KR101606685B1 - Groundwater sampling device - Google Patents

Abstract

The present invention relates to a sampling chamber (100); A pressure control check valve (200) communicating with the lower end of the sampling chamber (100) and automatically opened by a groundwater hydraulic pressure at a specific location of a borehole to set groundwater into the sampling chamber (100); And a poppet valve (300) communicating with the upper end of the sampling chamber (100) and floating inside the float (330) installed by the water surface of the groundwater filled in the sampling chamber (100) And a groundwater collecting device (1000).

Description

Groundwater sampling device

BACKGROUND OF THE INVENTION Field of the Invention The present invention relates to a groundwater collecting apparatus for collecting groundwater, which is a high-pressure fluid located at a specific depth of a borehole, intact.

In general, on-site hydraulic tests and geochemical analyzes are conducted to investigate the hydraulic characteristics of the mediums of interest in crystalline rocks in the boreholes. Groundwater sampling equipment for groundwater sampling is being used for these tests and analyzes.

In addition, since groundwater varies in characteristics depending on the depth of the borehole, it is necessary to collect the groundwater sample at a specific depth of the borehole.

In the conventional groundwater sampling system, a borehole of predetermined diameter and depth is formed in a rock bed, a water intake pipe is inserted at a specific depth of the borehole, and a groundwater sample is collected using a pumping water pump.

However, it was possible to collect a large amount of groundwater samples at a time by using the conventional groundwater collecting device pumping pump. However, since the power source and the additional equipment and manpower for operating the pumping pump are required, .

In addition, the conventional groundwater collecting apparatus has a problem in that since the hydraulic pressure is reduced in the course of groundwater being pumped from the inside of the borehole to the ground, the dissolved gas contained in the groundwater is discharged to the outside and the groundwater can not be collected as it is.

Korean Patent Publication No. 2004-0046802 discloses an air compressor for generating a constant air pressure; A tube installed to transmit air pressure at a position spaced apart from the air compressor by a predetermined distance; And a sample collecting port connected to upper and lower check ball valves respectively connected to the upper portion of the normal sample bottle and the upper and lower ends of the tube to block the flow of fluid in one direction, We have presented a groundwater sampling system at a certain depth,

However, in the prior art, the air supplied from the air compressor is interposed between the water surface of the groundwater accommodated in the sample bottle and the upper check ball valve, so that the air supplied from the air compressor and the ground water received in the sample bottle are mixed with each other, There is a problem that can not be done.

In addition, the conventional art requires a power source for operating the air compressor, so that it takes a lot of groundwater collection cost and can not be used in an outdoor environment where power supply is difficult.

Therefore, it is necessary to develop various groundwater collecting apparatuses to solve the above-mentioned problems.

Korean Patent Publication No. 2004-0046802 (June 2004)

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is to provide a groundwater collecting apparatus capable of collecting and recovering groundwater as it is.

Another object of the present invention is to provide a groundwater collecting apparatus that can minimize the collection cost of ground water and can be used in an outdoor environment where power supply is difficult.

A groundwater collecting apparatus (1000) according to the present invention includes a sampling chamber (100); A pressure control check valve (200) communicating with the lower end of the sampling chamber (100) and automatically opened by a groundwater hydraulic pressure at a specific location of a borehole to set groundwater into the sampling chamber (100); And a poppet valve (300) communicating with the upper end of the sampling chamber (100) and floating inside the float (330) installed by the water surface of the groundwater filled in the sampling chamber (100) .

The pressure control check valve 200 has an upper end connected to the lower end of the sampling chamber 100 and a lower end connected to the lower end of the pressure control check valve 200 via a first hooking jaw 211, a second hooking jaw 212, A pushing bar 220 which is placed on the upper end of the first stopping hook 211 and closes the inside of the check stopping bar 220; A first spring 230 installed between the two latching jaws 212 to compress the pushing bar 220 by the groundwater hydraulic pressure at a specific location of the borehole transmitted through the pushing bar 220, A moving bar 240 installed between the first spring 230 and the third locking step 213 and a second spring 250 installed between the moving bar 240 and the third locking step 213, And further comprising:

The check cover 210 is formed with an inflow hole 215 for introducing groundwater between the second stopping protrusion 212 and the third stopping protrusion 213, And closes the hole 215, and is pushed upward by the upward movement of the pushing bar 220 to open the inflow hole 215.

The movement bar 240 is formed on an outer circumferential surface and has a passage hole 241 communicating with the inlet hole 215 when the movement bar 240 is pushed upward and a passage hole 241 communicating with the passage hole 241 and the third And a hollow hole 242 communicating with the inside of the latching jaw 213 is further formed.

The pressure control check valve 200 includes a first magnet 260 coupled to an upper end of the movement bar 240 and a second magnet 260 coupled to a lower end of the third engagement step 213, And a second magnet 270 attached to the first magnet 260 when the first magnet 260 is pushed upward.

The pressure control check valve 200 is mounted on the upper end of the third latching jaw 213 and is connected to the inside of the third latching jaw 213 by a load of groundwater filled in the sampling chamber 100. [ And a check cap 280 that closes the check valve 280.

The poppet valve 300 includes a poppet cover 310 communicating with an upper end of the sampling chamber 100, a protruding protrusion 320 formed on an inner circumferential surface of the poppet cover 310, The float 330 is installed inside the sampling chamber 100 and floats by the water surface of the groundwater filled in the sampling chamber 100 to close the inside of the protrusion 320.

The float 330 includes a floating member 331 which is mounted on the upper end of the protrusion 320 and floated by the surface of the groundwater and a floating member 331 which is coupled to the lower end of the floating member 331, And a stem member 332 which floats together with the protruding jaw 320 to close the lower end of the protruding jaw 320.

In addition, the poppet valve 300 has a sloped surface for narrowing the lower end inner circumferential surface of the protruding protrusion 320 and a bottleneck surface for narrowing the lower outer circumferential surface of the stem member 332 toward the upper side .

Accordingly, the groundwater collecting apparatus according to the present invention automatically receives the groundwater into the sampling chamber through the pressure control check valve that is opened only by the hydraulic pressure of the groundwater located at a specific position of the borehole, thereby collecting and recovering the groundwater There is an effect that can be.

Further, the groundwater collecting apparatus according to the present invention does not require a separate power source for opening the pressure control check valve and closing the poppet valve, thereby minimizing the collection cost of the groundwater.

1 is a schematic view of a groundwater collecting apparatus according to the present invention;
Figure 2 is a cross-sectional view of a pressure-
3 is a cross-sectional view of the poppet valve according to the present invention
FIGS. 4 to 12 are diagrams showing the operation of the groundwater collecting apparatus according to the present invention

Hereinafter, the technical idea of the present invention will be described more specifically with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are included to provide a further understanding of the technical concept of the present invention, are incorporated in and constitute a part of the specification, and are not intended to limit the scope of the present invention.

1 is a schematic view of a groundwater collecting apparatus according to the present invention.

1, the groundwater collecting apparatus 1000 according to the present invention includes a sampling chamber 100, a pressure control check valve 200, and a poppet valve 300. As shown in FIG.

The sampling chamber 100 is a tube for filling groundwater therein, and may be made of a corrosion-resistant material.

The pressure control check valve 200 is a check valve having an upper end communicated with a lower end of the sampling chamber 100 and automatically opened by a groundwater hydraulic pressure at a specific location of the borehole, As shown in FIG.

More specifically, the pressure control check valve 200 is closed at a hydraulic pressure lower than the groundwater hydraulic pressure at a specific location of the borehole, and is set to open at a hydraulic pressure equal to or higher than the groundwater hydraulic pressure at a specific location of the borehole.

When the groundwater is completely filled in the sampling chamber 100, the pressure control check valve 200 raises the sampling chamber 100 to the ground. In this process, the inside of the sampling chamber 100 The pressure regulating check valve 200 can be automatically closed because the hydraulic pressure of the ground water is greater than the hydraulic pressure or atmospheric pressure of the groundwater located outside the sampling chamber 100.

The float valve 300 communicates with the upper end of the sampling chamber 100 and floats in the float 330 installed therein by the water surface of the groundwater filled in the sampling chamber 100.

Accordingly, the groundwater collecting apparatus 1000 according to the present invention automatically receives the groundwater into the sampling chamber 100 through the pressure control check valve 200, which is opened only by the hydraulic pressure of the groundwater located at a specific position of the borehole , The groundwater can be collected and recovered as it is.

Further, the groundwater collecting apparatus 1000 according to the present invention does not require a separate power source for opening the pressure control check valve 200 and closing the poppet valve 300, thereby minimizing the collection cost of groundwater .

The groundwater collecting apparatus 1000 according to the present invention may further include a high pressure hose 10, a first stop valve 20, a second stop valve 30, and a third stop valve 40 have.

The lower end of the high pressure hose 10 communicates with the upper end of the poppet valve 300, and the upper end communicates with the air on the ground.

The first stop valve 20 is installed on the upper end of the high pressure hose and supplies the ground air into the sampling chamber 100 through the poppet valve 300 so that the difference between the air pressure on the ground and the hydraulic pressure difference So that the groundwater can be introduced into the sampling chamber 100.

The second stop valve 30 is installed and opened between the sampling chamber 100 and the poppet valve 300 and the third stop valve 40 is connected to the sampling chamber 100 and the pressure control check valve 200 And the second stop valve 30 and the third stop valve 40 are closed when the groundwater is filled in the sampling chamber 100 and the sampling chamber 100 is closed, Thereby maintaining the internal airtight state of the fuel cell stack 100.

2 is a cross-sectional view of a pressure-controlled check valve according to the present invention.

2, the pressure control check valve 200 includes a check cover 210, a pushing bar 220, a first spring 230, a moving bar 240, and a second spring 250 And the like.

The check cover 210 is a body of the pressure control check valve 200. The inside of the check cover 210 is hollow in the vertical direction and the upper end communicates with the lower end of the sampling chamber 100. In the inner circumferential surface, A second stopping jaw 212 and a third stopping jaw 213 are arranged in the order of the second stopping stopper 212 and the third stopping stop 213, An inflow hole 215 is formed.

Referring to FIG. 2, the first latching jaw 211 may be formed at the lower end of the check cover 210, but the present invention is not limited thereto.

The pushing bar 220 is placed on the upper end of the first latching jaw 211 to close the inside of the first latching jaw 211. The outer surface of the pushing bar 220 contacts the inner circumferential surface of the check cover 210, Direction.

Also, the pushing bar 220 receives groundwater pressure at a specific location of the borehole.

The first spring 230 is installed between the pushing bar 220 and the second engaging jaw 212 to urge the pushing bar 220 downward, And is compressed by the groundwater hydraulic pressure at a specific position so that the pushing bar 220 moves upward.

The moving bar 240 is installed between the first spring 230 and the third engaging jaw 213 to close the inlet hole 215 and is pushed upward by the upward movement of the pushing bar 220 The inlet hole 215 is opened.

At this time, groundwater located outside flows into the inflow hole 215.

The second spring 250 is installed between the moving bar 240 and the third engaging jaw 213 so as to push the moving bar 240 downward so that the moving bar 240 is moved to the pushing bar 220, So that it can be pushed upward only by the rise of the pressure.

At this time, the first spring 230 adjusts the elastic force that pushes the pushing bar 220 downward, thereby adjusting the upward hydraulic pressure of the pushing bar 220 so that the pushing bar 220 is moved to a specific position It is possible to set the oil pressure to be raised only by the oil pressure of the oil pan.

The movement bar 240 includes a passage hole 241 formed on the outer circumferential surface of the inflow hole 215 and communicating with the inflow hole 215 when the movement bar 240 is pushed upward, And a hollow hole 242 communicating with the passage hole 241 and the inside of the third stopping protrusion 213 may be further formed.

That is, while the moving bar 240 is pushed upward, the inflow hole 215, the passage hole 241 and the hollow hole 242 are communicated with each other, and the inflow hole 215, the passage hole 241, Groundwater flows into the third latching jaw 213 through the first latching jaw 242 and groundwater flowing into the third latching jaw 213 flows into the sampling chamber 100 again.

The pressure control check valve 200 may further include a first magnet 260 and a second magnet 270.

The first magnet 260 is coupled to the upper end of the moving bar 240.

The second magnet 270 is coupled to the lower end of the third stopping protrusion 213 and is attached to the first magnet 260 when the movable bar 240 is pushed upward, .

That is, the first magnet 260 and the second magnet 270 maintain the state where the moving bar 240 is pushed upward, thereby maintaining the open state of the inlet hole 215.

In addition, the pressure control check valve 200 may further include a check cap 280.

The check plug 280 is formed in a T shape and is mounted on the upper end of the third stopping protrusion 213 and is raised by the flow of groundwater flowing into the third stopping protrusion 213, When the groundwater is filled in the sampling chamber 100 and the flow of the groundwater is stopped, the inside of the third catching jaw 213 is closed again by the self-load of the groundwater.

In addition, the pressure control check valve 200 may be provided with an O-ring 290 for airtightness between the check stopper 280 and the upper end of the third stopping protrusion 213.

3 is a sectional view of a poppet valve according to the present invention.

3, the poppet valve 300 according to the present invention may include a poppet cover 310, a protrusion 320, and a float 330.

The poppet cover 310 is communicated with the upper end of the sampling chamber 100, and the interior thereof is hollowed in the vertical direction.

The projecting step 320 is formed on the inner peripheral surface of the poppet cover 310.

The float 330 is installed inside the protruding jaw 320 and floats by the water surface of the groundwater filled in the sampling chamber 100 to close the protruding jaw 320.

At this time, the float 330 may further include a floating member 331 and a stem member 332.

The floating member 331 may be formed in a spherical shape and is mounted on the upper end of the protruding protrusion 320 to float by the water surface of the groundwater.

The stem member 332 is coupled to the lower end of the floating member 331 and floats together with the floating member 331 to close the lower end of the protrusion 320.

At this time, the poppet valve 300 may be formed with a sloped surface inclined at a lower inner circumferential surface of the protruding protrusion 320, and a bottleneck surface inclined by a lower outer circumferential surface of the stem member 332 may be formed.

The inclined surface and the bottleneck surface serve to enhance airtightness between the protruding protrusion 320 and the stem member 332.

Hereinafter, an operation process of the groundwater collecting apparatus 1000 according to the present invention will be described.

4 to 12 are operation diagrams of a groundwater collecting apparatus according to the present invention. 6 is an enlarged view of the pressure control check valve 200 shown in FIG. 5, FIG. 8 is an enlarged view of the pressure control check valve 200 shown in FIG. 7, and FIG. FIG. 12 is an enlarged view of the pressure control check valve 200 and the poppet valve 300 shown in FIG. 11; FIG.

As shown in FIG. 4, the groundwater collecting apparatus 1000 according to the present invention is prepared.

5 to 6, the groundwater collecting apparatus 1000 according to the present invention is injected at a specific position of the borehole (a specific depth at which the groundwater of the borehole is to be collected) The bar 220 is lifted and the first spring 230 is compressed.

7 to 8, the movable bar 240 is pushed upward by the upward movement of the pushing bar 220 so that the inflow hole 215, the passage hole 241, the hollow hole 242, And the groundwater flows into the third receiving jaw 213 through the inlet hole 215, the passage hole 241 and the hollow hole 242, The groundwater flowing into the third latching jaw 213 flows into the sampling chamber 100 by raising the check plug 280 by the flow of the groundwater.

At this time, the first magnet 260 and the second magnet 270 are pushed to the upper side of the moving bar 240 and attached to each other to prevent the moving bar 240 from moving downward, 215) are kept open.

9 to 10, the groundwater introduced into the sampling chamber 100 flows into the inside of the poppet valve 300, and the floating member 331 of the float 330 receives the groundwater It floats by the surface of the water.

11 to 12, the stem member 332 is suspended with the floating member 331 to close the lower end of the protrusion 320 so that the upper end of the sampling chamber 100 is closed do,

Also, after the groundwater is filled in the sampling chamber 100, the check plug 280 is pressed downward by the self-load of the groundwater to close the inside of the third catching jaw 213.

Thereafter, the sampling chamber 100 is pulled up to the ground so that the hydraulic pressure of the groundwater filled in the sampling chamber 100 is higher than the atmospheric pressure of the outside, so that the check plug 280 and the stem member 332 So that the inside of the sampling chamber 100 is sealed.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

10: High pressure hose
20: First stop valve
30: Second stop valve
40: Third stop valve
1000: groundwater collecting device according to the present invention
100: sampling chamber
200: Pressure control check valve
210: check cover
211: first stopping jaw
212: second stopping jaw
213: Third stop jaw
215: inlet hole
220: Pushing bar
230: first spring
240: Moving bar
241: passage hole
242: hollow hole
250: second spring
260: first magnet
270: Second magnet
280: Check plug
290: O ring
300: Poppet valve
310: Poppet cover
320: protruding chin
330: Float
331: floating member
332: absence of stem

Claims (9)

A sampling chamber (100);
A pressure control check valve (200) communicating with the lower end of the sampling chamber (100) and automatically opened by a groundwater hydraulic pressure at a specific location of a borehole to set groundwater into the sampling chamber (100); And
And a float valve (300) communicating with the upper end of the sampling chamber (100) and floating inside the float (330) installed by the water surface of groundwater filled in the sampling chamber (100)
The pressure control check valve 200 has an upper end communicating with the lower end of the sampling chamber 100 and has a first hooking jaw 211, a second hooking jaw 212, and a third hooking jaw A pushing bar 220 which is placed on the upper end of the first stopping hook 211 and closes the inside of the check stopping bar 211; A first spring (230) installed between the jaws (212) and compressed by groundwater hydraulic pressure at a specific location of the borehole transmitted through the pushing bar (220) to raise the pushing bar (220) A moving bar 240 installed between the spring 230 and the third locking protrusion 213 and a second spring 250 installed between the moving bar 240 and the third locking protrusion 213 (1000). ≪ / RTI >
delete The method according to claim 1,
The check cover 210 is formed with an inflow hole 215 for introducing groundwater between the second stopping protrusion 212 and the third stopping protrusion 213,
Wherein the moving bar (240) closes the inlet hole (215) and is pushed upward by the upward movement of the pushing bar (220) to open the inlet hole (215) .
4. The apparatus of claim 3, wherein the movement bar (240)
A passage hole 241 formed in the outer circumferential surface and communicating with the inlet hole 215 when the movable bar 240 is pushed upward and a communication hole 241 communicating with the inside of the passage hole 241 and the third engagement protrusion 213 And a hollow hole (242) is formed in the groundwater collecting apparatus (1000).
5. The apparatus of claim 4, wherein the pressure control check valve (200)
A first magnet 260 coupled to an upper end of the moving bar 240,
Further comprising a second magnet (270) coupled to a lower end of the third locking step (213) and attached to the first magnet (260) when the movement bar (240) is pushed upward, Device (1000).
2. The apparatus of claim 1, wherein the pressure control check valve (200)
And a check stopper 280 mounted on the upper end of the third stopping stopper 213 to close the inside of the third stopping stopper 213 by a load of groundwater filled in the sampling chamber 100 (1000). ≪ / RTI >
[2] The apparatus of claim 1, wherein the poppet valve (300)
A poppet cover 310 communicating with an upper end of the sampling chamber 100,
A protruding protrusion 320 formed on an inner circumferential surface of the poppet cover 310,
And a float 330 installed in the protruding jaw 320 and floated by the water surface of the groundwater filled in the sampling chamber 100 to close the protruding jaw 320. [ Groundwater collecting device (1000).
8. The apparatus of claim 7, wherein the float (330)
A floating member 331 mounted on the upper end of the protruding jaw 320 and suspended by the water surface of the groundwater,
Further comprising a stem member (332) coupled to a lower end of the floating member (331) and suspended with the floating member (331) to close the lower end of the protrusion (320) 1000).
9. The system of claim 8, wherein the poppet valve (300)
An inclined surface is formed in which the lower end inner peripheral surface of the protruding protrusion 320 becomes narrower toward the upper side,
Wherein a bottleneck surface is formed at the lower end of the stem member (332) so as to become narrower toward the upper side.

Images