KR20160000599A - Groundwater sampling device for each of a depth of the hole - Google Patents

Abstract

The present invention relates to an underground water sampling device for each depth of a drilling hole (1000), comprising: a high pressure tube (100); a sample tube (200); a plurality of inlet valves (300); and a moving means (500). The purpose of the present invention is to provide the underground water sampling device for each depth of a drilling hole sampling underground water for each depth of a drilling hole at once.

Description

[0001] The present invention relates to a groundwater sampling device,

BACKGROUND OF THE INVENTION Field of the Invention The present invention relates to a groundwater sampling apparatus for each depth of borehole.

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, groundwater samples are required to be collected at depth because of differences in characteristics depending on the depth of the borehole.

In particular, when the groundwater is the same, there is a large change in the depth characteristics of each depth even within a depth of several tens of centimeters. Therefore, it is necessary to collect a plurality of groundwater samples several times to analyze the difference in depth characteristics of groundwater.

In the conventional groundwater collecting apparatus, a borehole having a predetermined diameter and a depth is formed in a rock bed at a position to be sampled, a water intake pipe is inserted into the borehole, and a groundwater sample is collected from a desired depth region in the borehole through a water intake pipe.

In this case, the conventional groundwater collecting apparatus is provided with a pump for pumping groundwater through a water intake pipe.

However, in the conventional groundwater collecting apparatus, a large amount of groundwater samples can be sampled at a time using a pumping pump, but groundwater can not be collected at a depth of the borehole.

In order to solve this problem, the applicant of the present invention has proposed a groundwater collecting apparatus for inserting groundwater into a borehole of Korean Patent Publication No. 2011-0024521, comprising: a shell forming part of a water intake pipe; An operation unit which is formed to be movable in the vertical direction within the shell and which allows the groundwater in the borehole to flow into the water intake pipe by up-and-down movement; A drive unit provided at the upper and lower parts of the operation unit to move the operation unit up and down; And an opening and closing unit provided in the operation unit and opening and closing the flow path of the operation unit according to the up and down movement of the operation unit.

However, in the conventional electric groundwater collecting apparatus, a sample bottle is inserted at a specific depth of the borehole, and then the sample bottle is inserted again at a specific depth of the borehole to collect the groundwater at various borehole depths There is a problem that the efficiency is lowered.

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

Korea Patent Publication No. 2011-0024521 (Mar. 2011)

It is an object of the present invention to provide a groundwater sample collecting apparatus with a borehole depth capable of collecting groundwater at a borehole depth at a time.

A groundwater sampling apparatus (1000) according to the present invention includes a high-pressure tube (100) having an upper end connected to a fluid compressor; A sample tube 200 coupled to a lower end of the high pressure tube 100 and inserted into a specific position of the borehole and separated from the plurality of partitions 210 having an interior vertically arranged to form a plurality of sample chambers 220; ); A plurality of inlet valves 300 connected to upper ends of the peripheral surfaces of the plurality of sample chambers 220; And the plurality of inflow valves 300 are respectively closed and then moved downward by the high fluid pressure of the fluid compressor to open the plurality of inflow valves 300 to open the plurality of sample chambers 220, And moving means (500) for allowing the water to flow in every depth.

The moving means 500 includes a pressure piston 510 disposed inside the high-pressure tube 100 and moved downward by a high fluid pressure of the fluid compressor, and a plurality of sample chambers 220 vertically A connection rod 520 penetrating through the center portion and being disposed at an inner upper end of the sample chamber 220 to close the inlet valve 300, And a plurality of interlocking pistons (530) interlocking with the pressure piston (510) and opening the inlet valve (300).

In addition, the groundwater sampling apparatus 1000 according to the borehole depth includes a plurality of first outflow pipes 410 connected to the lower end of the peripheral surface of the plurality of sample chambers 220; A second outlet pipe 420 connected to the lower end of the circumferential surface of the high-pressure tube 100; And a plurality of take-out valves 600 connected to upper ends of the circumferential surfaces of the plurality of sample chambers 220. When the pressure piston 510 is moved downward, And a pushing portion 525 protruding to the lower side of the sample tube 200 is formed.

The inlet valve 300 includes a cover 310 that is connected to the upper end of the circumference of the sample chamber 220 and an outlet port 310 that is arranged in the direction opposite to the inside of the sample chamber 220 from the inner surface of the cover 310. A spring 340 installed between the first and second stopping protrusions 320 and 330 and the first and second stopping protrusions 320 and 330, And a cover 350 installed between the springs 340 and 320.

The moving means 500 includes a first O-ring 540 installed between the circumferential surface of the pressure piston 510 and the inner surface of the high-pressure tube 100, a first O-ring 540 disposed between the circumferential surface of the peristaltic piston 530, A second O-ring 550 installed between the inner surface of the chamber 220 and a third O-ring 560 installed between the inner circumferential surface of the partition 210 and the outer circumferential surface of the connecting rod 520. [ do.

The groundwater sampling apparatus 1000 according to the present invention further includes an induction pipe 700 connecting the plurality of first outflow pipes 410 and the second outflow pipe 420 to each other .

In accordance with the present invention, the groundwater sample collecting apparatus according to the present invention has a plurality of inlet valves connected to a plurality of sample chambers separated by a plurality of partition walls vertically arranged in the sample tube, The advantage of this method is that groundwater can be collected at a single depth of borehole.

Particularly, according to the present invention, the groundwater sampling apparatus according to the depth of borehole has an advantage that the moving means simultaneously opens and closes a plurality of inlet valves simultaneously, and groundwater can be sampled at the depth of borehole at the same time.

1 is a perspective view of a groundwater sampling apparatus according to the present invention;
2 is a front view of a groundwater sampling system according to the present invention;
3 is a front view of the moving means according to the present invention;
4 is a cross-sectional view of a groundwater sampling device according to the present invention
5 to 6 are diagrams showing the operation of the groundwater sampling apparatus according to the present invention
7 is a cross-sectional view of an inflow valve 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.

FIG. 1 is a perspective view of a groundwater sampling apparatus according to the present invention, FIG. 2 is a front view of a groundwater sampling apparatus according to the present invention, FIG. 3 is a front view of a moving means according to the present invention, FIGS. 5 to 6 are operation diagrams of a groundwater sampling apparatus according to the present invention. FIG. 5 is a sectional view of a groundwater sampling apparatus according to the present invention.

1 to 4, a groundwater sampling system 1000 according to the present invention includes a high pressure tube 100, a sample tube 200, a plurality of inlet valves 300, a plurality of first An outflow pipe 410, a second outflow pipe 420, and a moving means 500.

The high-pressure tube 100 may be formed in a cylindrical shape, and the upper end thereof is connected to the high-pressure hose 10 of a fluid compressor (not shown).

The sample tube 200 is coupled to the lower end of the high pressure tube 100 and is inserted into a specific position of the borehole together with the high pressure tube 100. The sample tube 200 is separated by a plurality of partition walls 210, A sample chamber 220 is formed.

Here, a borehole refers to a hole drilled at a predetermined depth on the ground for surveying groundwater.

The plurality of sample chambers 220 are connected to the upper end of the circumferential surface of the plurality of sample chambers 220 and the inlet valve 300 Way valve capable of only the inflow of groundwater into the plurality of sample chambers 200.

The plurality of first outflow tubes 410 are connected to the lower end of the circumferential surface of the plurality of sample chambers 220 respectively and the second outflow tubes 420 are connected to the lower end of the high pressure tube 100.

The moving means 500 is configured to open and close the inlet valve 300, the first outlet pipe 410 and the second outlet pipe 420 and includes a pressure piston 510, a connecting rod 520 and an interlocking piston 530, .

The pressure piston 510 is disposed in the interior of the high pressure tube 100 and the peripheral surface thereof is in close contact with the inner surface of the high pressure tube 100 and is moved downward by the high fluid pressure of the fluid compressor, And flows out to the second outflow pipe 420. [0051] At this time, the fluid inside the high-pressure tube 100 may be air.

The connecting rod 520 penetrates the plurality of sample chambers 220 in the up and down direction and is coupled to the pressure piston.

The plurality of interlocking pistons 530 are arranged such that the circumferential surface thereof is in close contact with the inner surface of the sample chamber and the connecting rod 520 is penetrated through the center portion and disposed at the inner upper end of the sample chamber 220 to close the inlet valve 300, The fluid in the sample chamber 220 flows out to the first outflow pipe 410 while the fluid is interlocked with the piston 510 and the inflow valve 300 is opened to discharge the groundwater into the plurality of sample chambers 220, Let it flow by depth. At this time, the fluid inside the sample chamber 220 may be air.

The operation principle in which the groundwater is introduced into the sample chamber 220 by the depth of the borehole will be described in more detail.

As shown in FIG. 4, the fluid compressor applies a high fluid pressure to the inside of the high-pressure tube 100 with the pressure piston 510 disposed at the inner upper end of the high-pressure tube 100.

At this time, the plurality of interlocking pistons 530 are respectively disposed at the inner upper ends of the plurality of sample chambers 220 to close the inlet valve 300.

5, as the pressure piston 510 moves downward due to the high fluid pressure of the high-pressure tube 100, the plurality of interlocking pistons 530 are moved downwardly to interlock the plurality of inflow valves 300 The groundwater is introduced into the plurality of sample chambers 220 through the plurality of inlet valves 300 at the depth of the borehole.

At this time, as the pressure piston 510 moves downward, the fluid inside the high-pressure tube 100 flows out to the outside through the second outlet pipe 420.

Also, as the interlocking piston 530 is moved downwardly, the fluid in the sample chamber 220 flows out through the first outflow pipe 410.

6, the pressure piston 510 is disposed at the inner lower end of the high-pressure tube 100 to close the second outlet pipe 420, and the interlocking piston 530 is connected to the inner bottom of the sample chamber 220 And the first outflow pipe 410 is closed. Groundwater is introduced into the plurality of sample chambers 220 by the depth of the borehole.

Thereafter, the groundwater sampling apparatus 1000 according to the present invention can be raised to analyze the characteristics of the groundwater contained in the plurality of sample chambers 220 by the depth of the borehole.

That is, when the interlocking piston 530 closes a plurality of inflow valves 300 and is interlocked with the pressure piston 510 to open a plurality of inflow valves 300, And the groundwater is introduced into the plurality of sample chambers 220 again.

Accordingly, the groundwater sampling apparatus 1000 according to the present invention includes a plurality of sample chambers 220 separated by a plurality of barrier ribs 210 arranged in a vertical direction in a sample tube 200, The groundwater can be simultaneously introduced through the plurality of inlet valves 300 connected to each other, so that the groundwater can be collected at a time according to the depth of the borehole.

Particularly, in the groundwater sampling apparatus 1000 according to the present invention, the moving means 500 simultaneously opens and closes a plurality of the inlet valves 300, and the groundwater can be sampled at the depth of the borehole at the same time.

The groundwater sampling apparatus 1000 according to the present invention further includes a blow-out valve 600. When the pressure piston 510 is moved downward and the connecting rod 520 is moved to the lower side of the sample tube 200 And the pushing portion 525 is formed.

The take-out valve 600 is connected to the upper end of the circumferential surface of the sample chamber 220, and is always closed.

The extraction valve 600 and the pushing portion 525 are used in a state in which groundwater is introduced into the plurality of sample chambers 220 at the depths of the borehole, 525 may be pushed upwards and the groundwater introduced into the plurality of sample chambers 220 through the extraction valve 600 may be discharged to the outside by the depth of the borehole.

That is, the apparatus 1000 for collecting groundwater depths according to the present invention has a structure in which a plurality of sample chambers 220, which have been introduced into a plurality of sample chambers 220 using the extraction valve 600 and the pushing portions 525 of the connecting rod 520, The groundwater can be easily discharged to the outside.

7 is a cross-sectional view of an inflow valve according to the present invention.

7, the inlet valve 300 may include a cover 310, a first latching jaw 320, a second latching jaw 330, a spring 340, a lid 350, have.

The cover 310 may be formed in a cylindrical shape and penetrate the upper end of the circumferential surface of the sample chamber 220.

The first stopping jaw 320 and the second stopping jaw 330 are arranged in the direction opposite to the inside of the sample chamber 220 on the inner surface of the cover 310.

The spring 340 is installed between the first latching jaw 320 and the second latching jaw 330.

The lid 350 is disposed between the first latching jaw 320 and the spring 340 to close the space formed inside the first latching jaw 320 by the elasticity of the spring 340, When the interlocking piston 530 opens the inlet valve 300, it is opened by the water pressure of groundwater.

A portion of the lid 350 which is located inside the first latching jaw 320 is formed in a tapered shape that becomes wider as the latching jaw 320 moves away from the first latching jaw 320, 320 can be closed more tightly.

Accordingly, the inlet valve 300 closes the space formed inside the first stopping protrusion 320 by the elasticity of the spring 340, so that the interlocking piston 530 flows in at a specific position of the borehole When the valve 300 is opened, it is opened by the water pressure of the groundwater so that foreign matter flows into the interior of the inlet valve 300 while the inlet valve 300 is inserted to a specific depth of the borehole, Can be prevented from deteriorating.

The moving means 500 further includes a first O-ring 540, a second O-ring 550, and a third O-ring 560.

The first O-ring 540 and the second O-ring 550 are disposed between the circumferential surface of the pressure piston 510 and the inner surface of the high-pressure tube 100 and between the circumferential surface of the interlocking piston 530 and the inner surface of the sample chamber 220 Each can be installed to enhance confidentiality.

The third O-ring 560 is installed between the inner circumferential surface of the partition 210 and the outer circumferential surface of the connecting rod 520 to enhance airtightness.

Also, the groundwater sampling apparatus 1000 according to the present invention may further include an induction pipe 700.

The induction pipe 700 connects the plurality of first outflow pipe 410 and the second outflow pipe 420 to each other and flows out through the plurality of first outflow pipes 410 and the second outflow pipe 420 It is possible to prevent the fluid from entering the ground water and deteriorating the characteristics of the ground water.

In addition, the induction pipe 700 may be formed on the upper side of the borehole, that is, a length protruding to the ground.

This is to prevent the fluid flowing out to the outside through the first outflow pipe 410 and the second outflow pipe 420 into the groundwater.

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.

1000: Groundwater sampling device according to the borehole depth of the present invention
10: High pressure hose
100: High pressure tube
200: sample tube
210:
220: sample chamber
300: inflow valve
310: cover
320: first stopping jaw
330: second stopping jaw
340: spring
350: cover
410: first outflow pipe
420: second outflow pipe
500: Moving means
510: pressure piston
520: connecting rod
525: pushing region
530: Peristaltic piston
540: First O-ring
550: Second O-ring
560: Third O-ring
600: Exhaust valve
700: Induction tube

Claims (6)

A high pressure tube (100) having an upper end connected to a fluid compressor;
A sample tube 200 coupled to a lower end of the high pressure tube 100 and inserted into a specific position of the borehole and separated from the plurality of partitions 210 having an interior vertically arranged to form a plurality of sample chambers 220; );
A plurality of inlet valves 300 connected to upper ends of the peripheral surfaces of the plurality of sample chambers 220; And
The plurality of inlet valves 300 are respectively closed and then moved downward by the high fluid pressure of the fluid compressor to open the plurality of inlet valves 300 so that the groundwater is supplied to the plurality of sample chambers 220, And a moving means (500) for allowing the groundwater to be introduced into the borehole.
The apparatus of claim 1, wherein the moving means (500)
A pressure piston 510 disposed inside the high-pressure tube 100 and moved downward by a high fluid pressure of the fluid compressor; and a pressure piston 510 penetrating the plurality of sample chambers 220 in the up- The connecting rod 520 is coupled to the center of the sample chamber 220 and is disposed at the upper end of the sample chamber 220 to close the inlet valve 300. The pressure piston 510, And a plurality of interlocking pistons (530) for opening the inlet valve (300) while being interlocked with each other.
The groundwater sampling system according to claim 2, wherein the borehole depth sampling device (1000)
A plurality of first outflow tubes 410 connected to the lower end of the circumferential surface of the plurality of sample chambers 220;
A second outlet pipe 420 connected to the lower end of the circumferential surface of the high-pressure tube 100; And
And a plurality of take-out valves (600) connected to upper end surfaces of the plurality of sample chambers (220), respectively,
The lower end of the connecting rod 520 is protruded to the lower side of the sample tube 200 while the pressure piston 510 is moved downward to form a pushing part 525. [ 1000).
2. The apparatus of claim 1, wherein the inlet valve (300)
A cover 310 connected to the upper end of the circumferential surface of the sample chamber 220,
A first latching jaw 320 and a second latching jaw 330 arranged in the direction opposite to the inside of the sample chamber 220 on the inner surface of the cover 310,
A spring 340 installed between the first latching jaw 320 and the second latching jaw 330,
And a lid (350) installed between the first latching jaw (320) and the spring (340).
3. The apparatus according to claim 2, wherein the moving means (500)
A first O-ring 540 installed between the circumferential surface of the pressure piston 510 and the inner surface of the high-pressure tube 100,
A second O-ring 550 installed between the circumferential surface of the peristaltic piston 530 and the inner surface of the sample chamber 220,
Further comprising a third O-ring (560) installed between the inner circumferential surface of the partition wall (210) and the outer circumferential surface of the connecting rod (520).
4. The groundwater sampling system (1000) according to claim 3, wherein the borehole depth-
Further comprising an induction pipe (700) connecting the plurality of first outflow pipes (410) and the second outflow pipe (420) to each other.

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