KR100437343B1 - Strengthening system for weak foundation with a double vertical drainage and construction method thereof - Google Patents

Abstract

The present invention relates to a soft ground reinforcement system for quickly discharging the pore water in the soft ground to the ground, so that the soft ground is quickly strengthened, the system of the present invention is formed in the interior of the soft ground (20) in the ground soft ground Sand pillars 31 absorbing the number of gaps of water and discharged to the ground surface, and a plurality of passages are formed along the inner longitudinal direction of the sand pillars 31 and the gap water is introduced into the ground surface and discharged to the ground surface. And a porous tube 14 having an inner space therein, and because the present invention discharges the gap water to the ground surface in double through the sand column 31 and the porous tube 14, a part of the sand column 31 is broken. In the event of a loss or similar situation, the pore water is discharged to the ground normally quickly, ensuring the ground strengthening effect.

Description

Structuring system for weak foundation with a double vertical drainage and construction method

The present invention relates to a system for reinforcing soft ground, and in particular, to reinforce the soft ground through a double vertical drainage structure which is constructed inside the soft ground so that the soft ground is quickly reinforced by quickly discharging excess pore water in the soft ground to the ground surface. It is about a system. The present invention also relates to a method for constructing a double vertical drainage structure in the soft ground so that the excess pore water in the soft ground can be quickly discharged to the ground surface.

Soft ground is composed of soils with high moisture content such as landfills and reclaimed land, and these soft grounds are vulnerable to loads.

In general, the strengthening of soft ground is carried out through the discharge of excess pore water present in the ground. The method of discharging the excess pore water to the ground to strengthen the ground includes the sand drain method, the paper drain method, and the pack drain method. For this purpose, it is classified according to the type of drain material (vertical drainage material) which serves as a passage for absorbing the pore water and discharging it to the outside.

The sand drain method is a method of vertically installing sand pillars (drain material) having a diameter of about 30 to 50 cm inside the soft ground. The paper drain method is a drain material made of petrochemical materials such as polyethylene and polypropylene. It is a method of installing vertically inside the soft ground, and the pack drain method is a method of vertically installing the inside of the soft ground by protecting the sand pillar with a diameter of about 10 cm with a soft porous fiber bag.

The sand drain method, which is evaluated as the best among the above methods, has a problem that it is difficult to apply to soft ground having a deep depth because the drain material may be broken during the strengthening of the ground if the depth of the soft ground is deep. The pavedrain method developed for the construction also has a risk that the drain material may fall into the ground during construction, or the top and bottom portions may be disconnected due to the kink of the drain material. In addition, since the paper drain method uses a drain material made of a petrochemical material, there is a disadvantage of low reliability at a deep depth due to long term deterioration of absorption performance and breakage problem. When the drain material is cut out of the above problems, it is very unlikely that the gap of the lower part of the cut will not be discharged to the surface quickly, so that the reinforcement of the soft ground will not be carried out as planned. There is a problem that can cause a big problem.

Therefore, the present invention has been made to solve the problems of the prior art as described above, even if a part of the drain material is broken or similar situation through the double vertical drainage structure, the gap water is quickly discharged to the ground surface quickly. The purpose of the present invention is to provide a soft ground reinforcement system that can secure the ground reinforcement effect as well as to facilitate the smooth reinforcement of the pore water even under normal circumstances.

In addition, the present invention has another object to provide a construction method that can quickly obtain the ground reinforcement effect by constructing a double vertical drainage structure that can be discharged smoothly to the ground surface even in abnormal or normal conditions.

1 is a schematic view of the steel pipe used in the construction method of the present invention,

2a to 2f is a process chart showing a construction method of a double vertical drainage structure for reinforcing soft ground according to the present invention,

3a and 3b are respective cross-sectional views showing a double vertical drainage structure constructed in the soft ground according to the present invention,

4 is a conceptual diagram illustrating a process of discharging the pore water from the soft ground to the ground surface through the double vertical drainage structure according to the present invention.

♠ Explanation of symbols on the main parts of the drawing ♠

10: iron pipe 11: pointed part

12: drain material inlet port 13: air supply port

14: porous tube 15: tube insertion hole

16: centering member 20: soft ground

30: drain material 31: sand pillar

According to the present invention for achieving the above object,

In the system that reinforces the soft ground by discharging the gap water inside the soft ground to the ground surface,

An external drainage formed in the inner direction of the soft ground from the ground surface to absorb the gap water inside the soft ground and discharge it to the ground surface;

It is installed along the inner longitudinal direction of the external drainage and includes a plurality of passages through which the pore water flows and includes an internal drainage having an inner space for discharging the pore water introduced through the passage to the ground surface,

It is characterized by reinforcing the soft ground by discharging the gap water to the ground in double through the external drain and the internal drain.

In addition, according to the present invention for achieving the above object,

In the method of constructing a drainage drainage water from the interior of the soft ground to the ground surface to discharge the gap water inside the soft ground to strengthen the soft ground,

Injecting an iron pipe for forming the drainage material into the soft ground;

Disposing a plurality of passages through which the pore water flows along the inner longitudinal direction of the steel pipe and having an inner space for discharging the pore water introduced through the passage to the ground surface;

Filling an external drainage material capable of absorbing gap water into the steel pipe in which the internal drainage material is disposed and discharging it to the ground surface;

Supplying air to the inside of the steel pipe and applying pressure to draw the steel pipe to the upper, and constructing a double drain material having an internal drainage formed in the inside of the external drainage sequentially from the inside of the soft ground to the ground surface. Characterized in that.

In the following, with reference to the accompanying drawings, a preferred embodiment of the soft ground reinforcement system and its construction method through a double vertical drainage structure according to the present invention will be described in detail.

1 is a schematic diagram of an iron pipe used in the construction method of the present invention.

As shown in Figure 1, the steel pipe 10 used in the present invention is formed similarly to the steel pipe used in the sand drain method. That is, the bottom of the iron pipe 10 is formed in a pointed shape so that it can be easily inserted into the soft ground, this pointed portion 11 is opened by the pushing force from the inside and closed to its original position when the force is removed It is formed to be. In the upper portion of the steel pipe 10, a drain material inlet 12 for injecting a drain material such as sand and an air supply port 13 for supplying high pressure air into the steel pipe 10 are respectively formed. It is. In addition, at the top of the steel pipe 10 is formed a tube insertion hole 15 that serves as a passage through which the porous tube 14 is inserted. The steel pipe 10 thus formed is irrelevant to any cross-sectional shape if the cross section is formed inside the circle, square, pentagon, hexagon, or octagon.

In the following, the construction method of the double vertical drainage structure for strengthening the soft ground according to the present invention using the steel pipe 10 configured as described above.

In the drawings, Figures 2a to 2f is a process diagram showing a construction method of the double vertical drainage structure for reinforcing soft ground according to the present invention, Figure 3a and 3b is a double vertical construction on the soft ground according to the present invention 4 is a cross-sectional view illustrating the drainage structure, and FIG. 4 is a conceptual diagram illustrating a process of discharging the pore water from the soft ground to the ground surface through the double vertical drainage structure according to the present invention.

First, as shown in FIGS. 2A and 2B, the steel pipe 10 is press-fitted to a predetermined point of the soft ground 20. In some cases, the steel pipe 10 is press-fitted by applying vibration to increase the press-fitting capability. At this time, the porous tube 14 is pre-positioned in the inner center of the steel pipe 10, and then the steel pipe 10 is pressed into the soft ground 20 or the steel pipe 10 is pressed into the soft ground 20. Afterwards, the porous tube 14 is positioned at the inner center of the steel tube 10 through the tube insertion hole 15. At this time, the porous tube 14 is preferably disposed exactly vertically along the inner center of the steel tube 10, so in the present invention is inserted and fixed around the porous tube 14 and a plurality of protrusions of the same length on the surface The centering member 16 is formed. That is, the plurality of protrusions formed in the centering member 16 allows the porous tube 14 to be positioned exactly vertically along the inner center of the steel pipe 10.

The porous tube 14 has a plurality of holes evenly distributed to allow fluid to flow from the inside to the outside or the outside to the inside, the cross section of the inside, such as circular, oval, square, pentagonal, hexagonal or octagonal Any cross-sectional shape is irrelevant as long as it forms a space through which fluid can flow. In addition, since the porous tube 14 has sufficient strength to be not cut or broken even if it has a predetermined length, any material may be satisfied as long as such requirements are satisfied.

When the steel pipe 10 is press-fitted to a predetermined point of the soft ground 20, as shown in Figure 2c is introduced into the drain material sand through the drain material inlet 12 formed in the upper portion of the steel pipe (10). In this way, when sand injection is completed, as shown in FIGS. 2D and 2E, the drain material inlet 12 and the tube insertion port 15 are sealed, and the steel is gradually applied while applying a high pressure air pressure through the air supply port 13. Draw the tube 10 upwards. Then, while the pointed portion 11 located at the bottom of the steel pipe 10 is opened, inside the soft ground 20, as shown in FIG. 2F, the porous tube 14 has a sand pillar shape in the center. The drain material 30 is made sequentially. When the steel pipe 10 is slowly drawn to the upper side so that the lowermost part is exposed to the ground surface, it no longer supplies high pressure air through the air supply port 13, and then the pointed portion 11 of the steel pipe 10 is provided. Also closed in place.

When the drain material is installed inside the soft ground by the above construction method, the drain material 30 having the double vertical drainage structure is constructed as shown in FIGS. 3A and 3B. That is, inside the drain material 30, a porous tube 14 serving as an internal drain material for discharging the gap water is located, and around the porous tube 14, a sand column serving as an external drain material for discharging the gap water ( 31) is formed, and the drain material 30 has a double drainage structure.

As shown in FIG. 4, the gap water inside the soft ground 20 is discharged to the ground surface through the drain material 30 having the double drainage structure. That is, the pore water is discharged to the ground along the porous tube 14 and the sand pillar 31 serving as the inner drain and the outer drain.

In the above-described embodiment, a case in which a drain material having a double vertical drainage structure is formed using a porous tube and sand has been described, but the present invention is not implemented by only such a member and a material. That is, as a substitute for the porous tube, it has a strength that is not cut or broken even if it has a predetermined length, and if the external fluid can be introduced into the space to form a space that can flow along the inside, the shape and material It can be used regardless of the like. For example, the drain board used in the paper drain method can also be used as a substitute for the porous tube. In addition, as a substitute for sand used in the present invention, any material having good water permeability even in a wet state like sand can be used.

As described in detail above, when a drain material having a double vertical drainage structure is constructed by the construction method of the present invention, the pore water is moved to the ground surface through the inner porous tube even if some external sand column drain material is broken or a similar situation occurs. As it can be discharged quickly and quickly, it is possible to secure the ground strengthening effect as well as the ground strengthening effect can be obtained quickly by helping the smooth discharge of the pore water under normal circumstances.

Above, the technical details of the soft ground reinforcement system and its construction method through the double vertical drainage structure of the present invention have been described with the accompanying drawings, which are illustrative examples of the best embodiments of the present invention. It is not.

In addition, it is obvious that any person skilled in the art can make various modifications and imitations without departing from the scope of the technical idea of the present invention.

Claims (8)

Soft ground comprising a drain material inserted into the soft ground to absorb the gap water contained in the soft ground, and a porous tube installed along the inner longitudinal direction of the drain material so that the gap water is more easily discharged to the ground surface. In the system to strengthen, Soft ground reinforcement through a double vertical drainage structure, characterized in that the centering member is inserted and fixed to the periphery of the porous tube so that the porous tube is positioned vertically, the surface is formed with a plurality of protrusions having the same length on the surface thereof. system. delete delete delete delete In the construction method to strengthen the soft ground by discharging the pore water contained in the soft ground to the ground surface, A first step of having an iron pipe pressed into the soft ground; A centering member having a plurality of protrusions is fixed to an outer surface of the porous tube so that the porous tube is vertically positioned at the inner center of the steel pipe, and the porous tube is inserted into the steel pipe through the tube insertion hole of the steel pipe. A second step of placing; A third step of filling a drain material into the steel pipe pressed into the soft ground; And And a fourth step of drawing the iron pipe to the upper portion while applying pressure to the inside of the iron pipe, thereby strengthening the soft ground through the double vertical drainage structure. delete delete