KR102136256B1 - Rainwater storage tank construction method using top-down method - Google Patents

Abstract

The present invention is a simple process and relates to a method of constructing a rainwater storage tank using a top-down method to easily construct a rainwater storage tank into a basement of a desired depth, and this construction method primarily involves excavating a target ground to first circular excavation. A primary excavation step (S10) to be formed, a primary segment installation step (S20) to install a primary segment in the primary circular excavation part, and a slab construction to construct a concrete slab on the ground around the primary segment Step (S30), a primary segment fixing step (S40) for fixing the primary segment to the slab, a secondary digging step (S50) for excavating the ground below the primary segment, and the primary segment Secondary segment installation step (S60) of installing a secondary segment at the bottom of the, and filling the inner wall filling step of fixing the secondary segment by injecting concrete between the inner wall of the primary circular digging part and the outer circumferential surface of the secondary segment (S70), the second excavation step (S50), the secondary segment installation step (S60) and the rainwater storage tank construction completion step (S80) repeatedly performing the inner wall filling fixing step (S70), and the primary excavation step ( It includes a continuous construction step (S90) of the rainwater storage tank repeatedly performed from S10) to the completion of the rainwater storage tank construction step (S80), and a drain pipe connection step (S100) connecting a drain pipe between the rainwater storage tanks.

Description

Rainwater storage tank construction method using the top-down method{RAINWATER STORAGE TANK CONSTRUCTION METHOD USING TOP-DOWN METHOD}

The present invention relates to a method of constructing a rainwater storage tank, and more particularly, to a rainwater storage tank construction method using a top-down method that allows a simple process and a depth of depth to easily construct a rainwater storage tank.

In general, the construction method of constructing a rainwater storage tank is to construct a earth wall by first constructing a mudguard facility with steel materials such as sheet piles or H beams on the ground, and then excavating the ground within the earth wall to a certain depth, and then construct a concrete structure on the excavation wall surface. Construct from bottom to top.

Here, in the conventional method for constructing a rainwater storage tank as described above, first, to construct a rainwater storage tank underground, construct a temporary steel mudguard facility on the excavation target ground, and then excavate the ground after the earthwall, which is the temporary mudguard facility, is formed to a certain depth. It is to collectively form a vertical water structure from the bottom to the top.

Particularly, the construction method of the above-mentioned mudguard installation facility has a very large construction cost increase factor, because it takes a lot of time and money to construct the mudguard construction site to form the earth wall, and the larger the excavation area of the ground, the larger the size of the temporary installation facility due to soil pressure. .

Also, in order to confirm the safety of the above provisional facilities, follow-up measures such as measurement must be carried out throughout the construction period, and the construction of the underground rainwater storage tank must also be constructed from the bottom, so the construction is complicated, complex, and even after the completion of the rainwater storage tank. As the cost and manpower are also incurred for the removal of temporary facilities, the construction of a traditional rainwater storage tank is very uneconomical and the construction is very complicated.

Registered Patent No. 1411989 "Assembly rainwater storage unit module and rainwater storage construction method using the same" (2014.06.19.)

Accordingly, the present invention has been devised to solve the above-mentioned conventional problems.

An object of the present invention is to provide a method for constructing a rainwater storage tank using a top-down method that enables a simple process and a construction of a rainwater storage tank to a desired depth underground.

In order to achieve the above object, "a rainwater storage tank construction method using a top-down method" according to the present invention comprises: a primary excavation step of excavating circularly with an excavator on a target ground; A primary segment installation step of assembling an arc-shaped primary segment made of concrete along the inner circumferential surface of the primary circular excavation part formed in the primary excavation step to form a tubular inner wall; A slab construction step of placing concrete on the upper surface of the target ground and curing the concrete slab to surround a part of the outer surface of the primary segment around the primary circular excavation part; A primary segment fixing step of interconnecting the primary segment with the slab so that the primary segment is fixed to the concrete slab; A second excavation step of excavating circularly with an excavator to have a relatively wide inner diameter than a tubular inner wall formed by the primary segment below the primary segment fixed to the slab; Secondary segments installed to form the inner wall of the tubular by assembling the secondary segments of circular arcs made of concrete along the inner circumferential surface of the secondary circular excavation formed in the secondary excavation step, by assembling the primary segments up and down. An installation step; By injecting concrete with high pressure inward through a through hole formed horizontally through the secondary segment to fill the empty space between the secondary segment and the inner wall of the secondary circular excavation, curing the concrete filled in the empty space An inner wall filling fixing step of fixing the secondary segment to the inner wall; Including, the second excavation step, the second segment installation step and the inner wall filling fixing step; A rainwater storage tank construction completion step of repeatedly completing the construction of the rainwater storage tank by repeatedly performing the second excavation step, the second segment installation step, and the inner wall filling fixing step; A rainwater storage tank continuous construction step of repeatedly performing the rainwater storage tank at least two or more successively from the first excavation step to the completion of the rainwater storage tank construction step; A drain pipe connection step of interconnecting a drain pipe between the rainwater storage tanks so that water flows between the plurality of rainwater storage tanks constructed; It is characterized by including.

In addition, in the step of connecting the drain pipe of the "how to construct a rainwater storage tank using a top-down construction method" according to the present invention, the drainage pipe is gradually lowered so that it gradually increases from the rainwater storage tank on one side to the rainwater storage tank on the other side. Method

In addition, in the primary segment installation step of the "rainwater storage tank construction method using a top-down method" according to the present invention, the primary segment is positioned relatively higher than the primary circular excavation, and the primary segment and secondary The segment includes a first segment formed of an arc-shaped plate, four of which are continuously connected to the side by bolt fastening, and which can be interconnected up and down by bolt fastening; A second segment connected to one side of the first segment of which four are continuously connected by a bolt fastening, a first inclined surface is inclined to the outside, formed of an arc-shaped plate, and can be interconnected vertically; A third segment connected to the other side of the first segment in which four are continuously assembled, a second inclined surface inclined to the outside, formed of an arc-shaped plate, and mutually connected to each other up and down; Corresponding inclined surfaces are formed on both sides to be in close contact with the first inclined surface and the second inclined surface, and are connected by bolting between the second segment and the third segment to form a cylinder, formed into an arc-shaped plate, up and down A fourth segment that can be interconnected; It is characterized by including.

In addition, in the step of fixing the primary segment of the "rainwater storage tank construction method using a top-down method" according to the present invention, the primary segment is anchored to the slab through a through hole formed horizontally through the primary segment. It is fixed, and in the second excavation step, the excavation depth is characterized in that the second segment is excavated to a depth that is connected to two to four vertically.

As described above, the present invention has an effect of ensuring the simplicity and speed of construction in spite of being a large underground construction structure by easily constructing a rainwater storage tank into a basement of a desired depth while being a simple process.

1 is a step view showing a construction method according to the invention,
2 to 11 is a schematic configuration diagram showing a construction method according to the invention,
12 is a schematic perspective view showing a connection state of segments according to the present invention;
13 is a schematic longitudinal sectional view of FIG. 12,
14 is a schematic longitudinal sectional view of a main part showing a connection state of segments according to the present invention;
15 to 18 are schematic front views showing a segment according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings. However, it should be understood that the present invention can be implemented in many different forms and is not limited to the described embodiments.

1 to 11 are schematic views showing a construction method according to the present invention. As shown in this, the method for constructing a rainwater storage tank using the top-down construction method according to the present invention is primarily a primary excavation step (S10) of excavating a target ground to form a primary circular excavation part (S10), and the primary circular excavation part A primary segment installation step (S20) for installing the primary segment, and a slab construction step (S30) for constructing a concrete slab on the ground around the primary segment, and fixing the primary segment to the slab 1 Secondary segment fixing step (S40), a second excavation step (S50) of excavating the ground to the lower portion of the primary segment, and a second segment installation step (S60) of installing a secondary segment at the bottom of the primary segment And, filling the inner wall between the inner wall of the primary digging portion and the outer circumferential surface of the secondary segment to fix the secondary segment (S70) and the secondary digging step (S50) installing the secondary segment Rainwater storage tank construction completion step (S80) repeatedly performing the step (S60) and the inner wall filling fixing step (S70), and the rainwater storage tank construction completion step (S80) repeatedly performed in the first excavation step (S10) It includes a continuous construction step (S90) of the rainwater storage tank, and a drainage pipe connection step (S100) of connecting a drain pipe between the rainwater storage tanks.

The first excavation step (S10) refers to a step of excavating in a circular manner with an excavator on a target ground to construct a tubular rainwater storage tank with an open top (see FIG. 2). At this time, it is preferable that the primary circular excavation portion is relatively lower than the vertical height of the primary segment so that the primary segment is exposed to the upper portion of the primary circular excavation portion. This is to allow the construction of the slab to be adhered to the circumference.

The primary segment installation step (S20) is to form an inner wall of a tubular shape by assembling an arc-shaped primary segment made of concrete in close contact with the inner circumferential surface of the primary circular excavation part formed in the primary excavation step (S10). Refers to the step of installation (see FIG. 3). This step forms a tubular inner wall through the primary segment, and serves to provide a place where the slab is constructed while covering the inner wall of the excavated site.

Here, the primary segment is described in detail with reference to FIGS. 12 to 18 below, and is an arc-shaped structure pre-made of concrete, which can be assembled to both sides and up and down, and serves to form an inner wall of a tubular shape. will be.

It is preferable that the primary segment is positioned relatively higher than the primary circular excavation, so that it can be smoothly connected to the slab while serving as an inner wall for the constructed slab.

The slab construction step (S30) is to construct a concrete slab by pouring and curing concrete on the upper surface of the target ground to tightly surround a part of the outer surface of the primary segment protruding upwardly around the primary circular excavation part. Refers to the steps (see FIG. 4). This step forms a slab around the primary segment to form a structure in which the primary segment can be fixed.

The primary segment fixing step (S40) refers to a step of interconnecting the slab and the primary segment so that the primary segment is fixed to the concrete slab. This step serves to secure the primary segment assembled in a tubular shape to the slab so that the primary segment does not fall downward even when additional drilling is performed.

The primary segment is anchored to the slab through a through hole formed horizontally therethrough. That is, the anchor is driven through the through hole to fix the primary segment to the slab.

The second excavation step (S50) refers to a step of excavating circularly with an excavator so as to have a relatively wide inner diameter than the tubular inner wall formed by the primary segment below the primary segment fixed to the slab (FIG. 5) Reference). This step refers to digging the ground downward to form a vertical circular structure, a rainwater storage tank. Here, the inner diameter of the excavation site wider than the primary segment is to form a space to inject concrete.

In the second excavation step (S50), the excavation depth is preferably excavated to a depth in which the secondary segments are connected to 2 to 4 vertically (two are connected to the drawing: see FIG. 8). That is, the secondary circular excavation portion is formed relatively deeper than the primary circular excavation portion, so that the construction of the rainwater storage tank can be quickly performed.

The second segment installation step (S60), while assembling the arc-shaped secondary segment made of concrete along the inner circumferential surface of the secondary circular excavation formed in the secondary excavation step (S50), mutually up and down the primary segment Refers to the step of assembling and installing to form a tubular inner wall. This step serves to form the inner wall of the rainwater storage tank (see FIGS. 6 and 7 ). Here, the secondary segment is the same as the primary segment and is described in detail through FIGS. 12 to 18 below.

The secondary segment is fixed to the segment transfer device connected to the crane and is installed by being transferred from the ground to the secondary circular excavation. The segment transfer device is installed on a crane, and the tip is fitted into a through hole formed in a central portion of the secondary segment to balance the weight with a rear weight to fix the secondary segment for easy transport through the crane To make it possible.

The inner wall filling fixing step (S70) fills the empty space between the inner wall of the secondary segment and the secondary circular excavation by injecting concrete at high pressure through the through hole formed horizontally through the secondary segment. Refers to the step of curing the concrete filled in the empty space to fix the secondary segment to the inner wall (see FIGS. 8 and 9 ). In this step, a concrete injection pipe is connected to the through-hole, and concrete is injected to fill the empty space of the inner wall while fixing the secondary segment to the ground through concrete.

The completion of the rainwater storage tank construction step (S80) is completed by repeatedly performing the second excavation step (S50), the second segment installation step (S60), and the inner wall filling fixing step (S70). Refers to the steps (see FIG. 10). This construction method can be carried out without interruption to the required depth or desired depth by continuously performing the second excavation step (S50), the second segment installation step (S60), and the inner wall filling fixing step (S70).

The continuous construction of the rainwater storage tank (S90) is performed repeatedly from the first excavation step (S10) to the rainwater storage tank construction completion step (S80) to continuously construct at least two rainwater storage tanks with the slab connected. It refers to the steps (see FIGS. 10 and 11). 10, it can be seen that three rainwater storage tanks were constructed.

The drain pipe connection step (S100) refers to a step of interconnecting a drain pipe between the rainwater storage tanks so that water flows between the plurality of rainwater storage tanks constructed (see FIG. 11).

In the step of connecting the drain pipe (S100), the drain pipe is preferably arranged to be gradually lowered so as to gradually step from the rainwater storage tank on one side to the rainwater storage tank on the other side, which is more rapid while moving rainwater from the rainwater storage tank on one side to the rainwater storage tank on the other side. It is to make it happen smoothly.

As described above, the construction method installs a plurality of the rainwater storage tanks and connects the drain pipes therebetween, so that the storage space of rainwater can be more sufficiently secured, and rainwater flows through the drain pipes between the rainwater storage tanks and the rainwater storage tanks. As it is moved, foreign matter is precipitated and purified to the bottom of the rainwater storage tank, so that clean water can be secured.

12 to 18 are views showing a segment according to the present invention. As shown in this, the segments used in the rainwater storage method construction method using the top-down construction method according to the present invention are four first segments 10 which are continuously assembled and one side of the first segment 10 to which the four are connected. A second segment 20 connected to the third segment 30 connected to the other side of the first segment 10 connected to the four, and the second segment 20 and the third segment 30 It includes a fourth segment 40 to be connected.

The first segment 10 is formed of an arc-shaped plate, four of which are continuously connected to the side by bolt fastening and can be interconnected up and down by bolt fastening, and serves to form most of the present segments made of a tubular structure. Do it.

The first segment 10 is formed with a connecting hole (A) and a fastening pipe (P) so that both sides and upper and lower sides can be assembled with mutual bolts (B). The connecting hole (A) provides a place where the bolt (B) is fitted and the fastening tube (P) is a tube formed with a spiral on the inner circumferential surface, and the other first segment in a direction that is connected to the connecting hole (A) It is installed in (10) so that the two first segments 10 can be coupled to each other while the bolts B are fastened.

In addition, the first segment 10 has a through hole (T) is formed to penetrate horizontally from the central portion of the inner surface toward the outer surface. The through hole (T) serves to provide a passage through which the concrete is injected while providing a place where the segment transfer device is fitted, and is closed with a stopper or the like after the concrete is injected.

The second segment 20 is connected by bolt fastening to one side of the first segment 10 in which four are continuously connected, a first inclined surface 21 is formed to be inclined to the outside, and is formed as an arc-shaped plate and mutually up and down. It can be connected.

The first inclined surface 21 provides a portion coupled to one side surface of the fourth segment 40, and the second segment 20 is the fastening pipe P, like the first segment 10, The connecting hole (A) and the through hole (T) are formed.

The third segment 30 is connected to the other side of the first segment 10, four of which are continuously assembled, a second inclined surface 31 is formed to be inclined on the outside, and is formed as an arc-shaped plate and can be interconnected up and down. It is.

The second inclined surface 31 provides a portion that is coupled to the other side of the fourth segment 40, and the third segment 30 is the fastening pipe P, like the first segment 10, The connecting hole (A) and the through hole (T) are formed.

The fourth segment 40 has corresponding inclined surfaces formed on both sides so as to be in close contact with the first inclined surface 21 and the second inclined surface 31, and between the second segment 20 and the third segment 30. It is connected by bolt fastening to form a cylinder, which is formed as an arc-shaped plate and can be interconnected up and down, while pushing from the bottom to the top, both sides are in close contact between the first inclined surface 21 and the second inclined surface 31. It is assembled to the second segment 20 and the third segment 30 to complete the assembly of the present segment.

In the fourth segment 40, as in the first segment 10, the fastening pipe P, the connecting hole A, and the through hole T are formed.

Although the preferred embodiments of the present invention have been described above, the present invention can use various changes, modifications, and equivalents. It is clear that the present invention can be equally applied by appropriately modifying the above embodiments. Accordingly, the above description is not intended to limit the scope of the present invention as defined by the following claims.

Meanwhile, in the detailed description of the present invention, specific embodiments have been described, but it will be apparent to those skilled in the art that various modifications are possible without departing from the scope of the present invention.

10: first segment
20: second segment
21: first slope
30: third segment
31: second slope
40: 4th segment
B: Bolt
A: connector
P: Fastening tube
T: Through hole

Claims (4)

A first excavation step (S10) of excavating circularly with an excavator on the target ground;
The primary segments of circular arcs made of concrete in close contact with the inner circumferential surface of the primary circular excavation formed in the primary excavation step (S10) are assembled to each other so as to be positioned relatively higher than the primary circular excavation, thereby forming a tubular inner wall. A primary segment installation step (S20) of installing to form;
A slab construction step (S30) of constructing a concrete slab by pouring and curing concrete on an upper surface of the target ground so as to tightly surround a part of the outer surface of the primary segment protruding upwardly around the primary circular excavation part. ;
A primary segment fixing step (S40) in which the primary segment is anchored to the slab through a through hole formed horizontally through the primary segment so that the primary segment is fixed to the concrete slab to interconnect the slab and the primary segment. Wow;
A second excavation step (S50) of excavating circularly with an excavator to have a relatively wide inner diameter than a tubular inner wall formed by the primary segment below the primary segment fixed to the slab;
The secondary segment formed of concrete along the inner circumferential surface of the secondary circular excavation part formed in the secondary excavation step (S50) is assembled with each other while assembling the primary segment up and down to form a tubular inner wall. Secondary segment installation step (S60) and;
By injecting concrete with high pressure inward through a through hole formed horizontally through the secondary segment to fill the empty space between the secondary segment and the inner wall of the secondary circular excavation, curing the concrete filled in the empty space by curing An inner wall filling fixing step (S70) of fixing the secondary segment to the inner wall;
A rainwater storage tank construction completion step (S80) for repeatedly completing the construction of the rainwater storage tank by repeatedly performing the second excavation step (S50), the second segment installation step (S60), and the inner wall filling fixing step (S70);
From the first excavation step (S10) to the rainwater storage tank construction completion step (S80) by repeatedly performing the rainwater storage tank continuous construction of the rainwater storage tank in a state in which the slab is connected (S90) and ;
A drain pipe connection step (S100) of interconnecting a drain pipe between the rainwater storage tanks so that water flows between the plurality of rainwater storage tanks constructed in a plurality; Including,
In the second excavation step (S50), the depth of excavation is a rainwater storage tank construction method using a top-down method, characterized in that the second segment is excavated to a depth that is connected to 2 to 4 vertically.
According to claim 1,
In the step of connecting the drain pipe (S100), the drain pipe is gradually lowered so as to gradually step from the rainwater storage tank on one side to the rainwater storage tank on the other side.
According to claim 1,
The primary segment and the secondary segment,
It is formed of an arc-shaped plate, and four are continuously connected to the side by bolt fastening, and can be interconnected up and down by bolt fastening, and connect holes (A) so that they can be assembled by mutual bolts (B) both up and down. A first segment in which the fastening pipe P is formed;
Four are connected to one side of the first segment connected continuously by bolt fastening, a first inclined surface is formed obliquely on the outside, formed of an arc-shaped plate, can be interconnected up and down, and mutually bolted to both sides and up and down ( A second segment in which the connecting hole (A) and the fastening tube (P) are formed to be assembled into B);
Four are continuously connected to the other side of the first segment, a second inclined surface is formed to be inclined on the outside, formed of an arc-shaped plate, can be interconnected up and down, and mutually bolted to both sides up and down (B) A third segment in which the connecting hole (A) and the fastening tube (P) are formed to be assembled into;
Corresponding inclined surfaces are formed on both sides to be in close contact with the first inclined surface and the second inclined surface, and are connected by bolting between the second segment and the third segment to form a cylinder, formed into an arc-shaped plate, up and down A fourth segment in which a connecting hole (A) and a fastening pipe (P) are formed to be connected to each other and to be assembled with mutual bolts (B) on both sides; Rainwater storage tank construction method using a top-down method comprising a.
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