KR20090129089A - Decompression apparatus of double drain pipe - Google Patents

Abstract

PURPOSE: A decompression structure for a double drain pipe is provided to restrain buoyancy by underground water by keeping the water level of underground water not to exceed the planned stable water level, and to prevent underground water from being drained off excessively by compulsion. CONSTITUTION: A decompression structure for a double drain pipe(20) comprises an outer pipe(21) having a through hole(21a) on one side of the outer circumference and an opening(21b) opened downward, and an inner pipe(24) composed of a horizontal pipe(22) provided with an inflow port(22a) to let underground water flow in and an end of the inflow port side exposed to the outside of the outer pipe via the through hole, and a vertical pipe(23) located in the outer pipe and extended upward from the horizontal pipe and provided with a discharge port(23a) to make influent underground water rise and overflow.

Description

Decompression apparatus of double drain pipe

The present invention relates to a double drain pipe decompression structure, and more particularly, to a decompression structure that can be connected to the outlet of the discharge pipe installed in the sump to maintain and control the upstream pressure of the groundwater flowing through the discharge pipe.

In general, when a large amount of groundwater exists around and underneath the building, the building receives a buoyancy force due to the groundwater, which causes the building to rise and is destroyed, threatening safety. On the contrary, if the groundwater existing around and underneath the building is rapidly removed by forced drainage, the ground where the groundwater existed suddenly becomes empty and the ground sinks, which causes the building to fall and threaten its safety. .

Many methods are used through dead weight and permanent (buoyancy) anchors for the up-water pressure treatment on the foundation floor of the building, but this is limited in that the continuous reliability of the buoyancy anchor's tensile force is not guaranteed with respect to the durability and safety of the building. have. An improved method is to form an artificial catchment and drainage layer under the foundation floor so that the groundwater flowing into the site is collected in the catchment along the drainage path and pumped and discharged regularly so that the foundation floor concrete does not act as a positive pressure. Permanent drainage system method. This has the advantage of more stable and permanently solve the problem of up-water pressure in proportion to the high groundwater level compared to the conventional method.

This conventional general drainage system is shown in FIG. 1. Referring to FIG. 1, a drainage material (or formwork) 110 having a predetermined height is horizontally and / or vertically connected to each other at a predetermined distance from the oyster finish surface 101 to be disposed horizontally, and the gulto finish surface of the rock layer. While the non-woven fabric (not shown) is positioned between the 101 and the drain 110, the outlet of the drain 110 gathered to one side is installed to connect with the sump 130 and cast mortar on a predetermined height thereon. The concrete 120 is formed.

This conventional method is forced to drain through the sump 130, or directly connected to a separate discharge pipe (not shown) and in communication with the external main drain (not shown), so that it can be naturally drained by the upward pressure do. However, this drainage method has a problem that can not prevent ground subsidence due to excessive discharge. That is, even if only a slight upward water pressure is generated, since it is a continuous drainage without stopping, in some cases the ground may be settled or weakened due to excessive groundwater drainage.

Therefore, the groundwater discharge is prevented to prevent the upward pressure of the building, and at the same time, the excessive discharge is prevented, and the design ground water level, that is, the theoretical groundwater level is a balance between the force due to the pressure of the groundwater under the building. In order to be maintained, it is necessary to have a drainage system that collects groundwater that penetrates the bottom of the building until it reaches a design level and discharges only when it exceeds the level.

In order to solve the problems of the prior art as described above, an object of the present invention is to prevent the buoyancy acting by the groundwater so that the groundwater level does not exceed the design stable water level, and at the same time to prevent excessive groundwater drainage It is to provide a decompression structure that can be.

In order to achieve the above object, the present invention is a pressure reducing structure installed on the upper side of the sump well so as to be connected to the outlet of the discharge pipe installed in the sump to control the upward water pressure of the groundwater generated from the basement floor, through the periphery of one side It is formed, the outer tube having an open opening on the lower side; And an inlet is formed so that the groundwater flows in, the inlet side end passes through the through-hole and the horizontal tube is exposed to the outside of the outer tube, the inner tube is located inside the outer tube and extends upwards from the horizontal tube, It provides a double drain pipe decompression structure, characterized in that it comprises an inner tube consisting of a vertical pipe is formed so that the outlet port is so overflow.

In addition, the present invention in the decompression structure is installed on the upper side of the sump well so as to be connected to the outlet of the discharge pipe installed in the sump to control the upward water pressure of the groundwater generated from the bottom of the basement building structure, the through hole is formed on one side An outer tube having an open opening at a lower side thereof; A vertical pipe formed with a first discharge port located inside the outer pipe, a second discharge port exposed to the outside of the outer pipe, and an inlet formed therein so that groundwater flows in, and the ground pipe flows into the vertical pipe; An inner tube communicating with one side and including a horizontal tube through which the inlet side end passes through the through hole and is exposed to the outside of the outer tube; And a valve provided at the end portion of the second outlet side to open and close the second outlet so as to control the discharge of the groundwater introduced into the inlet of the horizontal pipe. .

In another aspect, the present invention is a pressure reducing structure installed on the upper side of the sump well to be connected to the outlet of the discharge pipe installed in the sump to adjust the up-water pressure of the groundwater generated from the bottom of the basement building, the first through the outer periphery An outer tube having a second opening formed at an opposite side thereof, and having an open opening at a lower side thereof; An inlet is formed to allow the groundwater to flow in, and a first discharge port is formed on the opposite side to discharge the groundwater, and an inlet end portion passes through the first through hole to be exposed to the outside of the outer tube, and a first discharge side end portion is formed in the first outlet port. A horizontal pipe passing through the two holes and exposed to the outside of the outer pipe, and a vertical pipe positioned inside the outer pipe and extending upward from the middle of the horizontal pipe, the second outlet being formed so that the inflow of the groundwater flows upward Inner tube made of; And a valve provided at the end portion of the first outlet side to open and close the first outlet to control the discharge of the groundwater introduced into the inlet to the horizontal pipe. .

The present invention also provides a double drain pipe decompression structure, characterized in that the ground water outflow passage is formed between the inner peripheral surface of the outer tube and the outer peripheral surface of the vertical tube.

In another aspect, the present invention provides a double drain pipe decompression structure, characterized in that the vertical pipe is formed to extend to the height of the design stable water level of groundwater.

In another aspect, the present invention provides a double drain pipe decompression structure, characterized in that the through-hole is formed on the opening side.

In another aspect, the present invention provides a double drain pipe decompression structure, characterized in that the first through the second hole is formed on the opening side.

As described above, the double drain pipe decompression structure according to the present invention connects the double drain pipe extending to the height of the design stabilized water level with the discharge pipe, so that if the groundwater level is less than or equal to the design stabilized water level, the proper water pressure is maintained inside the discharge pipe. The groundwater discharge can be suppressed, and if the groundwater level is above the design stable water level, the groundwater overflows, thereby controlling the upward pressure of the groundwater.

In addition, the double drain pipe decompression structure according to the present invention has an effect that can be easily installed in the drainage structure for the decompression drainage.

Hereinafter, with reference to the accompanying drawings will be described in more detail the double drain pipe decompression structure according to a preferred embodiment of the present invention.

2 is a three-dimensional view showing a double drain pipe decompression structure according to the first embodiment of the present invention, Figure 3 is a view showing a state in which the decompression structure of Figure 2 is applied.

2 and 3, the double drain pipe decompression structure 20 according to the first embodiment of the present invention includes an outer tube 21 and an inner tube 24.

The outer tube 21 has a through hole 21a formed at one side of the outer circumferential edge, and has an opening 21b having a lower side opened. Here, the through hole 21a is preferably formed at the opening 21b side.

The inner tube 24 is composed of a horizontal tube 22 and the vertical tube 23, is formed in the 'b' shape on the front.

The horizontal pipe 22 is formed with an inlet port 22a so that the groundwater flows in, and the inlet port 22a side end passes through the through hole 21a and is exposed to the outside of the outer tube 21.

The vertical pipe 23 is positioned inside the outer pipe 21 and extends upward from the horizontal pipe 22, and an outlet 23a is formed so that the inflowing groundwater rises and overflows.

In addition, the vertical pipe 23 is preferably extended to the height of the design stable water level of groundwater for decompression drainage of groundwater.

The outer tube 21 and the inner tube 24 configured as described above are integrally formed, and an outlet passage (not shown) is formed between the inner circumferential surface of the outer tube 21 and the outer circumferential surface of the vertical tube 23. When the groundwater flowing into the horizontal pipe 22 rises through the vertical pipe 23 and overflows from the top of the vertical pipe 23, the ground water flows into the sump 3 through the outflow passage (not shown). You are guided.

As shown in Figure 3, the inlet (22a) side end of the horizontal pipe 22 is disposed between the gulto finish surface 1 and the concrete layer (2) is installed to be connected to the sump (3) ( 10), it is possible to control the groundwater penetrated to the bottom of the building to the appropriate water pressure to suppress the buoyancy acting by the groundwater and to prevent excessive discharge of groundwater discharged to the sump (3).

4 is a three-dimensional view showing the double drain pipe decompression structure 30 according to the second embodiment of the present invention, Figure 5 is a view showing a state in which the decompression structure 30 of FIG.

4 and 5, the double drain pipe decompression structure 30 according to the second embodiment of the present invention includes an outer tube 31, an inner tube 34, and a valve 32c.

The outer tube 31 has a through hole 31a formed at one side of the outer circumferential edge thereof, and has an opening 31b having an open lower side. Here, the through hole 31a is preferably formed at the opening 31b side.

The inner tube 34 is composed of a vertical tube 32 and a horizontal tube 33, and is formed in a 'ㅓ' shape on the front.

The vertical pipe 32 is inserted into the inner space of the outer pipe 31, the first discharge port 32a is formed on the upper side, the second discharge hole 32b is formed on the lower side. The first outlet 32a is positioned inside the outer tube 31, and the second outlet 32b passes through the opening 31b of the outer tube 31 and is exposed to the outside.

In addition, the vertical pipe 32 is preferably extended to the height of the design stable water level of groundwater for decompression drainage of groundwater.

The horizontal pipe 33 is formed with an inlet 33a to allow the groundwater to flow therein, and communicates with one side of the vertical pipe 32 to allow the groundwater to flow into the vertical pipe 32. The inlet 33a side end passes through the through hole 31a and is exposed to the outside of the outer tube 31.

The valve 32c is provided at the end portion of the second discharge port 32b so that the second discharge port 32b can be opened and closed to control the discharge of the groundwater introduced into the inlet 33a of the horizontal pipe 33.

The lower end of the vertical pipe 32 is provided with a valve 32c for opening and closing the second outlet 32b, so that the valve 32c is normally closed so that the groundwater is overwritten by the first outlet 32a of the vertical pipe 32. When sedimentation and sediment accumulate in the lower part of the discharge pipe 10 and it is blocked, the valve 32c is opened and the groundwater discharges to the 2nd discharge port 32b of the vertical pipe 32, and it remains in the discharge pipe 10 inside. Foreign matter can be removed.

The outer tube 31 and the inner tube 34 configured as described above are integrally formed, and an outlet passage (not shown) is formed between the inner circumferential surface of the outer tube 31 and the outer circumferential surface of the vertical tube 32. When the groundwater flowing into the horizontal pipe 33 rises through the vertical pipe 32 and overflows from the top of the vertical pipe 32, the groundwater flows into the sump 3 through the outflow passage (not shown). You are guided.

As shown in Figure 5, the inlet (33a) side end of the horizontal pipe 33 is disposed between the gulto finish surface 1 and the concrete layer (2) is installed to be connected to the sump (3) ( 10), it is possible to control the groundwater penetrated to the bottom of the building to the appropriate water pressure to suppress the buoyancy acting by the groundwater and to prevent excessive discharge of groundwater discharged to the sump (3).

6 is a three-dimensional view showing a double drain pipe decompression structure 40 according to a third embodiment of the present invention, Figure 7 is a view showing a state in which the decompression structure 40 of FIG.

6 and 7, the double drain pipe decompression structure 40 according to the third embodiment of the present invention includes an outer tube 41, an inner tube 44, and a valve 42c.

The outer tube 41 has a first through-hole 41a is formed at one side of the outer circumferential portion, a second through-hole 41b is formed at the opposite side thereof, and has an opening 41c having a lower side thereof open. Here, it is preferable that the first through hole 41a and the second through hole 41b are formed on the side of the opening 41c.

The inner tube 44 is composed of a horizontal tube 42 and the vertical tube 43, it is formed in a 'ㅗ' shape on the front.

The horizontal pipe 42 is formed with an inlet port 42a to allow the groundwater to flow therein, and a first discharge port 42b formed to discharge the groundwater to the opposite side. The inlet 42a side end passes through the first through hole 41a and is exposed to the outside of the outer tube 41, and the first outlet 42b side end passes through the second through hole 41b and the outside. The tube 41 is exposed outside.

The vertical pipe 43 is located inside the outer pipe 41 and extends upward from the middle of the horizontal pipe 42, and a second discharge port 43a is formed so that the flowing ground water flows upwardly.

In addition, the vertical pipe 43 is preferably extended to the height of the design stable water level of groundwater for decompression drainage of groundwater.

The valve 42c is provided at the end portion of the first discharge port 42b so that the first discharge port 42b can be opened and closed to control the discharge of the groundwater introduced into the inlet 42a of the horizontal pipe 42.

The other end of the horizontal pipe 42 is provided with a valve 42c for opening and closing the first outlet 42b, whereby the valve 42c is normally closed so that the groundwater is discharged to the second outlet 43a of the vertical pipe 43. When the sedimentation and sediment accumulate in the discharge pipe 10 and blockage, the valve 42c is opened so that the groundwater is discharged to the first discharge port 42b of the horizontal pipe 42, thereby allowing the inside of the discharge pipe 10 to flow. Residual debris can be removed.

The outer tube 41 and the inner tube 44 configured as described above are integrally formed, and an outlet passage (not shown) is formed between the inner circumferential surface of the outer tube 41 and the outer circumferential surface of the vertical tube 43. When the groundwater flowing into the horizontal pipe 42 rises through the vertical pipe 43 and overflows from the top of the vertical pipe 43, the groundwater flows into the sump 3 through the outflow passage (not shown). You are guided.

As shown in FIG. 7, an inlet pipe 42a side end of the horizontal pipe 42 is disposed between the gulting finish surface 1 and the concrete layer 2 to be connected to the sump well 3. By being connected with (10), it is possible to control the groundwater penetrated to the bottom of the building to the appropriate water pressure to suppress the buoyancy acting by the groundwater and at the same time prevent excessive discharge of groundwater discharged to the sump (3).

As described so far, the double drain pipe decompression structure of the present invention can control the upward pressure of the groundwater by connecting the double drain pipe extending to the height of the design stabilized water level with the discharge pipe installed in the sump, and the double drain pipe integrally. By being configured, there is an advantage that can be easily installed in the drainage structure for decompression drainage.

While the invention has been described in detail in the foregoing embodiments, it will be apparent to those skilled in the art that various modifications and variations are possible within the spirit of the invention, and such modifications and variations belong to the appended claims.

1 is a view showing a conventional drainage system.

2 is a three-dimensional view showing a double drain pipe decompression structure according to the first embodiment of the present invention.

3 is a view showing a state in which the pressure-sensitive structure of FIG. 2 is applied.

4 is a three-dimensional view showing a double drain pipe decompression structure according to the second embodiment of the present invention.

5 is a view showing a state in which the pressure-sensitive structure of FIG. 4 is applied.

6 is a three-dimensional view showing a double drain pipe decompression structure according to the third embodiment of the present invention.

FIG. 7 is a view illustrating a state in which the pressure reducing structure of FIG. 6 is applied.

 <Explanation of symbols for the main parts of the drawings>

10: discharge pipe 20: decompression structure

21: outer tube 22: horizontal tube

23: vertical tube 24: inner tube

Claims (7)

In the decompression structure is installed on the upper side of the sump to connect with the outlet of the discharge pipe installed in the sump to control the upward pressure of the ground water generated from the basement floor below, An outer tube is formed on one side of the outer periphery, the outer tube having an open opening on the lower side; And An inlet is formed so that the groundwater flows in, and an inlet side end passes through the through hole, and the horizontal tube is exposed to the outside of the outer tube, and the ground water is located inside the outer tube and extends upwardly from the horizontal tube. An inner tube including a vertical tube formed with a discharge port so as to be overflowed; Double drain pipe decompression structure, characterized in that configured to include. In the decompression structure is installed on the upper side of the sump to connect with the outlet of the discharge pipe installed in the sump to control the upward pressure of the ground water generated from the bottom of the basement building structure, An outer tube is formed on one side of the outer periphery, the outer tube having an open opening on the lower side; A vertical pipe formed with a first discharge port located inside the outer pipe, a second discharge port exposed to the outside of the outer pipe, and an inlet formed therein so that groundwater flows in, and the ground pipe flows into the vertical pipe; An inner tube communicating with one side and including an inlet side end with a horizontal tube passing through the through hole and exposed to the outside of the outer tube; And A valve provided at the end portion of the second outlet side such that the second outlet is openable to control the discharge of groundwater introduced into the inlet of the horizontal pipe; Double drain pipe decompression structure, characterized in that configured to include. In the decompression structure is installed on the upper side of the sump to connect with the outlet of the discharge pipe installed in the sump to control the upward pressure of the ground water generated from the bottom of the basement building structure, A first through hole is formed at one side of the outer periphery, and a second through hole is formed at the opposite side thereof, and an outer tube having an open opening at a lower side thereof; An inlet is formed to allow the groundwater to flow in, and a first discharge port is formed on the opposite side to discharge the groundwater, and an inlet end portion passes through the first through hole to be exposed to the outside of the outer tube, and a first discharge side end portion is formed in the first outlet port. A horizontal pipe passing through the two holes and exposed to the outside of the outer pipe, and a vertical pipe positioned inside the outer pipe and extending upward from the middle of the horizontal pipe, the second outlet being formed so that the inflow of the groundwater flows upward Inner tube made of; And A valve provided at the end portion of the first outlet side to open and close the first outlet to control the discharge of the groundwater introduced into the inlet to the horizontal pipe; Double drain pipe decompression structure, characterized in that configured to include. The method according to claim 1 or 2 or 3, Double drain pipe decompression structure, characterized in that the groundwater outflow passage is formed between the inner peripheral surface of the outer tube and the outer peripheral surface of the vertical pipe. The method according to claim 1 or 2 or 3, The vertical pipe is a double drain pipe decompression structure, characterized in that extending to the height of the design stable water level of groundwater. The method according to claim 1 or 2, The through-hole is formed in the opening side, the double drain pipe decompression structure. The method of claim 3, And the first through holes and the second through holes are formed at the opening side.

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