KR20210017626A - Pneumatic water drainage system for underground sink - Google Patents

Abstract

The present invention provides a pneumatic water draining system for an underground collecting well, which can omit a conventionally used expensive explosion-proof underwater pump by using pneumatic pressure for drainage through a drain connected to the underground collecting well. To this end, the pneumatic water draining system for an underground collecting well includes a draining unit, an air supply unit, and a water level measuring device.

Description

Pneumatic water drainage system for underground sink

The present invention relates to a drainage system for underground water collection wells, and more particularly, to a pneumatic drainage system for underground water collection wells using air pressure.

Typically, a storage tank is disposed in an underground storage room for a charging station or a gas station, and an anchor is installed to fix the storage tank in the underground storage room. If water is filled above the level where the anchor is installed, the anchor may be corroded or the storage tank may float on the water, so drainage is legally enforced so that water does not occupy above a certain height. For this reason, conventionally, a drainage system for draining water collected in a water collection well of an underground storage room has been used.

The conventional drainage system uses a water pump installed in the sump to drain the water collected in the sump of the underground storage room. More specifically, a conventional drainage system is configured to collect water that has permeated into sand in an underground storage room into a sump, and drain the water in the sump by driving a water pump.

In the case of charging stations or gas stations, a certain distance (e.g. 8 m) around the machine room is legally defined as an explosion-proof area, so all electrical installations within the explosion-proof area are restricted to use explosion-proof products. However, since the explosion-proof submersible pump is excessively expensive, it is a cause of greatly deteriorating the economics of the entire system.

In addition, the conventional drainage system is a system that uses a water pump capable of operating in the presence of a pickle, and there is no problem in a state where enough water is collected in the water collecting well, but it is difficult to operate the submersible pump without a pickle in the state of low water. Therefore, it causes only overload to the motor. In other words, the water collected in the water collecting well is drained at the beginning of the operation of the submersible pump, but after that, the water is discharged in trace amounts without a gap where the water is collected in the water collecting well.

In addition, the conventional drainage system has a problem that it is difficult for a manager to check how much water has been drained. Although the operator intermittently measures the water level using a tape measure, this causes a lot of hassle and inconvenience.

Patent Document 1: Republic of Korea Utility Model Publication No. 20-0427714

The present invention was conceived to solve the above-described problems, and an object of the present invention is for an underground water collecting well that can omit the expensive explosion-proof underwater pump that has been used conventionally by using pneumatic pressure for drainage through a drain pipe connected to the underground water well. It is to provide a pneumatic drainage system.

Another problem to be solved by the present invention is to provide a pneumatic drainage system for a collection well that easily and precisely measures the water level in an underground storage room in which an underground storage tank is arranged, and uses the measured water level information for pneumatic drainage. will be.

In order to solve the above problems, a drain pipe 110 having a water inlet through the water collecting well 4 and a water outlet through the outside, and a first check valve 120a installed in the drain pipe 110 and the A drain unit 100 including a check valve 120a and in which a water accumulation section is formed between the first check valve 120a and the second check valve 120b; and, the first in the drain pipe 100 1 an air supply unit 200 selectively opening the first check valve 120a by supplying air to an upstream side of the check valve 120a; And a water level measuring device 400 for measuring the water level of the collecting well 4 in the underground storage room, and when the first check valve 120a is opened by an increase in pressure on the upstream side of the first check valve 120a, The water introduced into the drain pipe 110 through the water inlet of the drain pipe 110 enters and accumulates in the water accumulation section 112 and is discharged when the second check valve 120b is opened. do.

In addition, the air supply unit 200 includes an air compressor 210 generating pneumatic pressure, a first air hose 221 having a base end connected to the air compressor 210, and a front end of the first check valve ( The second air hose 222 introduced into the drain pipe 110 so as to face 120a), and both ends are connected to the front end of the first air hose 221 and the base end of the second air hose 222, respectively. An air regulator 230 including a pipe 232 and an air on/off valve 234 installed in the intermediate pipe 232, and a first timer in which an opening period of the air on/off valve 234 is set (235) and a second timer 236 in which an open holding time of the air on/off valve 234 is set.

In addition, the air supply unit 200 includes an air compressor 210 that generates pneumatic pressure, a first air hose 221 having a base end connected to the air compressor 210, and a tip introduced into the drain pipe 110 A second air hose 222 facing the first check valve 120a and an air-on having both ends connected to the front end of the first air hose 221 and the base end of the second air hose 222, respectively. It characterized in that it comprises a /off valve 234, and a control panel 201 for controlling the operation of the air on/off valve 234 and the air compressor 210.

In addition, the control panel 201 includes a first timer 235 in which an opening period of the air on/off valve 234 is set and a second timer in which an open maintenance time of the air on/off valve 234 is set. It characterized in that it includes (236).

In addition, the water level meter 400 includes a vertical plate 401, a horizontal plate 402 coupled to an upper portion of the vertical plate 401, and a first horizontal plate 402 installed parallel to the lower surface of the horizontal plate 402 The pulley 403 and the second pulley 404, and the first pulley 403 and the second pulley 404 are maintained across, and one end extends toward the water collected in the basement storage room 3, and the other end is an underground storage room (3) A wire 405 extending downward from the upper machine room, a float 406 connected to one end of the wire 405 and floating on the level of the water collected in the underground storage room 3, and the wire ( It characterized in that it comprises a weight 407 connected to the other end of the 405, and a tape measure 408 installed vertically along a section in which the height of the weight 407 is changed.

As described above, according to the present invention, there is an advantage in that an expensive explosion-proof submersible pump that has been conventionally used can be omitted.

In addition, the pneumatic drainage system for underground water collection according to the present invention can easily and accurately measure the water level in the underground storage room in which the underground storage tank is arranged, and this measured water level information can be effectively used for drainage by pneumatic pressure. .

The present invention solves both the low economic efficiency and safety problems caused by the use of non-explosion-proof pumps, which are problems of the existing bump drainage system. In addition, the present invention solves the problem of overheating of the pump of the prior art, the problem of having to repeatedly operate the pump directly by the administrator of the prior art, and the problem of the prior art requiring long-time use.

The present invention has a simple structure and principle and good economic efficiency by using electric equipment at a lower price than explosion-proof electric equipment.

1 is a block diagram showing a pneumatic drainage system for an underground water collecting well according to an embodiment of the present invention.
2 is a block diagram showing a pneumatic drainage system for an underground water collecting well according to another embodiment of the present invention,
3 is an electric circuit diagram of the pneumatic drainage system for water collection wells shown in FIG. 2.

Hereinafter, with reference to the accompanying drawings, a pneumatic drainage system 1 for underground water collection wells according to an embodiment of the present invention will be described in detail. First, it should be noted that in the drawings, the same components or parts are indicated by the same reference numerals as far as possible. In describing the present invention, detailed descriptions of related known functions or configurations are omitted in order not to obscure the subject matter of the present invention.

1 is a block diagram showing a pneumatic drainage system for an underground water collecting well according to an embodiment of the present invention.

Referring to Figure 1, the pneumatic drainage system 1 for underground water collection according to an embodiment of the present invention, so that the water level of the underground storage room 3 in which the storage tank 2 is buried does not exceed a certain level, It is configured to drain the water collected in the water collecting well 4 of the storage room 3.

The pneumatic drainage system (1) for underground water collection according to this embodiment not only allows the use of non-explosion-proof electrical equipment in the underground storage room (3), as well as non-explosion-proof electrical equipment in the explosion-proof section around the storage tank (2). It is structured to exclude the use of.

The pneumatic drainage system 1 for an underground collection well according to the present embodiment includes a drain pipe 110 having a water inlet through the water collection well 4 and a water outlet through the outside, and a water accumulation section in the drain pipe 110 And a drain unit 100 including a first check valve 120a and a second check valve 120b positioned between the first check valve 120a and the water outlet to form 112.

In this embodiment, the drain pipe 110 is surrounded by a collecting pipe 41. In this specification. The collecting pipe 41 is defined as being a part of the collecting well 4.

In addition, the pneumatic drainage system 1 for an underground water collection well of this embodiment supplies air to supply air to the upstream side of the first check valve 120a to generate a pressure to open the first check valve 120a. It further includes a unit 200.

In addition, the pneumatic drainage system 1 for underground water collection wells according to the present embodiment further includes a water level measuring device 400 for measuring the water level of the water collection well 4 in the underground storage room.

On the other hand, in the drainage unit 100, when the first check valve 120a is opened by an increase in the upstream pressure of the first check valve 120a, the drain pipe through the water inlet of the drain pipe 110 (110) Water introduced into the water accumulation section 112 enters and accumulates, and when the pressure in the water accumulation section 112 increases above a predetermined pressure value, the second check valve 120b is opened, Water accumulated in the water accumulation section 112 is discharged to the outside through the water outlet of the drain pipe 110.

Therefore, by controlling the upstream pressure of the first check valve 120a through the control of the air supply amount to the upstream side of the first check valve 120a, the amount of water accumulated in the water accumulation section 112 and accordingly It becomes possible to control the amount of drainage through the second check valve 120b.

In addition, the drainage unit 100 further includes a line check valve 111 installed at the water inlet to prevent water entering the drain pipe 110 from exiting the water collecting well or underground storage room again through the water inlet. I can.

In addition, the air supply unit 200 of this embodiment includes an air compressor 210 that generates pneumatic pressure, a first air hose 221 having a base end connected to the air compressor 210, and a leading end. The second air hose 222 introduced into the drain pipe 110 so that the end) faces the first check valve 120a, and both ends of the first air hose 221 and the second air hose ( And an air regulator 230 including an intermediate pipe 232 respectively connected to the base end of the 222 and an air on/off valve 234 installed at the intermediate pipe 232.

In this embodiment, the air compressor 210 may be an air compressor that is already used in a car wash or service corner of a charging station or gas station. It is preferable that the air regulator 230 is movable. The air regulator 230, as pneumatic elements, includes the intermediate pipe 232 and the air on/off valve 234, while opening a control and operation panel and the air on/off valve 234 It includes a first timer 235 for setting a period and a second timer 236 for setting an open holding time of the air on/off valve 234.

The first air hose 221 is flexible, and its base end is connected to the air outlet of the air compressor 210 and its tip is separated from the inlet of the air regulator 230, that is, one end of the intermediate pipe 232 Connected as possible.

In addition, the second air hose 222 has a front end introduced into the drain pipe 110 to supply air to the upstream side of the first check valve 120a installed in the drain pipe 110, and the base end of the air regulator 230 It is detachably connected to the outlet of, that is, the other end of the intermediate pipe 232. In order to introduce the second air hose 222 into the drain pipe 110, it is connected to an air connector installed in the drain pipe 110, and the air connector passes through the upstream side of the first check valve 120a.

In addition, the first air hose 221 and the second air hose 222 have a connector type between the air compressor 210 and the air regulator 230 and between the air regulator 230 and the drain pipe 110 It is connected and used in a connector way, and can be recovered and stored after being used for water drainage in the underground storage room (3). Alternatively, it should be noted that the first air hose 221 or the second air hose 222 may be installed in the form of a rigid pipe upon request.

In addition, the air regulator 230, as a pneumatic element, further includes a regulator 237 on the upstream side of the air on/off valve 234, and as an electrical element, a power circuit breaker 238 and an operation switch ( 239) and the like.

The water level meter 400 includes a vertical plate 401, a horizontal plate 402 coupled to an upper portion of the vertical plate 401, and a first pulley installed parallel to the lower surface of the horizontal plate 402 ( 403) and the second pulley 404, and the first pulley 403 and the second pulley 404 are held across and have one end extending toward the water collected in the basement storage room 3, and the other end of the basement storage room 3 ) A wire 405 extending downward from the upper machine room, a float 406 connected to one end of the wire 405 and floating on the level of water collected in the underground storage room 3, and the wire 405 It includes a weight 407 connected to the other end of the, and a tape measure 408 installed vertically along a section in which the height of the weight 407 is changed. In this case, the tape measure 408 may be fixed to the vertical plate 401.

In addition, a cap 409 in contact with the wire 405 to maintain the equilibrium of the wire 405 while positioned at an arbitrary height between the first pulley 403 and the float 406 is further added. Can be provided. In addition, a detection tube 410 extending long to the collected water while being combined with the cap 409 may be further provided. The detection tube 410 also contributes to maintaining the balance of the wire 405 by suppressing the shaking of the wire 405.

In the water level measuring device 400 as above, when the water level rises, the float 406 also rises with the water level. Accordingly, the weight 407 descends downward by the height of the float 406 ascended. Conversely, when the water level goes down, the float 406 also goes down with the water level. Accordingly, the weight 407 rises upward by the height at which the float 406 descended. In this way, since the change in height of the weight 407 corresponds to the change in height and the water level of the float 406, the scale of the tape measure 408 indicated by the weight 407 may indicate the water level.

As above, the administrator can measure the water collected in the underground storage room, that is, the level of the water collection well 4 from the scale of the tape measure 408 that matches the weight 407 whose height has changed. In addition, the manager may operate the air supply unit 200 by using the water level information of the water collection well 4 measured using the water level measuring device 400. It may also be considered that the water level information of the water level meter 400 is changed to an electric signal and used for automatic control of the air supply unit 200.

A specific example of the method and operation of the pneumatic drainage system for underground water collection according to the present embodiment will be described.

First, the manager connects the air compressor 210 located in the non-explosion-proof section and the air regulator 230 used in the non-explosion-proof section with a first air hose 221. The first air hose 221 is connected by a connector method. The air regulator 230 includes an operation and control panel. In addition, the manager connects the air regulator 230 and the drain unit 100 with the second air hose 222. At this time, the tip of the second air hose 222 is connected to the drain pipe 111 of the drain unit 100 in a connector manner to be introduced into the drain pipe 111.

Next, the manager turns on the electric breaker 238 of the operation and control panel provided in the air regulator 230 and turns on the switch 239 of the operation and control panel. If necessary, the opening period of the air on/off valve 234 of the first timer 235 may be reset, and the open maintenance time of the air on/off valve 234 of the second timer 236 may be reset. I can. The opening period of the on/off valve 234 corresponds to a waiting time for collecting water and may be set to 30 seconds at the time of shipment. The open maintenance time of the air on/off valve 234 may be set to 2 seconds at the time of shipment.

When the water level measured by the water level meter 400 reaches 300 mm, the operation of the air supply unit 200 may be started automatically or manually. When the air supply unit 200 is operated, according to signals from the first timer 235 and the second timer 236, the air on/off valve 234 is opened for about 2 seconds after the 30 second waiting time, and 2 Air is supplied to the upstream side of the first check valve 120a of the drain pipe 110 for seconds. By this operation, the first check valve 120a is opened for about 2 seconds, and water in the water collecting well 4 flows into the water accumulation section 112 in the drain pipe 110. Water is collected in 30 seconds and the first check valve 120a is opened repeatedly for about 2 seconds, so that water is accumulated in the water accumulation section 112. The increase in pressure in the water accumulation section 112 opens the second check valve 120b, and by this opening, water in the drain pipe 110 can be discharged to the outside. When the water level measured by the water level meter 400 is less than 150 mm, the operation of the air supply unit 200 may be automatically or manually stopped.

2 is a block diagram showing a pneumatic drainage system for an underground water collection well according to another embodiment of the present invention, and FIG. 3 is an electric circuit diagram of the pneumatic drainage system for a water collection well shown in FIG. 2.

2 and 3, the pneumatic drainage system 1 for underground water collection according to the present embodiment, so that the water level of the underground storage room 3 in which the storage tank 2 is buried does not exceed a certain level, It is configured to drain the water collected in the water collecting well 4 of the storage room 3.

The pneumatic drainage system 1 for an underground water collecting well according to the present embodiment includes a drain pipe 110 having a water inlet through the water collecting well 4 and a water outlet through the outside, and a first check valve 120a, And a drain unit 100 including a second check valve 120b located downstream of the first check valve 120a.

A water accumulation section 112 is formed between the first check valve 120a and the second check valve 120b. The periphery of the drain pipe 110 is surrounded by a water collecting pipe 41.

In addition, the pneumatic drainage system 1 for the underground water collecting well of this embodiment, as in the previous embodiment, to generate a pressure to open the first check valve (120a), the upstream side of the first check valve (120a). It further includes an air supply unit 200 for supplying air to and a water level measuring device 400 for measuring a water level in the underground storage room.

In the drainage unit 100, when the first check valve 120a is opened by an increase in pressure upstream of the first check valve 120a, water introduced into the drain pipe 110 through the water inlet It enters into the water accumulation section 112 and is accumulated. When the pressure in the water accumulation section 112 increases above a predetermined pressure value, the second check valve 120b is opened and discharged to the outside through the water outlet of the drain pipe 110.

Therefore, by controlling the upstream air supply amount of the first check valve 120a, when controlling the pressure on the upstream side of the first check valve 120a, the amount of water accumulated in the water accumulation section 112 and the amount of water discharged accordingly are controlled. It becomes possible to do.

In addition, the air supply unit 200 of the present embodiment includes an air compressor 210 that generates pneumatic pressure, a first air hose 221 having a base end connected to the air compressor 210, and a front end of the drain pipe 110 A second air hose 222 that is introduced into the first check valve 120a, and both ends are connected to a front end of the first air hose 221 and a base end of the second air hose 222, respectively. Air on/off valve 234 is included.

In addition, the air supply unit 200 of this embodiment includes a control panel 201 for controlling the operation of the air on/off valve 234 and the air compressor 210. The control panel 201 includes an on/off switch 239 for turning on/off the operation of the air supply unit 200, and a first timer 235 for setting an open cycle of the air on/off valve 234. ) And a second timer 236 for setting an open holding time of the air on/off valve 234. Further, the control panel 201 is provided with a circuit breaker for the air compressor 210 and the air on/off valve 234.

In addition, a regulator 237 may be installed in the first air hose 221.

Since the water level meter 400 is of the same configuration as the previous embodiment, additional description will be omitted to avoid redundancy.

Optimal embodiments have been disclosed in the drawings and specification. Although specific terms have been used herein, these are only used for the purpose of describing the present invention, and are not used to limit the meaning or the scope of the present invention described in the claims. Therefore, those of ordinary skill in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical scope of the present invention should be determined by the technical spirit of the appended claims.

100: drain unit 110: drain pipe
112: water accumulation section 120a, 120b: first, second check valve
200: air supply unit 400: water level meter

Claims (5)

A pneumatic drainage system for underground water collection wells that doubles the use of electrical equipment in the basement storage room or the explosion-proof area around the basement storage room,
A water inlet through the water collecting well 4 and a water outlet through the outside, including a drain pipe 110 and a first check valve 120a installed in the drain pipe 110 and the first check valve 120a, A drain unit 100 in which a water accumulation section 112 is formed between the first check valve 120a and the second check valve 120b;
An air supply unit 200 selectively opening the first check valve 120a by supplying air to an upstream side of the first check valve 120a in the drain pipe 100; And
Including a water level measuring device 400 for measuring the water level of the collection well 4 in the underground storage room,
When the first check valve 120a is opened by an increase in the upstream pressure of the first check valve 120a, the water flowing into the drain pipe 110 through the water inlet of the drain pipe 110 is Pneumatic drainage system for underground water collection wells, characterized in that after entering into the accumulation section 112 and accumulating, discharged when the second check valve 120b is opened. The method of claim 1,
The air supply unit 200 includes an air compressor 210 that generates pneumatic pressure,
A first air hose 221 whose base end is connected to the air compressor 210,
A second air hose 222 introduced into the drain pipe 110 so that the tip faces the first check valve 120a,
An intermediate pipe 232 having both ends connected to the front end of the first air hose 221 and the base end of the second air hose 222, respectively,
An air regulator 230 including an air on/off valve 234 installed in the intermediate pipe 232,
A first timer 235 in which an opening period of the air on/off valve 234 is set, and
A pneumatic drainage system for underground water collection wells, characterized in that it comprises a second timer (236) in which an open holding time of the air on/off valve (234) is set. The method of claim 1,
The air supply unit 200 includes an air compressor 210 that generates pneumatic pressure,
A first air hose 221 whose base end is connected to the air compressor 210,
A second air hose 222 having a tip introduced into the drain pipe 110 and facing the first check valve 120a,
An air on/off valve 234 having both ends connected to the front end of the first air hose 221 and the base end of the second air hose 222, respectively,
And a control panel (201) for controlling the operation of the air on/off valve (234) and the air compressor (210). The method of claim 3,
The control panel 201 includes a first timer 235 in which an opening period of the air on/off valve 234 is set and a second timer 236 in which an open maintenance time of the air on/off valve 234 is set. Pneumatic drainage system for underground water collection, characterized in that it comprises a). The method of claim 1,
The water level measuring device 400,
With a vertical plate 401,
A horizontal plate 402 coupled to an upper portion of the vertical plate 401,
A first pulley 403 and a second pulley 404 installed parallel to the lower surface of the horizontal plate 402,
The first pulley 403 and the second pulley 404 are held across and one end extends toward the water collected in the basement storage room 3, and the other end extends downward from the upper machine room of the basement storage room 3 )Wow,
A float 406 connected to one end of the wire 405 and floating on the level of the water collected in the underground storage room 3,
A weight 407 connected to the other end of the wire 405,
Pneumatic drainage system for underground water collection wells, characterized in that it comprises a tape measure 408 installed vertically along a section in which the height of the weight 407 is changed.

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