KR100463314B1 - Soil Improvement Method of Soft Clay Using Water as Surcharge Load in Large Land - Google Patents

Abstract

The present invention is a large-scale site construction adjacent to the sea, so that the soft ground can be loaded at the same time by using water as a load in the improvement of the soft ground, so that the new soft ground can be applied to large-scale soft ground improvement. It is about improvement method.

Specifically, in the present invention, a sand mat layer is disposed on the soft ground to be improved, a sidewall of the soft ground is formed with a bank structure having a predetermined height, and the sand mat layer covers up to one side of the bank structure. In order to facilitate the consolidation of the soft ground by installing a water-repellent film, the condensation of the soft ground is provided by applying the self-weight of the fresh water to the load of the soft ground by desalting a predetermined amount of water in the space formed by the installation of the water-repellent film. do.

According to the present invention, it is possible to solve the problem of sediment securing as in the prior art because the installation of the water repellent membrane on the soft ground and using the weight of the fresh water therein as the consolidation load of the soft ground.

Description

Soil Improvement Method of Soft Clay Using Water as Surcharge Load in Large Land}

The present invention relates to a method for improving the soft ground, and in particular, as a large-scale site construction adjacent to the sea, it is possible to load an equal load on the soft ground at a time by using water as a loading load in improving the soft ground. The present invention relates to a new soft ground improvement method that can be applied to soft ground improvement.

In general, in the port construction work such as container wharf construction, the ground used as a container yard or related site is a super soft ground or drier sea clay which is filled with sea clay. These grounds are too fragile to be used for the purpose of use as a site, and there is a lack of bearing capacity without the ground improvement, which is not suitable for use as a site, and a substantial large settlement occurs when a load is applied even in actual use, causing problems in usability.

In order to solve this problem, a conventional method for improving soft ground is a soft ground improvement method by preloading. The preloading method loads a load larger than the load to be applied when the site is used ("floating load") to generate the settlement of the ground in advance, and in this preloading method, the settlement amount generated during use as a site is suitable for site use. Make sure you are within acceptable limits.

In this preloading method, sand drain, p. ratio. It is common to use a vertical drainage such as P.B.D. to reduce the drainage distance of consolidation leachate and to achieve rapid consolidation settlement of the soft ground. In the conventional preloading method, there are earth and sand, atmospheric pressure, water, and the like, which are used as a preload applied to the ground in advance, of which sand is most commonly used.

By the way, when the soil is used as the loading material, serious problems such as local depression during improvement of the soft ground due to the inherent problems of the soil, that is, the possibility of shear failure and the difference from the assumptions suggested in the calculation of the consolidation settlement, etc. Inequality problems will occur. In addition, it is not only expensive to secure reclaimed soil, but also causes considerable destruction of the natural environment when securing the soil.

On the other hand, the load loading method using atmospheric pressure is called vacuum consolidation method, and is a method of isotropically consolidating the soft ground by applying negative pressure to the ground using a vacuum pump. This method using the atmospheric pressure has the advantages of shortening the consolidation period and equal load, but it is essential to use airtight sheets and special vertical drainage material, and because it requires a vacuum pump operation, there is a fatal disadvantage that the construction cost is high. In addition, there is a disadvantage that the area of the site to which this method can be applied is small, and the load cannot be applied up to about 8 t / m ² .

On the other hand, the method of using water as a loading material has the advantage that the consolidation settlement calculation theory and the actual construction situation are in good agreement with very low construction cost because water is used as the loading material, but it is applied to large-scale sites for the following reasons. It was impossible to do.

As the ground subsides due to the consolidation of the ground, excessive tensile cracking occurs in the insulation film. Since a technique for preventing the occurrence of such a tensile crack has not been developed in the past, a large tensile crack in the insulation film due to substantial ground subsidence In this large-scale site, the use of water as a loading load has not been applied.

In addition, since a suitable method for draining the condensed leachate when the soft clay layer surface is ordered with the water-repellent film has not been proposed, the conventional method of using water as a loading load on a large-scale site has not been applied.

In particular, it is not applicable to large-scale sites because a method for checking and repairing a breakage or crack occurs.

For this reason, the method of improving the soft ground by using water as a loading load is used only as a secondary role of replenishing and loading the insufficient load of soil and vacuum consolidation with water in a very small area. come.

Accordingly, the present invention is a soft ground improvement method developed to overcome the limitations of the conventional soft ground improvement method as described above, and can be efficiently applied to large-scale sites while using water as a loading load, especially in large-scale site construction adjacent to the sea. It is an object of the present invention to provide a new soft ground improvement method that can be applied to the improvement of soft ground economically using sea water.

1 is a schematic cross-sectional view of a state in which the embankment structure is formed on the side of the soft ground site according to the soft ground improvement method according to the present invention, and a sand mat layer for consolidation drainage is installed on the soft ground site between the embankment structures.

Figure 2 is a schematic cross-sectional view and a detailed view of the sand mat layer is installed on the soft ground in accordance with the present invention, the water film is not yet contained in the state that the water curtain is installed thereon.

3 is a schematic cross-sectional view and a detailed view of a state in which a sand mat layer is installed on a soft ground and water is not yet contained in a state in which a water curtain is installed thereon according to another embodiment of the present invention.

Figure 4 is a schematic diagram showing the configuration of the leachate drainage unit used in the present invention.

* Explanation of Signs of Major Parts of Drawings *

1: Ordering film 2: Protective film for preventing shear resistance

3: discharge pipe 4: inflow pipe

6 pump 7 horizontal drainage

8: dike structure 9: vertical drainage

10: sand mat layer 11: leachate discharge unit

In order to achieve the above object, in the present invention, a sand mat layer is disposed on the soft ground to be improved, a dike structure having a predetermined height is formed around the soft ground, and the sand mat layer is disposed above the sand mat layer. It is installed to cover the side of the embankment structure, and the space formed by the installation of the water repellent membrane is characterized in that the fresh water of the fresh water is added to the load of the soft ground by the fresh weight of the fresh water to promote consolidation of the soft ground. Soft ground improvement methods are provided.

According to the present invention, it is possible to solve the problem of sediment securing as in the prior art because the installation of the water repellent membrane on the soft ground and using the weight of the fresh water therein as the consolidation load of the soft ground.

In the present invention, in the soft ground improvement method described above, a soft ground improvement method is provided, wherein a protective film for preventing shear resistance is provided between the order film and the bank structure to prevent direct contact with the soil of the bank structure. For example, as the soft ground subsides, the soft ground improvement method is provided so as to form a portion of the membrane in the portion where the bank structure and the soft ground meet so as to be deformed.

According to the present invention as described above, according to the settlement of the soft ground, because it adopts a structure that can reduce the shear resistance generated between the embankment structure around the soft ground and the order film, damage to the order film due to the generation of over-tension due to the shear resistance Can be prevented.

On the other hand, in the present invention, the leachate discharge unit is installed so that the end is located in the sand mat layer through the water-repellent film, and the leachate generated during the consolidation process of the soft ground is forcibly discharged by the leachate discharge unit. A soft ground improvement method is provided, wherein the leachate discharge unit is installed such that an end reaches the sand mat layer through the water repellent membrane and a through hole is formed at the end thereof so that leachate flows from the sand mat layer through the through hole and is stored. It may be configured to include an inlet pipe, a pump for pumping out the leachate introduced into and stored in the inlet pipe to the outside, and a transfer pipe connected to the pump to transfer the leachate to the outside.

In the present invention as described above using the leachate discharge unit is adopted to forcibly discharge the leachate generated by the consolidation of the soft ground it is possible to facilitate the consolidation by discharging the leachate effectively.

In the present invention, the load by the water by embedding the settlement and the excess pore pressure gauge in the ground of the soft ground and measuring the measurement related to the settlement of the soft ground measured from these settlements and the excess pore pressure gauge by wireless or wired It is also possible to efficiently manage settlements that occur on the soft ground due to loading.

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

In the accompanying drawings, in order to explain the method for improving the soft ground according to the present invention, a dike structure 8 is formed around the soft ground 100 site, and the soft ground 100 between the dike structures 8 is disposed on the site. A schematic cross-sectional view of a state in which a sand mat 10 is installed for consolidation drainage is shown.

As illustrated in FIG. 1, a sand mat layer 10 having a predetermined thickness is disposed on the soft ground 100 to be improved for consolidation drainage. At this time, the sand mat layer 10 is provided with a known horizontal drainage material 7 horizontally for consolidation drainage in the horizontal direction, and vertically known vertical drainage material 9 for vertical consolidation drainage in the vertical direction. Install it.

As will be described later, the leachate drainage unit 11 is installed in the sand mat layer 10 in order to discharge the condensed leachate generated when the soft ground 100 is consolidated by applying a load by water. The specific structure of the leachate drainage unit 11 is mentioned later.

In the present invention, after installing the sand mat layer 10 on the soft ground 100 as described above, the water is put on the soft ground 100 is applied to the soft ground 100, the sand mat layer 10, In order to contain water in the upper portion of the sand mat layer 10 is provided with a water-order film (1). The water-repellent membrane 1 extends so as to cover the slope of the embankment structure 8, as shown in FIG. 1, so that the water loaded by the load does not penetrate into the embankment structure 8 on both sides of the soft ground.

In the present invention, as the order film 1, a hard order film having limited deformation and a flexible order film free of deformation may be used. In the case of soft ground, it is preferable to use a flexible order film free of deformation since the settlement and deformation are considerably large. Do.

However, in general, since the soft liner has a low ultimate stress, when the soft liner is used, it is necessary to take measures so that the extreme liner is not applied to the liner. This is because when the stress exceeding the ultimate stress of the insulation film 1 is applied, the insulation film 1 is damaged and water contained in the insulation film 1 leaks.

As shown in FIG. 1, when the bank structure 8 is formed on both sides of the soft ground 100, and the water barrier film 1 is provided to cover the slope of the bank structure 8, the water barrier film 1 The place where a large stress can be generated is a part where the bank structure 8 and the order film 1 are in contact with each other, and the soft ground 100 is settled in the state where the order film 1 is in contact with the bank structure 8 piled with earth and sand. As a result, displacement of the insulation film 1 is caused, and shear resistance is generated at the contact portion between the bank structure 8 and the insulation film 1 to generate a tensile force in the insulation film 1.

Therefore, in order to prevent the stress on the ordering film 1 from exceeding the ultimate stress of the ordering film 1 and preventing the ordering film 1 from being damaged, the ordering film 1 may be freely displaced according to the ground subsidence. It is important to prevent excessive stress from occurring in the insulation film 1. In the present invention has a separate configuration for this, with reference to Figures 2 and 3 to be described below an example of the specific configuration.

2 is a schematic cross-sectional view and a detailed view of the sand mat layer 10 is installed on the soft ground, and the water is not yet contained in the state in which the water-repellent film 1 is installed thereon, the detailed view of FIG. As shown in FIG. 8, a protective film 2 made of a thin geotextile or other water-repellent material is provided between the slope of the bank structure 8 and the barrier film 1 covered thereon, whereby the barrier film 1 and the bank structure 8 are disposed. Do not directly touch the soil.

In this way, when the protective film 2 is provided between the ordering film 1 and the embankment structure 8 so that the order film 1 does not directly contact the soil of the embankment structure 8, the direct contact with the soil of the embankment structure 8 is achieved. Since there is no shear resistance due to contact, even when the water repellent membrane 1 covered on the slope of the embankment structure 8 is pulled down when the soft ground 100 is settled, the direct contact between the embankment structure 8 and the water repellent membrane 1 is performed. It is possible to prevent the excessive tensile stress is applied to the order film (1) because the shear resistance does not occur due to.

On the other hand, Figure 3 is another schematic cross-sectional view and a detailed view of the sand mat layer 10 is installed on the soft ground, the water film is not yet contained in the state in which the water-repellent film 1 is installed thereon, FIG. As shown in the detailed view of FIG. 3, the portion of the liner film 1 at the portion where the bank structure 8 and the soft ground 100 meet may be formed to be corrugated.

As such, when the portion of the liner membrane 1 where the bank structure 8 and the soft ground 100 meet each other is formed to be wrinkled, even if the soft ground 100 is settled and the liner film 1 is pulled down, Since the wrinkled portion is unfolded, the shear resistance between the order film 1 and the bank structure 8 is not generated, and the excessive tensile force is prevented from occurring in the order film 1.

Next, a specific configuration of the leachate drainage unit 11 for discharging the condensed leachate generated when the soft ground 100 is consolidated by applying a load by water will be described with reference to FIG. 4.

The leachate drainage unit 11 used in the present invention is installed so that the end reaches the sand mat layer 10 through the water repellent membrane 1 and the end is formed with a through hole (not shown). An inflow pipe 4 through which the leachate flows from the mat layer 10 and is stored therein, a pump 6 for pumping out the leachate introduced into and stored in the inflow pipe 4 to the outside, and the pump 6 It is configured to include a conveying pipe (3) connected to the) to transfer the leachate to the outside.

Leachate flowing from the sand mat layer 10 by consolidation is stored in the inflow pipe 4 and is forcibly discharged to the outside through the transfer pipe 3 by the pump 6. In order to support the inflow pipe 4, a side support 5 may be installed.

In the improvement of the soft ground, the target settlement amount for the ground is calculated and determined in advance, and the magnitude of the floor load and the waiting period required for reaching the predetermined settlement amount are determined. In the improved construction process of the soft ground, it is necessary to manage the time to reach the target settlement, that is, air.

As a device for measuring the settlement of the soft ground, there is a settlement system. In general, the settlement system is fixed to one side as a reference point, and the other side is composed of measurement points that can move together with the ground. Also, the settling amount can be known by measuring the change in length between the fixed reference point and the moved measuring point as an electrical signal.

When the soft ground is loaded, the excess pore water pressure is generated in the ground. If the ground is made of sand, this excess pore water pressure is immediately dissipated, but in the clay layer, the soil's permeability coefficient is small. It takes Therefore, when the excess pore water pressure remaining on the ground is measured, it is possible to know the compactness of the soft ground. The excess pore water pressure gauge is an apparatus for measuring the excess pore water pressure in the ground. In general, the excess pore pressure gauge has a structure in which a chip and a pressure gauge are built in a tube. The pressure of water flowing into the chip is measured by measuring the deformation of the diaphragm electrically.

In the present invention, such management is performed by using the above settling system and the excess pore pressure gauge. Specifically, in the present invention, a sediment meter (not shown) and an excess pore pressure gauge (not shown) are embedded in the ground of the soft ground 100 and the soft ground 100 measured from these sediment and excess pore pressure gauges. By measuring the measurement value (sedimentation amount, excess pore water pressure) related to settlement through wireless or wired wire, it measures the degree of settlement that occurs in the soft ground 100 due to the loading of the loading load by water, Management is performed by calculating settlement patterns, remaining time until the target settlement is reached.

In the present invention, the settlement system and the excess pore pressure gauge are arranged evenly over the soft ground 100 to be improved, and may be arranged more densely where the soft layer depth changes rapidly as necessary.

In addition, in the present invention, in order to ensure the stability of the insulation film 1 under load loading by water, the insulation film 1 is managed by providing a monitoring system capable of confirming whether or not a crack occurs in the insulation film 1. Such a monitoring system itself is a known one already used in landfills, etc., and a monitoring system using an electric method or sound can be used.

For example, in the electrical insulation monitoring method, the conductivity of water is used. If there is no crack in the insulation film, the insulation film is an insulator, and thus the current is not blocked because of the current, and even though current flows through the water and the ground outside the insulation film, the current is blocked. Although it is not energized on both sides of the insulation film, if a crack occurs in the insulation film, a current flows due to leakage of water due to the crack, so that the state of the electricity supply can be detected.

On the other hand, in the case of the monitoring method using the sound by installing the acoustic plate under the curtain to measure the change in the sound wave flowing in the water before and after the occurrence of the crack to determine whether the crack of the membrane.

In the present invention, the condition of the occurrence of cracks in the insulation film is continuously monitored by using such an insulation film monitoring method. If a crack in the insulation film is detected, the diver enters the water and repairs and cracks the portion of the insulation film.

Next, when the process steps of the soft ground improvement method according to the present invention are summarized and examined, first, as described above, the embankment structure 8 having a predetermined height is formed around the soft ground 100 to be improved, and the soft ground ( The sand mat layer 10 having a predetermined thickness is disposed on the upper portion 100. At this time, as described above, in the sand mat layer 10, the horizontal drainer 7 and the vertical drainer 9 for consolidation drainage are disposed in the horizontal and vertical directions, respectively.

The liner layer 1 is covered on the laid sand mat layer 10. Then, the above-described leachate discharge unit 11 is installed so that the end portion is located in the sand mat layer 10 through the order film 1. In this way, when the installation of the sand mat layer 10 and the water repellent film 1 is completed, water is supplied to the water repellent film 1 and fresh water.

As such, when a predetermined amount of water is freshly watered on the water-repellent film 1, the self-weight of the water acts as a load on the soft ground 100, thereby forcibly consolidating the soft ground 100. Leachate generated during the consolidation process of the soft ground 100 is forcibly drained by the leachate discharge unit (11).

In the prior art using earth and sand to apply the floor load for consolidation of the soft ground, it is necessary to develop a dump site to secure the earth load for the floor load, and the development of the dump site has a problem in that it costs a lot and destroys the environment.

However, as described above, in the present invention, since the water repellent membrane 1 is installed on the soft ground 100 and the self-weight of the fresh water therein is used as the consolidation load for the soft ground 100, the conventional load is as in the prior art. It will be possible to solve the problems caused by securing the soil (increased cost, environmental damage caused by securing the site).

In particular, when the soft ground site to be improved is adjacent to the beach, seawater can be used as water for the load of the sea, so it is very easy to secure and supply the water for the load of sea water, thereby significantly reducing the cost of soil improvement. It becomes possible.

In addition, the present invention adopts a structure that can reduce the shear resistance generated between the embankment structure around the soft ground and the order film in accordance with the settlement of the soft ground in order to provide the over-tension due to the shear resistance Due to this, it is possible to prevent damage to the barrier.

In addition, the present invention adopts a configuration for forcibly discharging the leachate generated by the consolidation of the soft ground can facilitate the consolidation by discharging the leachate effectively, and the sedimentation system and excess gap buried in the ground of the soft ground By measuring the degree of settlement of the soft ground 100 through a hydraulic meter, not only can it be efficiently managed, but it is also equipped with a monitoring system that can check whether or not a crack occurs in the insulation film 1, and thus the insulation film 1 is managed by managing the insulation film 1 The stability of (1) can be ensured. Therefore, the soft ground improvement method according to the present invention can be used on a large scale site.

In addition, in the present invention, since the embankment structure 8 is formed around the soft ground 100, and water acts as a load on the soft ground, consolidation of the soft ground occurs due to the loading of the soft ground. When the 100 is gradually settled, only the water that acted as a load on the embankment structure 8 is left as it goes down with the soft ground (100). Therefore, the space to hold water over the soft ground 100 is more secured, and more water is contained in the secured space, so that it can be applied as a load of the floor, and thus it can be particularly effectively applied to the improvement of a large-scale site.

Claims (6)

Laying a sand mat layer 10 on top of the soft ground 100 to be improved; Forming a levee structure 8 having a predetermined height on the side of the soft ground 100; A water barrier film (1) is provided on the sand mat layer (10) so as to cover the bank structure (8); In order to forcibly discharge the leachate generated during the consolidation process of the soft ground 100, the leachate discharge unit 11 so that the end portion of the leachate discharge unit 11 penetrates the water barrier film 1 to reach the sand mat layer 10. ), The leachate discharge unit (11), the inlet pipe is formed at the end of the inlet pipe (4) and the leachate flows into and stored from the sand mat layer 10 through the through hole and the inlet pipe ( 4) a pump 6 for pumping out the leachate introduced into and stored in the outside and discharged therein; and a conveying pipe 3 connected to the pump 6 to transfer the leachate to the outside; Improvement of the soft ground, characterized in that to promote consolidation of the soft ground 100 by applying the weight of the fresh water to the load of the soft ground 100 by desalination of a predetermined amount of water in the space formed by the installation of the water repellent membrane 1. Method. The method of claim 1, Soft ground improvement method characterized in that the protective film (2) for preventing shear resistance is provided between the order film (1) and the embankment structure (8) so as not to directly contact the soil of the embankment structure (8). The method of claim 1, As the soft ground 100 is settled, the soft membrane is characterized in that it is formed to wrinkle the portion of the order membrane (1) of the portion where the bank structure (8) and the soft ground 100 meets so that the order membrane (1) can be deformed. Ground Improvement Method. delete delete The method according to any one of claims 1 to 3, By embedding the settlement and the excess pore pressure gauge in the ground of the soft ground 100 and measuring the measurements related to the settlement of the soft ground 100 measured from these settlements and the excess pore pressure gauge by wireless or wired, Soft ground improvement method, characterized in that the management of the settlement that occurs in the soft ground (100) due to the load.