KR100330508B1 - Flood preventing apparatus for a tubular well - Google Patents

Abstract

The present invention relates to an apparatus for preventing infiltration of groundwater cores to properly regulate the pressure in the sealed groundwater cores and to prevent contamination from entering the cores from the outside.

The present invention as described above, and the heart cover to seal the groundwater heart well; An intake and exhaust pipe installed to penetrate or inject air into the heart well through the heart lid; A suction discharge tank connected to an end of the suction discharge pipe and formed with an air discharge portion and an air suction portion; First valve means installed at an air discharge portion of the intake and discharge tank and opened only when an internal pressure is higher than a predetermined value; It is characterized in that it comprises a second valve means which is installed in the air intake portion of the intake and exhaust tank to suck the outside air and at the same time block the air intake portion when the immersion occurs.

Description

Flood preventing apparatus for a tubular well}

The present invention relates to an apparatus for preventing infiltration of groundwater cores to properly regulate the pressure in the sealed groundwater cores and to prevent contamination from entering the cores from the outside.

1 is a block diagram showing the pumping device of the groundwater heart well.

When the groundwater in the heart well (1) sealed by the heart lid (6) is pumped by the heart pump (2), when the groundwater flows up to the upper level switch (4), the heart pump (2) is operated. The groundwater is pumped through the pump pipe 9.

In this way, when the groundwater level in the heart well 1 falls and reaches the lower level switch 5, the operation of the heart pump 2 is stopped and the pumping of the ground water is also stopped.

When the water level rises again due to the change of the groundwater level, the air inside the groundwater well (1) is discharged to the outside of the groundwater well (1), and when a large amount is instantaneously discharged, the groundwater well pump (2) Immediately after the operation stops.

In addition, when the cardiac pump 2 starts to operate according to the operation of the upper level switch 4, the groundwater level is lowered. At this time, air is sucked from the outside to compensate for the volume.

The present inventors have studied these characteristics of the groundwater deep well and the groundwater vein cleaning using the vacuum force generated during the operation of the groundwater deep well pump 2 through the groundwater vacuum pumping device described in Patent No. 85738 (95.6.14). The effect of increasing the amount of groundwater withdrawal has been described.

However, the above-mentioned patent invention has a premise that the heart well 1 is completely sealed through the heart well cover 6, but there is a limit to preventing the inflow of contaminated surface water through an intake valve (not shown) in case of a flooding accident. In the case of adopting the intake valve using the filter tank, there was also a problem that the flooding of the contamination surface water through the intake air inlet pipe also does not have sufficient preventive measures.

The present invention has been made to solve the above problems, it is possible to properly prevent the inflow of contaminated surface water into the heart well even when the groundwater core cover is flooded, as well as to prevent the inflow of contaminated air to properly pressure inside the heart well The purpose of the present invention is to provide a groundwater protection device for preventing the occurrence of groundwater contamination.

1 is a schematic view showing the groundwater pumping device,

Figure 2 is a block diagram showing the inundation prevention device of the groundwater core according to the present invention,

3 is a cross-sectional view showing an exhaust check valve according to the present invention;

4 is a cross-sectional view showing an intake valve for preventing water inflow according to the present invention;

5 is a cross-sectional view showing an exhaust valve check valve according to the present invention.

<Explanation of symbols for main parts of the drawings>

6: core cover 9: pumping pipe

51: suction exhaust pipe 60: suction discharge tank

61 tank body 62 partition plate

63 tank cover 64 drain valve

65 antibacterial filter 66 intake pipe

67: disinfectant fluid 68: liquid level gauge

69: on-off valve 70: check valve for exhaust

71 exhaust pipe 72 valve cover

74: leaf spring 75: O-ring

80: intake valve for preventing water inflow 81: intake pipe

82: valve case 83: valve cap

84: filter network 85: valve buoyancy body

86 valve stem 87 buoyancy body

88: valve guide 89: o-ring

90 check valve for exhaust shutoff 91 valve body

93: check ball 94: spring

In order to achieve the above-mentioned problems, an apparatus for preventing infiltration of groundwater heart wells includes: a heart well cover for sealing groundwater wells; An intake and exhaust pipe installed to penetrate or inject air into the heart well through the heart lid; A suction discharge tank connected to an end of the suction discharge pipe and formed with an air discharge portion and an air suction portion; First valve means installed at an air discharge portion of the intake and discharge tank and opened only when an internal pressure is higher than a predetermined value; It is characterized in that it comprises a second valve means which is installed in the air intake portion of the intake and exhaust tank to suck the outside air and at the same time block the air intake portion when the immersion occurs.

According to an embodiment of the present invention, the intake and exhaust tank is divided into two chambers up and down through a partition plate, the air intake chamber is located above, and the air discharge chamber is located below; An intake hole is formed in the partition plate, and a third valve means is provided in the intake hole to open when negative pressure is generated in the heart well so that external air is sucked in.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

Figure 2 is a block diagram showing a groundwater deep immersion prevention device according to the present invention.

The present invention provides a heart lid 6 'for sealing the groundwater heart well, a suction and exhaust pipe 51 installed to penetrate or discharge air into the heart well through the heart lid 6', and the suction and exhaust pipe ( 51 is connected to the end of the intake and exhaust tank 60, the air is sucked or discharged, and the exhaust check valve is connected to the air outlet (61a) of the intake and exhaust tank 60 is opened only when the internal pressure is a predetermined or more ( 70) and an intake valve 80 for preventing water inflow, which is connected to the air intake port 61b of the intake and exhaust tank 60 and inhales outside air and blocks the intake port at the time of flooding.

A pump pipe 9 'for pumping ground water is installed in the cardiac lid 6', and an opening / closing valve 55 is installed in the suction and discharge pipe 51 to block an air flow path as necessary. .

In addition, the intake and exhaust tank 60 is coupled to an upper portion of the tank body 61 formed with an intake port 61a, an exhaust port 61b, and a communication port 61c, and an upper portion of the tank body 61 to seal the inside thereof. The cover 63 is comprised.

The tank body 61 is divided into two upper and lower chambers A and B through a partition plate 62 installed at the center portion, and connected to an intake valve 80 for preventing water inflow through an air inlet 61b. The air inlet chamber A is positioned, and the lower side is an air outlet chamber B connected to the intake and exhaust pipe 51 and the exhaust check valve 70 through the communication port 61c and the outlet port 61a. do.

Here, the antibacterial filter 65 is installed in the air suction chamber A to purify the air introduced into the air intake port 61b through the water intake prevention intake valve 80 and then flow into the heart well.

The antibacterial filter 65 has a tubular shape of a predetermined size and is fixed to the support part 61d formed in the tank main body 61.

A partition plate 62 is provided below the antibacterial filter 65. An intake hole 62a is formed in the partition plate 62, and a negative pressure is generated in the intake hole 62a. When the exhaust valve check valve 90 is installed to open when the outside air is sucked.

A disinfecting fluid 67 is inherent in the air discharge chamber B, and an intake pipe 66 is provided inside the disinfecting fluid 67 from the exhaust shutoff check valve 90.

The intake pipe 66 is installed so that its end portion is positioned lower than the air outlet 61a and the communication port 61c so as to be immersed in the disinfecting fluid 67, and thus through the exhaust shutoff check valve 90. The introduced external air passes through the disinfecting fluid 67 and then flows into the heart through the suction and exhaust pipe 51.

In addition, a liquid level gauge 68 is installed in the tank main body 61 so as to check a storage state of the disinfecting fluid 67 at a side position of the air discharge chamber B.

In addition, a drain valve 64 is installed at a lower portion of the tank main body 61 to discharge the disinfecting fluid 67 and to clean the inside of the tank.

Three valves 70, 80, 90 are installed in the intake and exhaust tank 60 is configured as described above in detail as follows.

First, the exhaust check valve 70 is installed at the end of the exhaust pipe 71 connected to the outlet 61a of the tank body, as shown in FIG.

That is, the valve cover 72 is connected to the end of the exhaust pipe 71 by a hinge 73, the leaf spring 74 is provided on the outside of the valve cover 72 to be maintained in the closing force.

In addition, an o-ring 75 is installed between the end of the exhaust pipe 71 and the valve cover 72 to maintain airtightness.

Next, the inlet valve 80 for preventing water inflow is installed at the end of the intake pipe 81 connected to the intake and exhaust tank as shown in FIG. It is composed of a valve buoyancy body (85), which is inherent in (82) and closes the valve hole while rising along the surface when flooded.

In the valve case 82, a valve guide 88 is formed which forms a valve hole 88a and guides the vertical movement of the valve buoyancy body 85. An inlet side of the valve guide 88 is provided. When the valve buoyancy body 85 is raised, an o-ring 89 is installed.

The valve buoyancy body 85 is a buoyancy body 87 which rises by water flowing into the valve case 82 when flooded, and stands vertically on the upper portion of the buoyancy body 87 to provide the valve guide body. It consists of a valve stem 86 inserted into the guide hole 88b of the 88.

In addition, a valve cap 83 having a hole 83a is coupled to a lower portion of the valve case 82, and foreign substances and worms are introduced into the hole 83a of the valve cap 83. A filter net 84 for blocking is installed.

On the other hand, the suction pipe 81 is provided with an on-off valve 69 for vacuum water vein cleaning as shown in FIG.

Next, the exhaust shut-off check valve 90 is installed between the partition plate 62 and the intake pipe 66 as shown in FIG. 5 and the valve body 91 having the valve hole 91a formed therein, and A check ball 93 inserted into the valve body 91 to restrict the flow of air from the intake pipe 66 toward the partition plate 62; and a spring 94 for providing a predetermined elastic force to the check ball 93; It is composed of

The valve body 91 is provided with a sealing ring 92 to improve the sealing function in a portion where the check ball 93 is in close contact.

Referring to the operation of the present invention configured as described above are as follows.

In general, the air sucked into the groundwater well is introduced into the groundwater well through the antibacterial filter 65 and the disinfecting fluid through the intake valve 80 for preventing water inflow, thereby preventing contamination of groundwater from the polluted atmosphere. do.

At this time, the valve buoyancy body 85 of the water inflow prevention intake valve 80 is lowered by its own load, thereby opening the air intake passage.

When the groundwater level is discharged while the groundwater level rises inside the groundwater well, the check ball 93 is pushed up by the elastic force of the spring 94 and the pressure of the discharged air at the check-off valve 90 for exhaust air suction. Exhaust air is not introduced into the seal A side, thereby preventing the life and function of the antimicrobial filter 65 from decreasing due to the humid air discharged from the groundwater core.

The air blocked in the exhaust shutoff check valve 90 is naturally discharged through the exhaust check valve 70. That is, when the pressure in the tank rises, the valve cover 72 opens while pushing the leaf spring 74 having a weak force to release the discharge air of the groundwater core to the outside.

Next, in case of rain, the upper side of the core cover 6 'as well as when the water is immersed up to a predetermined height of the intake and exhaust tank 60, the exhaust cover check valve 70 side of the valve cover 47 is the elastic force of the leaf spring 48 In addition, since the exhaust pipe 71 is more strongly blocked due to the buoyancy of the water level or the water pressure formed by immersion, the inflow of the contaminated surface water is blocked.

In addition, the inflow valve 80 for preventing water inflow is gradually introduced into the valve case 82 through the valve cap 83 while the contamination index water is gradually increased due to the ingress of the intake and discharge tank 60. ) Will move upward along the surface due to buoyancy.

Thereafter, the valve buoyancy body 85 blocks the valve hole 88a of the valve guide body 88 so that the contamination surface water flows into the intake and discharge tank 60 and the groundwater core well through the intake pipe 81 side. Fundamentally preventable.

Accordingly, the device for preventing infiltration of groundwater heart wells of the present invention configured and operated as described above prevents the inflow of contaminated surface water into the heart well as well as the groundwater heart well cover as well as the intake and exhaust tanks. By preventing inflow, there is an advantage in that groundwater can be prevented from being contaminated, and there is also an advantage in that the pressure inside the heart can be adjusted more appropriately.

Claims (7)

A heart cover 6 'for sealing the ground water heart well; A suction and discharge pipe 51 installed to penetrate or discharge air into the heart well through the heart lid 6 '; An intake and discharge tank 60 connected to an end of the intake and exhaust pipe 51 and formed with an air outlet 61a and an air intake port 61b; First valve means (70) installed in the air outlet (61a) of the intake and exhaust tank (60) and opened only when the internal pressure is above a certain level; Submerged in the groundwater core, characterized in that it is installed in the air inlet 61b of the intake and discharge tank 60, and intakes external air and at the same time includes a second valve means 80 for blocking the air inlet 61b when inundation occurs. Prevention device. The method of claim 1, The intake and exhaust tank 60 is divided into two chambers up and down through the partition plate 62, the air intake chamber (A) is located on the upper side, the air discharge chamber (B) is located on the lower side; An intake hole 62a is formed in the partition plate 62, and the third valve means prevents inflow of wet air discharged from the heart into the air intake chamber A in the intake hole 62a. 90) is provided in the groundwater prevention device of the hearth water characterized in that the installation. The method according to claim 1 or 2, The infiltration prevention device of the groundwater core, characterized in that the filter means for purifying the intake air flowing through the second valve means (80) is installed inside the intake discharge tank (60). The method of claim 2, A disinfecting fluid 67 is embedded in the air discharge chamber B of the intake and exhaust tank 60, and the intake pipe 66 is provided from the intake hole 62a of the partition plate 62 to the lower side of the tank 60. The long water extends so that the end is submerged in the disinfecting fluid (67). The method of claim 2, The first valve means (70) and the third valve means (90) are each composed of a valve body (72) (93) for blocking a pipeline and an elastic member (74) (94) for providing an elastic force to the valve body. An intrusion prevention device for groundwater cores, characterized in that it is a check valve for prevention. The method of claim 1, The second valve means (80) is an intake pipe (81) communicating with the outside of the intake and discharge tank (60), and a valve case (82) installed at the end of the intake pipe (81) and open at the bottom; And a valve buoyancy body (85) which is embedded in the valve case (82) and rises along the water surface during the inundation and blocks the suction hole of the intake pipe (81). The method of claim 6, The lower part of the valve casing 82, the filtration network 84 is installed in order to block the inflow of foreign substances or insects, characterized in that the groundwater heart immersion prevention device.