KR101818949B1 - Construction method of pile type groundwater collector - Google Patents

Abstract

The present invention relates to a water collecting facility for collecting groundwater and storing the same. A storage tank (20) supported on the basis of a plurality of hollow piles (10) is constructed on upper ends of the hollow piles (10) of which lower portions are located on an aquifer, and a water transmission pipe (30) connected to a pump (35) is installed in the hollow piles (10) such that groundwater introduced into the lower portions of the hollow piles (10) is conveyed to the water transmission pipe (30) to be stored in the storage tank (20). According to the present invention, it is possible to construct a groundwater collecting facility without an operators underground or underwater operation. Moreover, it is possible to drastically reduce an amount of ground excavation compared to the prior art, and to stably support the storage tank (20).

Description

TECHNICAL FIELD [0001] The present invention relates to a pile type groundwater collecting facility,

The present invention relates to a water collecting facility for collecting and storing ground water, wherein a storage tank (20) having a plurality of hollow piles (10) located at a lower portion thereof and supported by a hollow pile (10) A water pipe 30 connected to a pump 35 is installed in the hollow pile 10 so that groundwater flowing into the lower portion of the hollow pile 10 is pumped by the water pipe 30 and stored in the storage tank 20.

The groundwater intake system can be constructed in various ways considering the ground conditions such as the structure of the aquifer. In the case of the aquifer in which the impervious layer is formed on the upper part of the aquifer, the tubular type is mainly applied and the free water surface The aquifer type is mainly applied to the aquifer, and the related art related to the groundwater intake system is the patent 690396.

As described in Patent No. 690396, the conventional free water surface aquifers groundwater collecting facility represented by radial collecting is advantageous in that it can efficiently receive groundwater reared in a wide area, but in construction and maintenance There are various problems.

First, in the conventional collecting, the collecting body, which is a large vertical pipe body, must be buried up to the deep part of the aquifer, which involves a large scale excavation, which requires a large construction cost.

Particularly, in the conventional collecting method, in order to promote the horizontal intake pipe, it is necessary to secure the internal space of the main body exceeding the scale required for the actual planned water amount, and the large diameter caisson is preceded by the large size special equipment And a large amount of soil is generated in the construction process, so that the earthworks cost can not be increased, and the air has a serious problem that must be extended.

In addition, since the conventional method for recovering the horizontal intake pipe of the present invention can not be performed in a narrow space inside the main body of the collecting apparatus, it requires a highly skilled manpower, requires a long period of air, .

The present invention has been made in view of the above-mentioned problems, and it is an object of the present invention to provide a hollow pile (10) A water storage tank 20 supported by the hollow pile 10 is installed at the upper end and a water supply pipe 30 connected to the pump 35 is installed inside the hollow pile 10. The lower end of the water supply pipe 30 is connected to a hollow pile And the discharge port 37 at the upper end of the water pipe 30 is located in the upper part of the storage tank 20 so that the ground water flowing into the lower portion of the hollow pile 10 is fed by the water pipe 30, And is then stored in the storage tank 20, which is a pile-type groundwater collecting facility.

The reservoir 20 has a bottom plate 21 joined to the upper end of the hollow pile 10 and a wall 22 and a wall 22 formed on the bottom plate 21 to project toward the center of the storage tank 20 And the upper end of the water pipe 30 is curved downward after passing through the deck 23 so that the discharge port 37 is positioned below the deck 23. [ to be.

In the method of constructing the pile-type groundwater collecting facility, a plurality of coupling holes 19 are formed on the upper portion of the hollow pile 10, a plurality of coupling holes 89 are formed in the upper portion, The hollow pile 10 is inserted into a steel recovery pipe 80 having an inner diameter equal to or greater than the outer diameter of the hollow pile 10. The hollow pile 10 is inserted into the coupling hole 89 of the return pipe 80 and the coupling hole 19 The upper end of the recovery pipe 80 is attached to the casing drive unit 93 of the pile driver 90 and the upper end of the recovery pipe 80 is attached to the casing drive unit 93 of the pile driver 90, (S10) in which the excavator (91) is introduced into the hollow pile (10) and pushed into the ground while the return pipe (80) and the hollow pile (10) A separating step S21 for separating the recovery pipe 80 from the hollow pile 10 by removing the coupling pin 85 when the target pile 10 reaches the target depth, A recovery step S22 of raising the east portion 93 to withdraw the recovery pipe 80 and a water supply pipe 30 connected to the pump 35 inside the hollow pile 10, And a facility step (S40) for constructing a pile-type groundwater collecting facility (20).

After the recovery step S22 is completed, a granular body 15 is poured into the hollow pile 10 to fill the granular body 15 at the lower inner end of the hollow pile 10. [ The filling step S30 is carried out and the facility step S40 is performed after the granular material input step S30 and the construction method of the pile type groundwater collecting facility.

The groundwater collecting facility can be constructed without the operator's underground work or underwater work, the ground excavation amount can be drastically reduced compared to the prior art, and the storage tank 20 can be stably supported .

Particularly, it is possible to construct the storage tank 20 having a sufficient capacity even without excavation of the large-diameter vertical shaft, and the hollow pile 10 penetrated into the ground has the basic role of the groundwater transfer route and the storage tank 20, It is possible to obtain effective groundwater intake and to secure the structural stability of the entire facility.

In addition, since the structure penetrated into the aquifer is constructed in the same manner as a conventional pile, simple and quick construction can be accomplished only by a general-purpose pile driver 90, which can shorten the air and reduce the construction cost.

BRIEF DESCRIPTION OF THE DRAWINGS Fig.
Figure 2 is a cross-
3 is a cutaway perspective view of the reservoir extract portion of the present invention
4 is a perspective view of a hollow pile and a recovery pipe of the present invention
FIG. 5 is a diagram illustrating a state in which a pile of a hollow pile and a return pipe of the present invention are fitted with a pile driver
FIG. 6 is a diagram illustrating a construction process of the present invention
Fig. 7 is an explanatory diagram of a particle filled type embodiment of the present invention

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 1, the present invention comprises a storage tank 20 including a wall 22, a bottom plate 21, and the like, a storage tank 20, And a plurality of hollow piles 10 joined to the lower end.

The present invention is installed in the ground where the aquifer layer is formed, and collects the groundwater and collects the groundwater, and is installed in the structure as shown in Fig.

That is, as shown in FIG. 2, a plurality of hollow piles 10 in a lower part of the aquifer are introduced into the ground in an upright state, and the upper part of the hollow pile 10 is supported by a hollow pile 10 A water storage tank 20 is installed and a water pipe 30 to which a pump 35 is connected is installed inside the hollow pile 10. The lower end of the water pipe 30 is located below the hollow pile 10, The upper discharge port 37 is located on the upper side of the inside of the storage tank 20 so that the ground water flowing into the lower portion of the hollow pile 10 is transported by the water supply pipe 30 to be discharged to the discharge port 37, will be.

Although not shown in the accompanying drawings, the storage tank 20 is formed with an outlet port for discharging the stored groundwater to the outside, and a water pipe connecting the outlet port and the consumer can be connected.

The hollow pile 10 of the present invention is a tubular pile having an open upper end and a lower end and can be applied with a precast concrete pile or steel pipe pile or the like. In the case of the free water surface aquifers as in the embodiment illustrated in FIG. 1, the lower end of the hollow pile 10 is penetrated below the groundwater level so that the groundwater around the hollow pile 10 is hollow Flows into the pile (10), and is then pumped to the water pipe (30).

2, a submersible pump 35 is used as a pump 35 connected to the water pipe 30 so that the pump 35 is connected to the lower end of the water pipe 30 and the hollow pile 10 The pump 35 sucks the inflowing groundwater and feeds the inflowing groundwater to the water pipe 30. If the depth of the aquifer is not deep, the pump 35 may be installed on the ground, for example, inside the storage tank 20.

The storage tank 20 constructed above the hollow pile 10 is a facility for storing the ground water pumped through the water pipe 30 and is provided with a bottom plate 21 and a wall 22 as shown in FIGS. It can be made of concrete as well as synthetic resin if it is built in small scale.

Since the reservoir 20 of the present invention can be constructed in a state in which the reservoir 20 is constructed directly on the ground or the reservoir is made small and the collected groundwater is stored, a considerable self weight may act. As described above, 20 and the hollow pile 10 are joined to each other so that the hollow pile 10 can exhibit the frictional force and the tip end supporting force and act as a foundation of the storage tank 20 to stably support the storage tank 20.

That is, in the present invention, the hollow pile 10 has a role as a path connecting an aquifer in the ground to the ground and a role as a foundation of the storage tank 20, thereby constructing an underground storage facility with a large- While avoiding the structural stability of the storage facilities.

2 and 3, the wall 22 of the inventive reservoir 20, which is composed of a bottom plate 21 joined to the upper end of the hollow pile 10 and a wall 22 constructed above the bottom plate 21, A deck 23 protruding from the inner surface of the wall body 22 toward the center of the storage tank 20 is formed in the deck 23. The upper end of the water pipe 30 passes through the deck 23 and then curves downward, The flow of the groundwater stored in the storage tank 20 back to the water pipe 30 is prevented by preventing the foreign matter from flowing into the water pipe 30 in a state where the operation of the pump 35 is stopped. Respectively.

3, the deck 23 formed on the storage tank 20 of the present invention is a planar annular plate, and a valve or the like may be installed on the curved portion of the water pipe 30 formed on the deck 23 A control panel or the like for controlling the pump 35 may be installed in the deck 23 and a valve or a control panel may be installed on the deck 23 so that even when groundwater is stored in the storage tank 20 The valve and the control panel can be easily operated.

4, by piercing a plurality of water holes 11 at the lower end of the hollow pile 10, smooth groundwater inflow can be achieved. In the case of the concrete hollow pile 10, There is a possibility of fracture or brittle fracture. Therefore, as shown in the drawing, a recovery pipe 80 for covering and protecting the hollow pile 10 in the course of in-ground pumping may be combined.

That is, instead of installing the hollow pile 10 alone in the pile driver 90 and penetrating the ground, the hollow pile 10 is inserted into the steel recovery pipe 80 as shown in FIG. 5 The construction method in which the recovery pipe 80 and the hollow pile 10 are connected to each other and then the recovery pipe 80 is mounted on the pile driver 90 and is introduced into the ground is applied. 6, the hollow pile 10 is inserted into a steel recovery pipe 80 having a plurality of engagement holes 89 formed therein at an upper portion thereof and having an inner diameter larger than the outer diameter of the hollow pile 10, The coupling pin 85 is fastened to the coupling hole 89 of the pipe 80 and the coupling hole 19 of the hollow pile 10 to bind the hollow pile 10 and the recovery pipe 80 together, The upper end of the hollow pile 10 is inserted into the casing drive part 93 of the pile driver 90 and the excavator 91 is pushed into the hollow pile 10 to pour into the hollow pile 10, (Step S10), which is a step involving the simultaneous penetration into the ground.

4, a plurality of binding holes 19 are formed on the upper portion of the hollow pile 10 and a plurality of coupling holes 89 are drilled on the upper portion of the return pipe 80, The coupling pin 89 of the recovery pipe 80 and the coupling hole 19 of the hollow pile 10 are coupled with the coupling pin 80 in the state where the hollow pile 10 is inserted into the return pipe 80, The outer circumferential surface of the hollow pile 10 is covered and protected by the recovery pipe 80. The recovery pipe 80 and the hollow pile 10 are connected to each other.

The installation of the pile pipe 80 and the pile driver 10 to the pile driver 90 is performed by binding the upper end of the recovery pipe 80 with the hollow pile 10 to the casing drive part 93 of the pile driver 90 In this state, the lower end of the recovery pipe 80 is positioned at the planned installation point, and then the casing driving unit 93 and the excavator driving unit 92 are lowered to move the excavator to the inside of the hollow pile 10. [ 91) digging the ground and collecting the return pipe 80 and the hollow pile 10 together.

When the recovery pipe 80 and the hollow pile 10 reach the target depth and the lower part of the hollow pile 10 is located in the aquifer, the coupling pin 85 is removed and the recovery pipe 80 and the hollow pile 10 The hollow pile 10 is lifted up the casing driving part 93 in a state where the hollow pile 10 remains in the ground and a collection step S22 for drawing out the recovery pipe 80 is performed So that only the hollow pile 10 remains intruded in the ground where the aquifer is formed

When the collection step S22 is completed, a facility step S40 is performed in which the water pipe 30 connected to the pump 35 is inserted into the hollow pile 10 and a storage vessel 20 is constructed at the upper end of the hollow pile 10 Thereby completing the groundwater collecting facility of the present invention.

7 shows a state in which the particle 35 serving as a particulate filter medium is filled in the inner lower end of the hollow pile 10 to suppress the closure of the pump 35 and the water supply pipe 30 due to the inflow of the particles. After the recovery step S22 is completed, the granular body 15 is poured into the hollow pile 10, and the granular body 15 filling the inner bottom of the hollow pile 10 is charged Step S30 is performed, and after the granular material input step S30, the facility step S40 is performed, thereby completing the granular object 15 filled embodiment of the present invention.

10: hollow pile
11: water ball
15:
19: bond ball
20: Storage tank
21:
22: Wall
23: Deck
30: water pipe
35: Pump
37: Outlet
80: Recovery pipe
85:
89: Coupling ball
90: File driver
91: Excavator
92: excavator driving section
93: casing driving part
S10: Accompanying step
S21: Separation step
S22:
S30: Grain filling step
S40: Facility stage

Claims (4)

A plurality of hollow piles 10 in a lower part of the aquifer are introduced into the ground in an upright state and an upper part of the hollow pile 10 is connected to a storage tank 20 And a water pipe 30 connected to the pump 35 is installed inside the hollow pile 10. The lower end of the water pipe 30 is located below the hollow pile 10, The groundwater pumped by the water pipe 30 is discharged to the discharge port 37 and then stored in the storage tank 20, In a method for constructing an underground water collecting facility,
A plurality of binding holes 19 are formed on the upper portion of the hollow pile 10;
The hollow pile 10 is inserted into a steel recovery pipe 80 having a plurality of engagement holes 89 at its upper portion and having an inner diameter equal to or greater than the outer diameter of the hollow pile 10, The coupling pin 85 is fastened to the coupling hole 89 of the hollow pile 10 and the coupling hole 19 of the hollow pile 10 to bind the hollow pile 10 and the recovery pipe 80 together, Is installed in the casing drive part 93 of the pile driver 90 and the excavator 91 is introduced into the hollow pile 10 and pushed into the ground while the return pipe 80 and the hollow pile 10 are co- A penetration step S10;
A separation step S21 for separating the recovery pipe 80 and the hollow pile 10 by removing the coupling pin 85 when the recovery pipe 80 and the hollow pile 10 reach the target depth;
The hollow pile 10 includes a collection step S22 for raising the casing drive part 93 and withdrawing the recovery pipe 80 while remaining in the ground;
And a facility step (S40) of charging a water pipe (30) connected to a pump (35) inside the hollow pile (10) and constructing a storage tank (20) at the upper end of the hollow pile (10) Construction method of facility.
The method according to claim 1, wherein, after the collecting step (S22)
A granular body 15 is inserted into the hollow pile 10 to fill the granular body 15 at the inner lower end of the hollow pile 10;
Wherein the facility step (S40) is performed after the granular material input step (S30). delete delete

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