KR20110120084A - A method and apparatus of siphon type suction drain for soft ground improvement - Google Patents

Abstract

PURPOSE: Device and method for improving weak ground in a siphon manner using vacuum pressure and natural-ground's water pressure are provided to increase lost vacuum pressure using the water pressure on the lower part of the underground water of natural-ground. CONSTITUTION: A method for improving weak ground in a siphon manner using vacuum pressure and natural-ground's water pressure is as follows. A vertical drain member is placed on weak ground and is coupled to a horizontal pipe installed on the upper part using a connector. The horizontal pipe is connected to an integral vacuum pressure loading device through a connecting pipe jointed at the lower part of the underground water of natural ground. The integral vacuum pressure loading device can load in a vacuum state and collect and drain water. Vacuum pressure applied through the vacuum pressure loading device is transferred to ground through the connecting pipe, the horizontal pipe, the connector and the drain member.

Description

Soft ground improvement apparatus using siphon method and vacuum method using vacuum pressure and ground pressure {A method and apparatus of siphon type suction drain for soft ground improvement}

The present invention relates to a siphon (Siphon) soft ground improvement apparatus using the vacuum pressure and the ground pressure, and more particularly, to compensate for the lost vacuum pressure or atmospheric pressure in the existing vacuum consolidation method, ground ground water The present invention relates to a vacuum loading device that penetrates the upper and lower parts and a method thereof to increase the lost vacuum pressure by using the water pressure of the lower ground water level in addition to the vacuum pressure used in the existing technology.

Kjellman (1952) proposed vacuum pressure condensation method is to discharge the gap water in the ground using atmospheric pressure by operating the vacuum pump after installing the sand mat and covering the airtight seat after installing drainage material on the soft ground. The vacuum consolidation method is about 65 ~ 75% efficient due to the reduction of the pump efficiency due to long time operation, the quality problem of the cover (sealing sheet) covering the ground, and the tightness of the connection between the end of the barrier and the ground. Only (Cortlever, 2002).

To solve this problem, an individual vacuum consolidation method (Patent No. 0679601) has been developed and applied. The individual vacuum consolidation method is to make each vertical drainage into a vacuum state and to use the atmospheric pressure of the upper portion as a reloading load. The tank separation tank, which is the loading device, is reached. However, the horizontal pipe, the header pipe, and the separation tank are located above the groundwater surface where atmospheric pressure is applied, so the head difference from the upper groundwater level to the separation tank valve must be overcome. In general, the head difference is about 2.0 tf / m ² when the pressure is converted to about 2.0 m. Therefore, the conventional vacuum consolidation method inevitably cannot load the lost pressure, so only the atmospheric pressure of about 8.0 tf / m ² is obtained. It is used as a load.

The main differences between the present invention and the existing techniques are shown in Table 1. As shown in Table 1, in the conventional technology, while the vacuum pressure is applied at the upper groundwater level due to the separation pipe and the header pipe installed on the ground, which is the upper groundwater level, in the present invention, the header pipe used in the existing technology to form a siphon is used. Without using, horizontal pipes were connected directly to the groundwater level below the groundwater separation tank. By employing the siphon method as described above was able to apply a vacuum pressure in the lower ground water level. Therefore, although the conventional technique adopts a continuous vacuum pressure applying method to apply a vacuum pressure to the ground, in the present invention has the advantage that the base can be dehydrated only by applying a single vacuum pressure under the condition that no leakage occurs.

Main differences between the existing technology and the present invention division Existing technology Invention concept

Consolidation load
(Usage load) Vacuum Vacuum Pressure + Ground Pressure
Main material Vacuum pump Vacuum pump Submersible pump Submersible pump Separation tank Separation tank Heather pipe not needed Location of vacuum loading device Above ground or groundwater level Underground or groundwater level

The individual vacuum consolidation method uses each vertical drainage to make a vacuum and uses the atmospheric pressure of the upper part as a reloading load. A water separation tank is reached. However, the horizontal pipe, the header pipe, and the separation tank are located above the groundwater surface where atmospheric pressure is applied, so the head difference from the upper groundwater level to the separation tank valve must be overcome. The water head difference is generally about 2.0 tf / m ² when converted into pressure at a pressure of about 2.0 m. In the conventional vacuum consolidation method, the above pressure cannot necessarily be loaded, so only the atmospheric pressure of about 8.0 tf / m ² I use it.

In the present invention, in order to compensate for the loss vacuum pressure or atmospheric pressure in the existing vacuum consolidation method, a vacuum load device that is introduced into the ground ground water level or lower and proposed the method used in the existing technology, in addition to the vacuum pressure in addition to the ground pressure ground water ground Using the water pressure of to increase the lost vacuum pressure.

The present invention for achieving the above object is characterized in that the vacuum loading device and the method that can be used in addition to the vacuum pressure used in the existing technology by underground infiltration to the bottom of the ground ground water level when applying the vacuum consolidation method .

As described above, if the underground penetration vacuum load device proposed by the present invention is used, the siphon method using the ground pressure in addition to the vacuum pressure used in the existing technology will be applied, and the effect of soft ground improvement will be greatly increased. .

1 is an exemplary conceptual view showing a front structure of a conventional vacuum consolidation method.
2 is a theoretical conceptual view of a conventional vacuum consolidation method.
Figure 3 is a plan view showing a soft ground improvement device of the siphon (Siphon) method using the vacuum pressure and the ground pressure of the present invention.
Figure 4 is a front view showing a siphon (Siphon) soft ground improvement device using the vacuum pressure and the ground pressure of the present invention.
5 is a conceptual diagram of a soft ground improvement method of the siphon (Siphon) method using the vacuum pressure and the ground pressure of the present invention.

In order to achieve the above object, the present invention focuses on the fact that the method of imparting a vacuum pressure at the upper groundwater level cannot overcome the head loss up to the upper groundwater level. Solved as follows.

First, the accompanying drawings will be described.

Figure 3 is a plan view showing a siphon (Siphon) soft ground improvement device using the vacuum pressure and the ground pressure of the present invention, Figure 4 is a siphon (Siphon) soft ground using the vacuum pressure and the ground pressure of the present invention It is a front view which shows the improvement apparatus, and FIG. 5 is a conceptual diagram of the soft ground improvement method of the siphon system which uses the vacuum pressure and the ground hydraulic pressure of this invention.

The present invention will be described in comparison with the prior art, Figure 1 is an exemplary conceptual diagram showing the front structure of the existing vacuum consolidation method, Figure 2 is a theoretical conceptual diagram of the existing vacuum consolidation method.

As shown in Figure 1 and Figure 2, the conventional individual vacuum consolidation method is to cast the vertical drainage 11 on the soft ground (1), it is coupled using the horizontal pipe 13 and the connector 12 installed on the top The horizontal pipe 13 is connected to a vacuum loading device 17 in which a vacuum pump and a water separation tank are coupled through a header pipe 16 as a water collecting device. The vacuum pressure applied through the vacuum loading device 17 is transmitted to the ground through the header pipe 16, the horizontal pipe 13, the connector 12, and the drain 11. When the vacuum pressure is transmitted to the ground, the atmospheric pressure acting on the ground ground water level 18 becomes a reload, which causes the effluent 100 to move upward through the drain 11 and the connector 12 and the horizontal pipe ( 13 is drained to the header pipe 16, the separation tank 17. The effluent reaching the water separation tank is drained to the outside through the submersible pump. However, the outflow water rising from the ground in the above process should be drained above the ground ground water level 18, and eventually must overcome the head difference 19 between the valve on the top of the separation tank and the ground ground water level 18. Therefore, vacuum pressure may be utilized, some possible vacuum pressure of about 10tf / m ² using a maximum to overcome the water head difference (19) has a problem that reduces to about 8tf / m ^2.

The theoretical conceptual diagram applied to the above existing technology is shown in FIG.

Applying the vacuum consolidation method, under the condition that there is no loss of vacuum pressure, atmospheric pressure (20) and hydrostatic pressure (21) acts in the ground, and the separation tank (17) from the base ground water level (18) to the base separation tank (17) The internal vacuum pressure 22 and the hydraulic pressure 23 act. However, since the fluid pressure in the lower part of the groundwater level and the fluid pressure in the upper part have an adverse effect on each other, the fluid pressure difference acts only up to the sum of (24) and (25), and the loss of (26) is generated. .

On the other hand, look at Figures 3 and 4 showing the present invention as follows.

Placing vertical drainage material 11 on the soft ground (1), using the horizontal pipe 13 and the connector 12 installed on the upper, the horizontal pipe (13) is a connection pipe that is incorporated in the lower ground ground water level It is connected to the vacuum load (32, 41) and the integrated vacuum load device 30 capable of collecting and draining through the (39). The vacuum pressure applied through the vacuum loading device 30 is transmitted to the ground through the connection pipe 39, the horizontal pipe 13, the connector 12, the drain 11. When the vacuum pressure is transmitted to the ground, the atmospheric pressure acting on the ground ground water level 18 becomes a reload, and the various pipes are in a vacuum state, and the effluent 100 is moved upward by riding the drain 11 and the connector 12 ) And the horizontal pipe 13, the connection pipe 39 to reach the vacuum loading device (30). The outflow water reaching the vacuum loading device 30 is drained through the submersible pump 34 and the pipes 40 and 31.

The theoretical conceptual diagram applied in the present invention is shown in FIG. The vacuum consolidation method is applied, and under the condition that there is no loss of vacuum pressure, atmospheric pressure 44 and hydrostatic pressure 45 act on the inside of the ground, and vacuum pressure inside the vacuum loading device infiltrated to the lower ground water level 18 below. 46 and the hydraulic pressure 47 act. Unlike the conventional technology, the vacuum pressure and the water pressure act as the fluid pressure at the bottom of the groundwater level, so that the fluid pressure difference acts as the sum of the 48, 49, and 50.

1: Soft ground (ground to be improved) 11: Vertical drainage
12: drain pipe and horizontal pipe connection connector 13: horizontal pipe
14: drain material vent 15: anchor plate
16: header pipe
17: equipped with vacuum pump and separation tank 18: groundwater level in the ground
19: head level in the ground level and head separation tank
20: Atmospheric pressure distribution (theoretical 1atm) 21: Hydrostatic pressure distribution by depth
22: Pressure distribution inside the separation tank (theoretical 1atm)
23: Distribution of water pressure in the separation tank
24: barometric pressure distribution acting on the ground
25: Distribution of water pressure acting on the ground
26: Loss vacuum pressure due to separation of tank and ground level (23)
31: vacuum pump connector
32: submersible pump or drainage pipe
33 valve 34 submersible pump
35: Level inside the tank with vacuum and water separation
36: gas space inside the tank with vacuum and water separation
37: foreign matter precipitation area
38: penetration or type rod
39: tank and horizontal piping connector
40: submersible pump or drain pipe
41: vacuum pump connector 42: tank lifting hook
43: difference between ground level and tank connector
44: Atmospheric pressure distribution (theoretical 1atm) 45: Hydrostatic pressure distribution by depth
46: Pressure distribution inside the integrated tank (theoretical 1atm)
47: hydraulic pressure distribution inside the integrated tank
48: Barometric pressure distribution acting on the ground (theoretical 1atm)
49: Hydraulic pressure distribution on the ground
50: hydraulic pressure distribution (43) acting as an additional load
100: flow path of water (effluent water) 101: gas flow path

Claims (2)

In the improvement method of soft ground,
Placing a vertical drainage material (11) on the soft ground (1), and combining the horizontal pipe (13) and the connector (12) installed on the upper portion;
The horizontal pipe 13 is connected to the vacuum load (32, 41) and the integrated vacuum load device 30 capable of collecting and draining through the connection pipe 39 is incorporated in the lower ground water level;
Vacuum pressure applied through the vacuum loading device (30) is transmitted to the ground through the connection pipe (39), horizontal pipe (13), connector (12), drain material (11);
When the vacuum pressure is transmitted to the ground, the atmospheric pressure acting on the ground ground water level 18 becomes a reload, and the various pipes are in a vacuum state, and the effluent 100 moves upward through the drainage material 11 so that the connector 12 And reaching the vacuum loading device 30 through the horizontal pipe 13 and the connection pipe 39;
The effluent using the vacuum pressure and the ground hydraulic pressure, characterized in that the effluent reaches the vacuum loading device 30 is sequentially performed, including the step of being drained through the submersible pump 34 and the pipes (40, 31). Soft ground improvement method of method. In the apparatus used for the method of claim 1,
Vertical drainage (11) is poured into the soft ground (1), the horizontal pipe 13 and the connector 12 is fastened to the upper portion of the vertical drain (11), the horizontal pipe (13) in the lower ground ground water level It is connected to the vacuum load (32, 41) and the integrated vacuum load device 30 that can be housed, drained through the connection pipe 39 is incorporated, while the vacuum pressure applied through the vacuum pressure load device (30) is connected The siphon (Siphon) soft ground improvement device using a vacuum pressure and ground pressure, characterized in that it is transmitted to the ground through the pipe (39), horizontal pipe (13), connector (12), drain material (11).

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