KR102422046B1 - Structure which submersible pump is installed in concrete structure - Google Patents

Abstract

In the present invention, a main conduit having a check valve and a sub conduit are embedded in a concrete structure, and a submersible pump is connected to the main conduit. Accordingly, internal water is normally drained naturally toward external water through the sub conduit without operating the submersible pump, and in case of danger of reverse flow, the submersible pump operates to forcibly discharge the internal water toward the external water through the main conduit. Therefore, there is no need to install a water gate on a concrete structure as a convention so that a construction process is simplified, and there is no need for components and equipment necessary for installing the water gate so that construction costs can be greatly reduced. In addition, the submersible pump is connected to an end of the main conduit outside the concrete structure, installation and lifting of the submersible pump are facilitated for convenient installation and management.

Description

Submersible pump concrete structure installation structure {Structure which submersible pump is installed in concrete structure}

The present invention relates to a structure in which a submersible pump is directly installed on a concrete structure without the need for a sluice gate.

In general, civil structures or concrete structures are constructed in reservoirs, rivers, reservoirs, rainwater sewage treatment pumping stations, water and sewage treatment pumping stations, and the like. At this time, in situations where it is not possible to secure a reservoir for installing the pump or in other situations where sufficient space cannot be secured, a pump is installed on a steel sluice gate, and a steel sluice gate is installed in a civil or concrete structure, and a steel sluice gate is installed. A submersible pump is installed.

Normally, the sluice gate is opened to naturally drain the internal water from the inside of the concrete structure to the outside of the concrete structure where external water flows. to prevent inflow into the concrete structure. Then, the internal water is forcibly drained to the outside of the concrete structure through a submersible pump.

In order to install a sluice gate equipped with a submersible pump in a concrete structure, many construction materials and construction equipment such as a sluice gate, a concrete structure, and a hoist are required. For this reason, the construction process is difficult and complicated, and the construction cost is greatly increased.

Korean Patent Registration (10-1973393)

It is an object of the present invention to provide a submersible pump concrete structure installation structure that can solve the above problems.

The submersible pump concrete structure installation structure for achieving the above object,

a main conduit buried through the concrete structure so that the inside of the concrete structure and the outside of the concrete structure communicate;

a main non-return valve connected to the opening of the main conduit facing the outside of the concrete structure and blocking the backflow of external water from the outside of the concrete structure into the inside of the concrete structure;

a submersible pump connected to the opening of the main conduit toward the inside of the concrete structure through a vibration-proof connection part, and forcibly draining the internal water inside the concrete structure to the outside of the concrete structure;

a pump support structure supporting the submersible pump;

a sub conduit buried through the concrete structure so that the inside of the concrete structure communicates with the outside of the concrete structure, the diameter of the sub conduit is smaller than that of the main conduit, and the sub conduit is disposed at a lower position than the main conduit; and

It is connected to the opening of the sub conduit facing the outside of the concrete structure, characterized in that it comprises a non-return valve for the sub to block the reverse flow of the external water outside the concrete structure into the concrete structure.

Since the present invention does not have a sluice gate and the submersible pump is installed in a concrete structure, not a sluice gate, many construction materials and construction equipment such as a sluice gate, a concrete structure, and a hoist for installing a sluice gate installed with a conventional submersible pump in a concrete structure are not required. . For this reason, the construction process is easier and simpler than when the conventional submersible pump installation sluice gate is installed in a concrete structure, and the construction cost can be significantly reduced.

The present invention embeds the main conduit and the sub conduit in which the non-return valve is installed in a concrete structure, and connects the submersible pump to the main conduit. For this reason, it is possible to naturally drain the domestic water to the outdoor water side through the sub conduit without operating the submersible pump in normal times, and operate the submersible pump to forcibly discharge the domestic water to the outdoor water side through the main conduit when there is a risk of backflow. Therefore, there is no need to install the sluice gate in the concrete structure as in the prior art, the construction process is simplified, and the components and equipment necessary for the sluice gate installation are not required, so the construction cost can be greatly reduced. In addition, since the submersible pump is connected to the end of the main conduit from the outside of the concrete structure, the submersible pump is easily installed and managed, making it easy to install and manage.

In the present invention, the submersible pump is connected to the main conduit through a vibration-proof connection. For this reason, vibrations generated during operation of the submersible pump can be effectively blocked without being transmitted to the main conduit. Therefore, it is possible to prevent cracking and collapse of the concrete structure due to the shaking of the main conduit.

The present invention includes an anti-vibration member that absorbs vibration of the submersible pump so that it is not transmitted to the pump support structure when the pump support structure is fixed to the floor. For this reason, the weight of the submersible pump itself and vibrations generated during operation of the submersible pump may be effectively blocked without being transmitted to the pump support structure.

The present invention includes a vibration-proof member that absorbs vibrations of the submersible pump so that it is not transmitted to the pump support structure and the concrete structure when the pump support structure is fixed to the concrete structure. For this reason, the weight of the submersible pump itself and vibrations generated during operation of the submersible pump can be effectively blocked without being transmitted to the pump support structure and the concrete structure.

1 is a side view of the submersible pump concrete structure installation structure according to a first embodiment of the present invention.
Figure 2 is a front view of the water pump concrete structure installation structure shown in Figure 1;
3 is a view showing a pump support structure for supporting the submersible pump shown in FIG. 1 .
4 is a view showing a state in which several sets of the water pump concrete structure installation structure shown in FIG. 2 are installed.
5 is a side view of the submersible pump concrete structure installation structure according to the second embodiment of the present invention.
6 is a side view of the submersible pump concrete structure installation structure according to the third embodiment of the present invention.

Hereinafter, the installation structure of the submersible pump concrete structure according to the first embodiment of the present invention will be described in detail.

1, the submersible pump concrete structure installation structure according to the first embodiment of the present invention includes a main conduit 100, a main non-return valve 200, a submersible pump 300, and a pump support structure ( 400), a sub conduit 600, and a non-return valve 700 for the sub.

[Main conduit (100), non-return valve for main (200)]

The main conduit 100 is buried through the concrete structure so that the inside of the concrete structure and the outside of the concrete structure communicate. Normally, high-level internal water is stored inside the concrete structure, and low-level external water flows outside the concrete structure. The left side of the concrete structure shown in FIG. 1 is inside the concrete structure, and the right side of the concrete structure is outside the concrete structure. 5 and 6 are also the same.

The main conduit 100 is located at a certain height of the concrete structure from the floor surface. The main conduit 100 is located between the high water level in the inner water level and the low water level in the outer water level, so that natural drainage can be made to the outside water level, where the high level water level is usually low level.

The main non-return valve 200 is connected to the opening of the main conduit 100 facing the outside of the concrete structure. The main non-return valve 200 allows the internal water inside the concrete structure to drain to the outside of the concrete structure, and blocks the reverse flow of external water from the outside of the concrete structure to the inside of the concrete structure.

As shown in FIG. 2 , the main non-return valve 200 is formed as a flap valve. The flap valve is a valve body 210 attached to the opening of the main conduit 100, a flap 220 that opens and closes the opening of the main conduit 100, and the flap 220 is rotated with respect to the valve body 210 It is composed of a hinge 230 .

In the case of the flap valve, when the internal water level is higher than the external water level, the flap 220 is opened by the water pressure generated according to the water level difference or by the pressure by the submersible pump 300, and the internal water inside the concrete structure is drained to the outside of the concrete structure, but , when the external water level is higher than the internal water level, the flap 220 is closed to prevent the reverse flow of external water from the outside of the concrete structure to the internal water side of the inside of the concrete structure.

The material of the flap valve is preferably any one selected from general steel, cast iron, stainless steel, etc. to suit the characteristics of the fluid.

[Submersible Pump (300)]

The submersible pump 300 is connected to the opening of the main conduit 100 facing the inside of the concrete structure, and forcibly drains the internal water inside the concrete structure to the outside of the concrete structure. A water level gauge is installed inside and outside the concrete structure to automatically detect the water level, and when the external water level is higher than the internal water level, the submersible pump 300 is controlled to automatically operate.

The submersible pump 300 is a transverse shaft type submersible pump 300 , and may be implemented by known technologies such as a motor, an impeller coupled to the rotation shaft of the motor, and a housing in which the motor and the impeller are accommodated.

The main conduit 100 is connected to the discharge port of the housing, and the suction pipe 310 through which domestic water is introduced is connected to the suction port of the housing.

Anti-vibration connection (500)

The submersible pump 300 is connected to the main conduit 100 through a vibration-proof connection part 500 that absorbs the vibration of the submersible pump 300 . The submersible pump 300 vibrates during operation. The main conduit 100 connected to the submersible pump 300 is shaken by the vibration of the submersible pump 300 , which may lead to cracks in the concrete structure. In order to prevent this, the anti-vibration connection part 500 is connected between the submersible pump 300 and the main conduit 100 .

The anti-vibration connection part 500 is preferably selected from any one of a rubber joint, an expansion joint, and a flexible joint.

In this embodiment, the expansion joint is applied as the vibration-proof connection part 500 .

[Pump support structure 400]

The pump support structure 400 is connected to the main conduit 100 to support the submersible pump 300 floating at a predetermined height from the floor.

In the pump support structure 400 , the main body 402 is fixed to the bottom surface inside the concrete structure. As shown in FIG. 3 , between the portion where the submersible pump 300 of the pump support structure 400 is connected, that is, the main body 402 fixed to the floor surface and the connecting rod 401 to which the submersible pump 300 is connected, An anti-vibration member 410 for absorbing the vibration of the submersible pump 300 is disposed.

The main body 402 and the connecting rod 401 are spaced apart from each other, and a plurality of anti-vibration members 410 are installed at regular intervals between the main body 402 and the connecting rod 401 . The anti-vibration member 410 absorbs the weight of the submersible pump 300 itself and vibrations generated during the operation of the submersible pump 300 .

The vibration isolation member 410 is preferably selected from a vibration isolation spring, an air spring, and a rubber pad.

In this embodiment, a vibration-proof spring is applied as the vibration-proof member 410 .

[Sub conduit (600), non-return valve for sub (700)]

The sub conduit 600, like the main conduit 100, is embedded through the concrete structure so that the inside of the concrete structure and the outside of the concrete structure communicate with each other. As shown in FIG. 1 , the diameter is smaller than that of the main conduit 100 , and is disposed at a lower position than the main conduit 100 . The position lower than the main conduit 100 means that the center of the sub conduit 600 is lower than the center of the main conduit 100 .

The non-return valve 700 for the sub is connected to the opening of the sub conduit 600 facing the outside of the concrete structure, so that the internal water inside the concrete structure is drained to the outside of the concrete structure, and the external water from the outside of the concrete structure is inside the concrete structure backflow is blocked.

The non-return valve 700 for the sub is formed as a flap valve like the non-return valve 200 for the main. The flap valve is formed in the same configuration as the main non-return valve 200 . However, the flap 220 is formed of a light material such as HDPE (High Density Polyethylene) or FRP (Fiberglass Reinforced Plastics).

Since the non-return valve 700 for the sub is installed at a lower place than the non-return valve 200 for the main, the water pressure is greater, and the flap 220 is formed of a light material, so that the internal water level is higher than the external water level at normal times. In this case, the flap 220 is easily opened so that the internal water inside the concrete structure can be naturally drained to the outside of the concrete structure. In addition, when the external water level is higher than the internal water level, the flap 220 is closed to prevent the reverse flow of the external water from the outside of the concrete structure into the inside of the concrete structure. 1 illustrates a state immediately before the flap 220 of the non-return valve 700 for sub is opened because the internal water level is higher than the external water level. 5 and 6 are also the same.

On the other hand, in the first embodiment, one set of submersible pump concrete structure installation structures were arranged in the concrete structure, but as shown in FIG. 4, several sets may be arranged in the concrete structure at regular intervals according to the size and quantity of the concrete structure. have.

Hereinafter, in the submersible pump concrete structure installation structure according to the first embodiment of the present invention, a drainage principle that varies depending on the difference in water level between internal and external water will be described. Reference is made basically to FIGS. 1 and 2 .

[High level of domestic water, low level of outdoor water]

As shown in Fig. 1, when the internal water inside the concrete structure is at a high water level and the external water outside the concrete structure is at a low water level, the non-return valve for the sub is disposed at a lower position than the main non-return valve 200 as shown in FIG. At 700, the flap is easily opened due to the pressure difference and the light material, and the internal water is naturally drained to the external water side through the sub conduit 600 .

[low water level in domestic water, high water level outside]

When the external water outside the concrete structure becomes high due to heavy rain or flood, and the internal water inside the concrete structure becomes low, and there is a risk of backflow, the flap 220 of the main non-return valve 200 and the backflow prevention for the sub The flap 220 of the valve 700 is closed to block the outside water from flowing into the concrete structure through the main conduit 100 and the sub conduit 600 .

[High level of domestic demand, high level of external water]

When the external water outside the concrete structure becomes a high water level due to heavy rain or flood, etc., and the internal water inside the concrete structure also becomes a high water level, the submersible pump 300 operates. The reverse flow of external water through the sub conduit 600 is blocked by the non-return valve 700 for the sub. The flap 220 of the main non-return valve 200 is opened by the pressure of the submersible pump 300 being operated, and internal water is forcibly drained to the outside water side through the main conduit 100 .

Hereinafter, the installation structure of the submersible pump concrete structure according to the second embodiment of the present invention will be described in detail.

As shown in Figure 5, the submersible pump concrete structure installation structure according to the second embodiment of the present invention is different from the first embodiment in the pump support structure 400A, and other components are different from the first embodiment same. A detailed description of the same configuration will be omitted. The same reference numerals are used for the same components.

[Pump support structure (400A)]

When the water depth is deep, the pump support structure 400A may be fixed to the side surface of the concrete structure rather than the floor surface. One end of the pump support structure 400A is connected to the submersible pump 300, and the other end is connected to the concrete structure.

The anti-vibration member 410 for absorbing the vibration of the submersible pump 300 is disposed at a portion where the submersible pump 300 of the pump support structure 400A is connected is the same as in the first embodiment. In addition, the anti-vibration member 410 is also disposed on the portion connected to the concrete structure of the pump support structure (400A). Therefore, the weight of the submersible pump 300 itself and vibrations generated during the operation of the submersible pump 300 are prevented from being transmitted to the concrete structure riding the pump support structure 400A.

In the submersible pump concrete structure installation structure according to the second embodiment of the present invention, the drainage principle that varies depending on the water level difference between the internal and external water is the same as the drainage principle described in the first embodiment, and thus a description thereof will be omitted.

Hereinafter, the installation structure of the submersible pump concrete structure according to the third embodiment of the present invention will be described in detail.

As shown in Figure 6, the submersible pump concrete structure installation structure according to the third embodiment of the present invention is different from the first embodiment in that a curved pipe 800 is added, and the other components are in the first embodiment same as A detailed description of the same configuration will be omitted. The same reference numerals are used for the same components.

[Cube (800)]

A curved pipe 800 bent in a downward direction may be additionally connected to the suction port of the submersible pump 300 .

When the curved pipe 800 bent toward the floor is added to the straight suction pipe 310, it is possible to smoothly suck the internal water even when the internal water level inside the concrete structure is low.

In this embodiment, the curved pipe 800 is connected to the suction pipe 310 connected to the suction port of the submersible pump 300 , but unlike this, the suction pipe 310 is omitted and the curved pipe 800 is connected directly to the suction port of the submersible pump 300 . may be In addition, it may be formed by expanding the end of the curved pipe 800 in the form of a fallopian tube in order to suck the internal water.

In the submersible pump concrete structure installation structure according to the third embodiment of the present invention, the drainage principle that varies depending on the difference in water level between the internal and external water is the same as the drainage principle described in the first embodiment, and thus a description thereof will be omitted.

On the other hand, although the submersible pump concrete structure installation structure according to the present invention is applied to a concrete structure, it may also be applied to a civil structure.

100: main conduit 200: non-return valve for main
210: valve body 220: flap
230: hinge 300: submersible pump
310: suction pipe 400, 400A: pump support structure
401: connecting rod 402: body
500: dustproof connection 600: sub conduit
700: non-return valve for sub 800: curved pipe

Claims (5)

In the submersible pump concrete structure installation structure without a sluice gate and a sluice gate opening/closing device for raising and lowering the sluice gate,
The water pump concrete structure installation structure is,
a main conduit buried through the concrete structure so that the inside of the concrete structure and the outside of the concrete structure communicate;
a main non-return valve in the form of a flap valve connected to the opening of the main conduit facing the outside of the concrete structure and blocking the reverse flow of external water from the outside of the concrete structure into the inside of the concrete structure;
a submersible pump connected to the opening of the main conduit toward the inside of the concrete structure through a vibration-proof connection part and forcibly draining the internal water inside the concrete structure to the outside of the concrete structure;
a pump support structure supporting the submersible pump;
a sub conduit buried through the concrete structure so that the inside of the concrete structure and the outside of the concrete structure communicate with each other, the diameter is smaller than the main conduit, and the sub conduit is disposed at a lower position than the main conduit;
It is connected to the opening of the sub conduit facing the outside of the concrete structure, and blocks external water from the outside of the concrete structure from flowing back into the concrete structure. A non-return valve for a sub in the form of a flap valve formed; and
It is connected to the suction port of the submersible pump, including a curved pipe bent downward from the suction port,

Without a sluice gate and a sluice gate opening/closing device for raising and lowering the sluice gate,
[High level of domestic water, low level of outdoor water]
Normally, when the internal water inside the concrete structure is at a high water level and the external water outside the concrete structure is at a low water level, the non-return valve for the sub disposed at a lower position than the non-return valve for the main is due to the water pressure difference and light material. The flap of the non-return valve for the sub is opened and the internal water is naturally drained to the outside water through the sub conduit,
[Medium level of domestic water, Low level of outdoor water]
When the external water outside the concrete structure becomes low water level, and the internal water inside the concrete structure becomes a medium water level that is higher than the non-return valve for the sub and lower than the inlet of the submersible pump, it is naturally drained to the outside water side through the sub conduit At the same time, the submersible pump operates to forcibly drain the internal water to the external water side through the curved pipe and the main conduit,
[low water level in domestic water, high water level outside]
When the external water outside the concrete structure becomes high due to heavy rain or flood, etc. and the internal water inside the concrete structure becomes low water level and there is a risk of backflow, the flap of the main non-return valve and the sub-use non-return valve The flap is closed to block the outside water from flowing into the concrete structure through the main conduit and the sub conduit,
[High level of domestic demand, high level of external water]
When the external water outside the concrete structure becomes high due to heavy rain or flood, etc., and the internal water inside the concrete structure also becomes high, the submersible pump operates, and the external water through the sub conduit by the non-return valve for the sub The reverse flow of the submersible pump is blocked, and the flap of the main non-return valve is opened by the pressure of the submersible pump to be operated, and the internal water is forcibly drained to the external water through the curved pipe and the main conduit. . delete delete delete delete

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