference was 13.9cm ³ / cm ² · sec.

(Comparative Example 1)
As the woven yarn, a polyester yarn having a yarn fineness of 1100 dtex / 192f was used.
A cloth mold having a width of 1 m and a length of 4 m, having a double weave portion and a single weave portion, was produced by bag weaving in which the upper fabric was plain weave and the lower fabric was plain weave. The weaving density (ground yarn only) was 21.9 warps / inch and 20.6 wefts / inch.

The cover factor of the obtained fabric mold was 726 for the warp and 683 for the weft. The Frazier air permeability, the upper layer fabric 35.2cm ³ / cm ² · sec, the lower layer fabric is 40.0cm ³ / cm ² · sec, the difference was 4.8cm ³ / cm ² · sec.

The fabric mold prepared as described above was placed on a 10% slope with the upper fabric side facing upward.
At this time, in order to collect dehydration from the upper layer cloth and the lower layer cloth, a blue sheet was attached to each of the upper layer cloth and the lower layer cloth of the cloth mold. As shown in FIG. 4, in order to collect dehydration from the lower surface (back), a water collecting reservoir 21 is dug, and a blue sheet 22 is laid between the slope 20 and the fabric form 1 (lower fabric 4). Was. Further, as shown in FIG. 5, in order to collect dehydration from the upper surface (front), blue sheets 23 are sewn in a U-shape on the left and right sides and the lower side of the upper fabric 3 of the fabric mold 1, respectively. Was.

A mortar (600 kg of cement, 1200 kg of sand, 360 kg of water) having a 1: 2 formulation was prepared. 0.5 m ³ of the mortar is injected from a mortar injection port of a cloth mold with a pump, and the amount of excess mortar discharged from the upper surface (front) and the side surface and the lower surface (back) of the protective structure (mat) is measured. did.
The surplus water discharged from the lower surface (back) of the mat is collected in the water collecting reservoir 21 along the blue sheet 22. Excess water discharged from the upper surface (front) of the mat accumulates on the blue sheet 23. These waters were collected and the amount was measured.

After leaving the mortar surplus water from the mat to dehydrate for 10 minutes, the mat was washed by pouring water over the surface. At this time, the household watering hose with an inner diameter of about 15 mm washes at an estimated hose watering flow rate of 13 L / min (calculated from the net article hose watering amount of 200 L / 15 minutes), and the slime adhered to the surface of the mat (the surface of the upper layer cloth) was visually cleaned. The time until it was drained was measured.
The amount of dehydration from the lower layer cloth, the amount of dehydration from the upper layer cloth, the state of the top cloth, and the time required for washing with water were compared. The results are summarized in Table 1.

In Example 1, the amount of dewatering from the upper layer cloth was very small, and the stain (pre-stain) due to the precipitated mortar was also small. In particular, there was little dirt immediately below the injection port, and washing with water was easy, and the mat washing was completed in 2 minutes. Similarly, in Example 2, the amount of dehydration from the upper layer cloth was very small, and the scumming was also small. In particular, there was little dirt immediately below the injection port, and it was the cleanest in Examples and Comparative Examples. Washing with water was easy, and mat washing was completed in 2 minutes.
On the other hand, in Comparative Example 1 in which the difference in air permeability between the upper fabric and the lower fabric was small, mortar spilled and it took 30 to 40 minutes to wash the mat. In addition, slime just under the injection port was remarkable.

  From the measurement of the amount of dehydration, in the example, the amount of dehydration from the lower fabric was not increased, but the woven density of the upper fabric was increased to reduce the air permeability. It is considered that this contributed to the prevention of slime contamination.

  By using the fabric mold according to the present invention, it is possible to reduce the labor for cleaning at the time of casting, and it can be widely used as a slope protection structure.

1: cloth mold 2: bag section 3: upper layer cloth 4: lower layer cloth 5: double layer cloth 6: filter section 7: single layer cloth 10: mortar

Claims (7)

A cloth formwork having a bag portion made of a two-layer fabric of an upper fabric and a lower fabric,
The bag portion, wherein the upper layer cloth has a Frazier permeability of 30 cm ³ / cm ² · second or less,
The Frazier permeability of the lower fabric is greater than the Frazier permeability of the upper fabric, and the difference in Frazier permeability between the upper fabric and the lower fabric is 10 cm ³ / cm ² · sec or more. To do, fabric formwork.   The fabric form according to claim 1, wherein the cover factor of the upper fabric is 750 or more.   The fabric formwork according to claim 1 or 2, wherein the upper layer fabric is a plain weave.   The fabric form according to any one of claims 1 to 3, wherein the lower layer fabric is a weft weave or a mixed weave of a weft and a plain weave.   The fabric mold according to any one of claims 1 to 4, further comprising a plurality of filter portions made of a single-layer woven fabric formed in a shape of an island at predetermined intervals inside the bag portion.   A slope protection structure, wherein the cloth formwork according to any one of claims 1 to 5 is used, and the cloth formwork is arranged with the upper fabric side facing upward. The following steps:
(1) a step of laying the fabric mold according to any one of claims 1 to 5 on a slope with the upper fabric side facing upward;
(2) a step of casting mortar or concrete inside the bag portion of the cloth mold;
(3) a step of dehydrating excess water contained in the mortar or concrete through the texture of the cloth mold; and (4) dehydrating excess water contained in the mortar or concrete, and then removing the surface of the cloth mold. Washing process,
Slope protection construction method.

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