KR101268681B1 - Construction method of shore protection using soil-bag having geotextile - Google Patents

Abstract

PURPOSE: A construction method for soil-bag shore protection using a multi-stage geotextile is provided to facilitate a construction regardless of the weather condition of the sea, lower the construction cost, and to shorten the construction period. CONSTITUTION: A soil-bag using a multi-stage geotextile is made of a filler filled with a geotextile and separated into multi-stages. The geotextile(20) comprises a first stage geotextile(21), a second stage geotextile(22), and a third stage geotextile(23) for being consecutively connected on the circumference on one side. The multi-stage soil-bag is produced by repeating the process of spreading the geotextile, filling the filler into a support frame, and sealing. The soil-bag is carried and piled up underwater for construction.

Description

FIELD CONSTRUCTION METHOD OF SHORE PROTECTION USING SOIL-BAG HAVING GEOTEXTILE

The present invention relates to a revetment construction method, and more particularly, to fill the filling material in the geosynthetic fiber in the land to make a breakwater-type soil bag, and to transport the soil bag to the construction site and to carry out the revetment in water The present invention relates to a soil bag revetment construction method using multi-stage geosynthetic fibers.

Conventionally, in order to install harbor revetment and seawalls, for example, sandstone is dropped to form a basic embankment. Or a scavenger was constructed.

As described above, the embankment seats located on the bottom of the water during the revetment of the revetment are made of large diameters, such as rocks, so that the water in the revetment and the reservoir is moved to the sea side, and a large hole is formed between the relics. By doing so, there is a problem that the flow rate proceeds quickly. In this case, if the flow velocity is not blocked, the dredged soil that is dumped when the revetment is made inside the embankment is lost, and the amount of diesel oil that is dumped through the small-diameter sand to install the filter sand is largely lost. There was a problem of increasing the construction cost due to the long construction period, and a problem of loss of the dike due to scrubbing of the constructed revetment.

In other words, in order to form a bank embankment, the sandstone was loaded on a barge or a dump truck to move to the offshore location, and then it was constructed by dropping underwater or in the water by design specifications and a gradient using an excavator at a designated location. In addition, there was a problem that the dead stone was not dropped in place due to the flow rate during the dropping, as well as lost.

In addition, there is a problem in that the purchase cost of the sandstone is expensive, and the construction cost increases as a large amount of the sandstone is used, and the environment is destroyed by supplying the sandstone through the quarrying of the stone.

In addition, there is a problem in that the workability is inferior because it requires various types of work such as dropping of sandstones, coating stones on the sea side, and construction of mats (cobbles, earth and sand) on the landfill side.

In addition, due to the loss of the earth and sand on the landfill side, the stability of the site is weak, causing settlement of the site, there is a problem that the ocean is polluted.

There is a patent document 1 to solve such a problem.

Patent Literature 1 stacks a tube structure, an auxiliary structure, and a reinforcement structure to construct a breakwater, and can solve problems caused by dumping of sandstones, etc., but injects dredged soil into the inside of the tube structure in the construction site. Because the production is made at sea, the work is difficult and takes a long time due to the blue, etc. Also, as the tube structure and other auxiliary structures are used, the work is cumbersome and the solid bond between the tube structure and the auxiliary structures is weak, which makes it a robust shore structure. There is a problem that can not be constructed.

Patent Registration No. 10-1084674

The present invention is to solve the problems as described above, by filling the filling material in the geosynthetic fiber in the land to make a breakwater-type soil bag, and transport the soil bag to the construction site after the retreat through the method of placing it in water The purpose of the present invention is to provide a soil bag revetment construction method using multi-stage geosynthetic fibers that can prevent the loss of gravel and soil and improve the construction properties such as shortening the air and easy height adjustment.

In the soil bag revetment construction method using the multi-stage geosynthetic fiber according to the present invention, one or more of the filling material including soil, sand and dredged soil is filled in the land, the soil bag filled so that the filling material is isolated in two or more steps through the geosynthetic fiber Wherein, the geosynthetic fiber is the first step of the first geosynthetic fiber, the first step consisting of a multi-stage geosynthetic fiber which is connected to one side in the circumference of the first geosynthetic fiber; The first step includes a second step of carrying the soil bag produced by the first step to the sea and then loaded and installed in water, wherein the first step is to install the geotextiles configured to be filled in two or more stages, but the filling material And install the first stage geotextiles, which is the bottom end of the geosynthetic fibers, in the first stage support frame to fill the first stage support frame, and fill the first stage fill material in the first stage geotextiles of the first stage geotextiles. Raising the circumference to surround the first stage filling material to seal the first stage to produce the first stage revetment bag, the second stage support frame on the first stage revetment bag produced through the first-first step After filling the second stage filling material in the second support frame, the second stage geotextiles connected to the periphery of the first stage geotextiles are raised, and the second stage filling material is wrapped and sealed to manufacture the second stage revetment bag. Comprising two steps It characterized.

According to the soil bag revetment construction method using the multi-stage geosynthetic fiber according to the present invention, the soil filled with the filling material (soil, sand, dredged soil, etc.) in the land civil engineering fibers (consisting of the bar material, etc. in advance to match the height of the revetment structure) After the pouch is manufactured, it can be constructed by carrying out a single bag that is carried in the bag and carried it in water. That is, it is divided into land work (making bag) and sea work (bag of bag). Rapid construction is possible without being restricted.

In particular, the geotechnical fibers of the lower stage form the bottom of the upper stage, that is, the geotextiles are integrated while sharing the lower and upper stages, filling the filling material, and covering and sealing the geotextiles of the lower stage. The structure can be manufactured and constructed, and therefore, inconveniences and difficulties due to underwater work can be solved, thereby shortening the air and reducing the construction cost.

In addition, it is possible to reduce the construction cost by using low-cost soil, avoid the complaints caused by environmental destruction because it does not cause environmental destruction for the purchase of soil, and the supply and demand is smoothly improved construction.

In addition, construction of the revetment facility is possible through only a single operation of filling the soil with multiple stages, thereby shortening the air and using only a single type of equipment.

In addition, the soil does not leak out in the geosynthetic fiber can ensure the stability of the site and can prevent marine pollution.

1 is a cross-sectional view of the soil bag by the soil bag revetment construction method using a multi-stage geosynthetic fiber according to an embodiment of the present invention.
Figure 2 is a cross-sectional view of the geosynthetic fiber applied to the soil bag revetment construction method using a multi-stage geosynthetic fiber according to an embodiment of the present invention.
Figure 3 is a soil bag manufacturing process applied to the soil bag revetment construction method using a multi-stage geosynthetic fiber according to an embodiment of the present invention.
Figure 4 is an exemplary diagram applied to the sand stone layer and the coating layer in the soil bag revetment construction method using a multi-stage geosynthetic fiber according to an embodiment of the present invention.

≪ Example 1 >

Soil bag revetment construction method using multi-stage geosynthetic fiber according to the present invention is as follows.

1. Make a clay bag.

The present invention consists of installing the soil bag filled with the filling material in the geosynthetic fiber in water, as shown in Figure 1, the soil bag 10 is more than two stages (hereinafter described as three stages as an example) that is the first stage It consists of the 3rd stage back and forth (11, 12, 13). The first to third Nos. 11, 12, and 13 of the soil bag 10 is filled so that each filler is isolated from each other, but the geosynthetic fiber is composed of one.

The soil bag 10 of such a configuration is preferably in the form of a stepped cross section with a narrower cross-sectional area toward the top.

2 is a geosynthetic fiber 20 of the first stage geotextile 21, the second stage geotextile 22 connected to the circumference of the first stage geotextile 21, of the second stage geotextile 22 It consists of a third stage geotextile 23 connected to the circumference.

The material of the geotextile 20 is the same material (non-woven fabric, etc.) as used in the civil engineering field, and the first to third stages to integrally constitute the first to third tidal foe bags (11, 12, 13) Geotextile 21, 22, 23 is configured as follows.

The second stage geotextile 22 is connected to the circumference of the first stage geotextile 21, and the third stage geotextile 23 is connected to the circumference of the second stage geotextile 22.

At this time, one side of the second stage geosynthetic fiber 22 is connected to the sewing and the like spaced apart from the end of the first stage geosynthetic fiber 21 to cover the first stage geotextile 21 the first stage filling material. Covering portion 21a is configured.

Similarly, the third stage geotextile 23 is connected to the free end of the second stage geotextile 22 so that the covering portion 22a is configured.

The third stage geotextile 23 is configured to cover and seal the third stage filler 13a while the free ends overlap each other.

Covering portions (21a, 22a) of the first and second stage geosynthetic fibers (21, 22) is sealed through the lap joint to prevent the loss of the filler material.

The manufacturing process of the soil bag using the geotextile 20 configured as described above is as follows.

Equipment such as a crane will be used to carry and stow the finished soil bag 10, and install a lifting rope or the like on the ground of the land so that the soil bag 10 can be transported by the crane.

1. Manufacture of the first stage Hoan bags (11).

As shown in Figure 3, the first stage support frame 30 is installed standing on the periphery of the first stage geotextile 21. It is preferable that the height of the 1st stage support frame 30 is more than the height of the 1st stage rake bag 11.

The first stage filler 11a is filled in the first stage support frame 30 on the first stage geotextile 21.

After covering the covering portion 21a of the first stage geotextile 21 over the first stage filling material 11a and sealing it, after laminating the covering portion 21a so that the first stage filling material 11a does not leak to the outside. Secure with sewing, etc.

2. Manufacture of the second stage lanyard.

The first-stage revetment bag 11 forms the bottom part of the second-stage revetment bag 12, installs the second-stage support frame 40 upright, and fills the second-stage filling material 12a and then covers it 22a. ) And the second stage arc back bag 12 is manufactured by sealing (sewing, fixing pin, etc.) by overlapping.

3. Manufacture 3rd tidal tiger bag.

The second-stage revetment bag 12 forms the bottom portion of the third-stage revetment bag 13, installs the third-stage support frame 50 upright, and fills the third-stage filling material 13a, followed by the third-stage civil engineering. By covering and sealing the fibers 23, the third-stage rake eye bag 13 is produced.

Through the above process to complete the soil bag (10) consisting of three heights, by fixing the soil bag (10) with a lifting belt to prepare the salvage.

The soil bag (10) thus prepared is loaded on a ship such as a barge and transported to the sea, and then loaded and placed in water.

On the other hand, the present invention, as shown in Figure 4, after placing the soil bag (10) in the water and then installed and installed a sandstone and coated stone (sofa block, etc.) in a predetermined thickness on one side of the soil bag (10) It can be reinforced by forming the coating layer 70.

10: soil bag, 11, 12, 13: 1st to 3rd bag
20: geosynthetic fiber, 21, 22, 23: first to third stage geotextile
21a, 22a: covering portion, 30, 40, 50: first to third stage support frame
60: sandstone layer, 70: coating layer

Claims (4)

One or more of the filling material including soil, sand and dredged soil is filled in the land, and the filling material is manufactured so that the filling material is segregated into two or more stages through the geotextile, wherein the geotextile is the first stage geotextile of the lowest stage. A first step consisting of multiple stages of geotextiles, one side of which is serially connected to the circumference of the first stage geotextiles;
And carrying the earth bag produced by the first step to the sea and then the second step of loading and laying in water,
In the first step,
Install the geosynthetic fiber configured to be filled in two or more stages, but install the first stage geosynthetic fiber, which is the bottom end of the geosynthetic fiber, in the first stage support frame to fill the filling material at a predetermined height, and the first stage geotextile Step 1-1, after filling the first stage filling material to raise the circumference of the first stage geosynthetic fiber to surround the first stage filling material and to seal the first stage filling material;
The upper end support frame is placed on the first end revetment bag manufactured through the first step 1-1, and the filling material is filled in the upper end support frame, and then the upper end geotextile connected to the circumference of the first end geotextile is raised to the filling material. A method of constructing a soil pocket using a multi-stage geosynthetic fiber, comprising: 1-2 steps of enveloping and enclosing the upper end revetment bag;
The geotextile of claim 1, wherein the geotextiles of the lower end share the bottom part of the upper end, and the geotextiles connected to the upper end are connected in series to be spaced a predetermined distance from the end of the civil fiber of the lower end of the lower end geotextile of the fiber. A soil pocket revetment construction method using multistage geosynthetic fibers, characterized in that the covering portion is formed in a portion where the upper geosynthetic fiber is joined from an end portion. The method according to claim 2, wherein the end of the geosynthetic fiber to wrap and seal the geosynthetic fibers after filling the geosynthetic fiber is laminated with a soil bag revetment construction method using a multi-stage geosynthetic fiber. The multi-stage civil engineering method according to any one of claims 1 to 3, further comprising a third step of placing sandstones and coated stones on one side of the soil bag after placing the soil bag in water through the second step. Earthen bag revetment construction method using fiber.

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