KR101144289B1 - Water sampler - Google Patents

Abstract

PURPOSE: A water sampling apparatus is provided to improve measurement accuracy by preventing underground water existing in each layer of a tube well from being mixed with each other. CONSTITUTION: A water sampling apparatus comprises a casing(100), a strainer(200), water outlets(300), and first and second packers(400,500). The casing is vertically inserted into a tube well formed in the ground and has a hollow. The strainer is vertically inserted into the hollow of the casing and has multiple inlet holes(210). The water outlets pump underground water existing inside the tube well to the ground. The first packer is coupled to the strainer and closes the tube well. The second packer is located inside a through hole of the first packer and is inflated by water pressure to close the through hole of the first packer.

Description

Water Harvester {WATER SAMPLER}

The present invention relates to a water collecting device, and more particularly, after dividing each layer of a well into a first packer and a second packer, a water collecting device capable of selectively dividing and measuring the groundwater present in each layer of the well. It is about.

In general, groundwater refers to water that fills or runs through gaps between underground strata and rocks.

Recently, as industrialization progresses, environmental pollution is getting serious, and soil pollution is getting serious.

Therefore, a groundwater deep well aquifer investigation collection device is used to prevent groundwater inflow of the upper groundwater wells or to carry out a pumping test survey for each groundwater core.

Such a conventional water collecting device includes a cylindrical casing inserted into a well formed in the ground, a pumping pipe connected to the casing, a power cable for power transmission, a pumping pump for pumping water, a measuring sensor, and the like. .

By the way, the conventional water harvesting device can sequentially withdraw and measure the groundwater present in each layer of the well, but it was difficult to individually discharge the groundwater so as not to mix with each other.

It is an object of the present invention to selectively divide and measure the groundwater present in each layer of a well by partitioning each layer of the well by using a first packer and a second packer inflated by a hydraulic pressure supply. Therefore, the groundwater of each layer is not mixed with each other.

The present invention provides a hollow casing inserted into a well formed in the ground, a hollow strainer inserted into a hollow of the casing, and a plurality of inlet holes are formed along a longitudinal direction, and a ground water inserted into a hollow of the strainer. The first packer for pumping the ground to the ground and coupled to the longitudinal direction of the strainer, the through hole is formed so that the groundwater is withdrawn through the water outlet, and is expanded by the water pressure supplied from the outside to close the well And a second packer positioned in the through-hole of the first packer in a state coupled to the water outlet, and expanding by the water pressure supplied from the outside to close the through-hole.

Here, it is preferable that the water extraction part is provided with a water outlet pipe inserted into the hollow of the strainer, and a water pump installed at a lower end of the water outlet pipe and pumping groundwater from the upper and lower portions of the second packer.

In addition, the first packer is coupled to the longitudinal direction of the strainer, the first frame is formed in the through hole vertically, and is installed on the outer surface of the first frame, is expanded to the side when the hydraulic pressure supply of the well It is preferable that the first expansion tube is in close contact with the wall surface, and the first pressure tube is connected to the first expansion tube, and transmits the water pressure supplied from the outside to the first expansion tube.

In addition, the second packer is installed on the second frame and the second frame is formed in the vertical coupling hole vertically coupled to the longitudinal direction of the water discharge pipe, the side surface when the hydraulic pressure supply is expanded to the wall surface of the through hole It is preferable that the second expansion tube in close contact with the second expansion tube, the second pressure tube is connected to the second expansion tube to transmit the water pressure supplied from the outside.

In addition, the first expansion tube and the second expansion tube is installed in a cylindrical shape on the outer surface of the first frame and the second frame, it is preferable that the side when the expansion is in close contact with the wall surface of the well as a whole.

In addition, the first packer and the second packer is coupled in plurality along the vertical length direction of the strainer, and closes each layer of the wells in multiple stages, and the water extraction part is an upper portion of the first packer and the second packer. Or it is preferably provided with a plurality in order to pump the groundwater at the bottom.

The present invention has the effect of collectively or selectively withdrawing and measuring the groundwater present at different heights in the state of partitioning each layer of the well by using the first packer and the second packer inflated during hydraulic pressure supply.

In addition, it can also be used in the soft ground wells that may be easily collapsed due to its strength, which has a wide range of effects.

In addition, since the groundwater present in each layer of the well is not mixed with each other, it has the effect of ensuring the accuracy and ease of groundwater discharge and measurement.

1 is a front sectional view for showing a water collecting device according to the present invention.
2 is a perspective view for showing a first packer and a second packer of the water collecting device according to the present invention.
3 is an installation state diagram for showing an installation state of the water collecting device according to the present invention.
4 is an enlarged view for showing a first packer and a second packer of the water collecting device according to the present invention.

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

Advantages and features of the present invention, and a method of achieving the same will be apparent with reference to the embodiments described below in detail with reference to the accompanying drawings.

However, the present invention is not limited by the embodiments disclosed below, but will be implemented in various forms, and only the present embodiments make the disclosure of the present invention complete, and those skilled in the art to which the present invention pertains. It is provided to fully inform the person having the scope of the invention, which is defined only by the scope of the claims.

In addition, in the following description of the present invention, if it is determined that related related technologies and the like may obscure the gist of the present invention, detailed description thereof will be omitted.

1 is a front sectional view for showing a water collecting device according to the present invention, Figure 2 is a perspective view for showing a first packer and a second packer of the water collecting device according to the present invention.

3 is a plan sectional view showing the first packer and the second packer of the water collecting device according to the present invention, and FIG. 4 is an installation state diagram for showing the installation state of the water collecting device according to the present invention.

4 is an enlarged view for showing the first packer and the second packer of the water collecting device according to the present invention.

1 to 4, the water collecting device according to the present invention is a casing 100, a strainer 200, a water extraction unit 300, a first packer (Packer, 400), and a second packer 500.

First, the casing 100 is vertically inserted into the well 10 formed in the ground.

Here, the casing 100 may have a cylindrical shape through which the hollow 110 is formed along the longitudinal direction.

In addition, a lower end of the casing 100 may be positioned to penetrate the crushing stand 11, which is a part of which the rock is broken along the basement fault.

The strainer 200 is inserted into the hollow of the casing 100 vertically, and a plurality of inflow holes 210 are laterally penetrated along the longitudinal direction.

Here, the strainer 200 may have a cylindrical shape in which the hollow 220 penetrates along the length direction.

At this time, the upper end of the strainer 200 is located in the hollow of the casing 100, the lower end is further extended to the lower end of the casing 100 is located in the well 10.

The inlet holes 210 allow groundwater existing between the strainer 200 and the well 10 to flow into the hollow of the strainer 200.

In this case, the inflow holes 210 may be located adjacent to each other by forming a group.

In addition, the plurality of inflow holes 210 forming one group may be arranged in a plurality along the vertical length direction of the strainer 200.

That is, the first packer 400 and the second packer 500 to be described later may be disposed between the inlet holes 210 formed in a plurality of groups along the vertical length direction of the strainer 200.

The water outlet 300 is inserted into the hollow of the strainer 200 and serves to pump groundwater existing in the inside of the well 10 to the ground.

Here, the water extraction unit 300 is installed in the water outlet pipe 310 is inserted into the hollow of the strainer 200, and the bottom of the water outlet pipe 310, the groundwater in the upper and lower portion of the second packer 500 An underwater pump 320 for pumping is provided.

The discharge pipe 310 is inserted into the hollow 220 of the strainer 200 to withdraw the groundwater to the ground.

In addition, the water discharge pipe 310 may be further provided with a power line (not shown) for supplying power to the submersible pump 320.

In addition, a power supply unit (not shown) and a controller (not shown) for supplying power may be further connected to an upper end of the power line.

The submersible pump 320 is installed at the lower end of the discharge pipe 310 and pumps groundwater from the upper and lower portions of the first packer 400 and the second packer 500 to be described later.

That is, the lower end of the water discharge pipe 310 and the submersible pump 320 are the upper portion of the first packer 400 and the second packer 500 to be described later, and the through hole 411 of the first frame 410 to be described later. Through the first packer 400 and the second packer 500 may be located respectively.

At this time, the submersible pump 320 is located at the height of the inlet holes 210, the groundwater flowing into the hollow 220 of the strainer 200 through the inlet holes 210 can be easily withdrawn.

The first packer 400 is coupled to the longitudinal direction of the strainer 200, the through hole 411 is formed so that the groundwater is withdrawn through the water outlet 300, is expanded by the water pressure supplied from the outside of the well (10) is closed.

To this end, the first packer 400 is composed of a first frame 410, a first expansion tube 420, a first pressure tube 430, and a first pressure adjusting unit 440.

The first frame 410 is coupled to the longitudinal direction of the strainer 200, the through hole 411 is formed vertically.

Here, the first frame 410 has a cylindrical shape corresponding to the strainer 200.

 To this end, the strainer 200 is horizontally divided vertically in the longitudinal portion.

In addition, the first frame 410 may be coupled to the upper and lower ends of the upper and lower ends of the strainer 200, respectively.

In this case, divided upper and lower ends of the strainer 200 and upper and lower ends of the first frame 410 may be coupled by welding.

That is, the outlet pipe 310 and the submersible pump 320 which will be described later through the through hole 411 of the first frame 410 may be located on each floor of the well 10.

On the other hand, the strainer 200 may be coupled in a vertically inserted state through the through hole 411 of the first frame 410.

For example, the fastening member (not shown) may be fastened through the outside of the first frame 410 or the hollow 220 of the strainer 200 to integrally connect the first frame 410 and the strainer 200. Can be combined.

The first expansion tube 420 is installed on the outer surface of the first frame 410, is expanded to the side when the hydraulic pressure supply is in close contact with the wall surface of the well 10.

Here, the first expansion tube 420 may be any one of a tube such as a synthetic resin material and a rubber material, but may be a tube such as a metal material if necessary.

The first expansion tube 420 may be installed in a cylindrical shape on the outer surface of the first frame 410.

That is, when water pressure is supplied into the first expansion tube 420, the side surface of the first expansion tube 420 may be expanded laterally to closely support the wall surface of the well 10.

Thus, as the side of the first expansion tube 420 is in close contact with the wall surface of the well 10, the space between the first frame 410 and the well 10 is sealed and partitioned up and down.

The first pressure tube 430 is connected to the first expansion tube 420 serves to supply and discharge the water pressure.

Preferably, the lower end of the first pressure tube 430 is coupled to the upper edge portion of the first frame 410 may be connected to the upper end of the first expansion tube (420).

In addition, an upper end of the first pressure pipe 430 may be connected to the first pressure control unit 440 located on the ground through the hollow 220 of the strainer 200.

Here, the lower end of the first pressure pipe 430 and the upper end of the first frame 410 may be coupled by a screw coupling method by a separate connection member (not shown).

The first pressure adjusting unit 440 is installed on the ground, and supplies and discharges a predetermined hydraulic pressure through the first pressure pipe 430 while the upper end of the first pressure pipe 430 is connected.

Here, the first pressure control unit 440 may use a device such as a compressor.

That is, when water pressure is supplied from the first pressure adjusting unit 440 to the first pressure pipe 430, the first expansion tube 420 connected to the first pressure pipe 430 is expanded by the water pressure.

The second packer 500 is located in the through hole 411 of the first packer 400 in a state coupled to the water outlet 300 in the longitudinal direction, and is expanded by the hydraulic pressure supplied from the outside to the through hole ( Close 411).

To this end, the second packer 500 includes a second frame 510, a second expansion tube 520, a second pressure tube 530, and a second pressure adjusting unit 540.

The second frame 510 is coupled to the longitudinal direction of the outlet pipe 310 and is located in the through hole 411 of the first packer 400.

In addition, at least one coupling hole 511 is vertically formed in the second frame 510 so that the second pressure pipe 530 may be coupled therethrough.

The second expansion tube 520 is installed on the outer surface of the second frame 510, and expands the side surface at the time of hydraulic pressure supply, and is in close contact with the wall surface of the through hole 411.

Here, the second expansion tube 520 may be any one of a tube such as a synthetic resin material and a rubber material, but may be a tube such as a metal material if necessary.

The second expansion tube 520 may be installed in a cylindrical shape on an outer surface of the second frame 510.

That is, when water pressure is supplied into the second expansion tube 520, the side surface of the second expansion tube 520 may be expanded laterally to closely support the wall surface of the well 10.

Therefore, as the side of the second expansion tube 520 is in close contact with the wall surface of the through hole 411, the through hole 411 of the first frame 410 is sealed and partitioned up and down.

The second pressure tube 530 is connected to the second expansion tube 520 serves to supply and discharge the water pressure.

Preferably, the lower end of the second pressure tube 530 may be coupled to the upper edge portion of the first frame 410 to be connected to the upper end of the second expansion tube 520.

In addition, an upper end of the second pressure pipe 530 may be connected to the second pressure control unit 540 positioned on the ground through the hollow 220 of the strainer 200.

Here, the lower end of the second pressure tube 530 and the upper end of the second frame 510 may be coupled by a screw coupling method by a separate connection member (not shown).

The second pressure control unit 540 is installed on the ground, and supplies and discharges a predetermined hydraulic pressure through the second pressure pipe 530 while the upper end of the second pressure pipe 530 is connected.

Here, the second pressure adjusting unit 540 may use a device such as a compressor.

That is, when water pressure is supplied from the second pressure control unit 540 to the second pressure tube 530, the second expansion tube 520 connected to the second pressure tube 530 expands by water pressure.

In addition, the aforementioned first expansion tube 420 and the second expansion tube 520 may be installed in a cylindrical shape on the outer surface of the first frame 410 and the second frame 510.

That is, the side of the first expansion tube 420 and the second expansion tube 520 is in close contact with the wall surface of the well 10 when the expansion.

On the other hand, the first packer 400 and the second packer 500 may be coupled in a plurality in the vertical direction of the strainer 200 to close each layer of the well 10 in multiple stages.

In addition, the water extraction unit 300 described above may be provided in plural to pump the groundwater at the upper or lower portions of the first packer 400 and the second packer 500.

In addition, the water collection device of the present invention may further include a measuring unit (not shown) for measuring the acidity (PH), electrical conductivity (EC) and the water level of the groundwater.

The measurement unit, a cable (not shown) inserted through the hollow 220 of the strainer 200, and is installed on the lower end of the cable acidity of the ground water in the upper and lower portions of the first packer 400 and the second packer 500 (PH), electrical conductivity (EC) and a measuring sensor (not shown) for detecting the water level may be provided.

In addition, the above-described water extraction unit 300 is located in the upper or lower portions of the first packer 400 and the second packer 500, respectively, to pump groundwater present in each layer of the well 10, respectively. Many can be used.

The multi-stage water collection device described above can be demolished after construction when the ground water is to be collected. However, the multi-stage water collecting device is intended to discharge ground water at a necessary time in a state in which it is installed semi-permanently in the well.

As a result, the present invention by using the first packer 400 and the second packer 500, which expands during the hydraulic pressure supply, the groundwater existing at different heights in a state of partitioning each layer of the wells, or withdrawal and selectively It can be measured.

In addition, since the strength is weak, it can be used in the well (10) which may be easily collapsed, so the use range is wide.

In addition, since the groundwater present in each layer of the well 10 is not mixed with each other, it is possible to secure the accuracy and ease of groundwater discharge and measurement.

Although specific embodiments of the water collecting device of the present invention have been described so far, it is obvious that various embodiments can be modified without departing from the scope of the present invention.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined by the claims below and equivalents thereof.

In other words, the foregoing embodiments are to be understood in all respects as illustrative and not restrictive, the scope of the invention being indicated by the following claims rather than the detailed description, and the meaning and scope of the claims and All changes or modifications derived from the equivalent concept should be interpreted as being included in the scope of the present invention.

10: Well 11: The Smasher
100: casing 200: strainer
210: inflow hole 300: water outlet
310: outlet pipe 320: submersible pump
400: first packer 410: first frame
411: through hole 420: first expansion tube
430: first pressure pipe 440: first pressure adjusting unit
500: second packer 510: second frame
511: coupling hole 520: second expansion tube
530: second pressure pipe 540: second pressure control unit

Claims (5)

A hollow casing inserted into a well formed in the ground, a hollow strainer inserted into a hollow of the casing, and having a plurality of inflow holes formed along a longitudinal direction, and a discharge pipe inserted into the hollow of the strainer A water outlet portion for pumping groundwater to the ground, and coupled to a lengthwise direction of the strainer, and a through hole is formed to allow the groundwater to be discharged through the water outlet portion, and is expanded by water pressure supplied from the outside to multistage each layer of the well. And a second packer closing the first packer, and a second packer positioned in the through hole of the first packer in a state coupled to the water outlet, and expanding by closing a water supply from the outside to close the through hole. ,
The first packer is coupled to the length direction of the strainer, the first frame is vertically formed with the through hole, and is installed on the outer surface of the first frame, and is expanded to the side when the hydraulic pressure supply to the wall surface of the well A first pressure tube connected to the first expansion tube, the first pressure tube connected to the first expansion tube, and configured to transfer the water pressure supplied from the outside to the first expansion tube,
The second packer, the second frame is formed in the vertical coupling hole to be coupled to the longitudinal direction of the water discharge pipe, and is installed on the outer surface of the second frame, the side when expanding the hydraulic pressure supply to the wall surface of the through hole A second expansion tube in close contact with the second expansion tube for vertically dividing the through hole of the first frame, and a second pressure tube connected to the second expansion tube and transferring a hydraulic pressure supplied from the outside to the second expansion tube; Watering device, characterized in that.
The method of claim 1,
The water extraction unit,
It is installed at the lower end of the discharge pipe, the water collecting device, characterized in that the water pump for pumping the groundwater in the upper and lower portion of the second packer.
delete The method of claim 1,
The first expansion tube and the second expansion tube,
Cylindrical shape is installed on the outer surface of the first frame and the second frame, the side of the water collecting device, characterized in that the side is in close contact with the wall of the well as a whole.
The method of claim 1,
The first packer and the second packer,
A plurality of coupled along the vertical length of the strainer, closing each layer of the well in multiple stages,
The water extraction unit,
Collecting device, characterized in that a plurality is provided for pumping groundwater in the upper or lower portion of the first packer and the second packer.

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