KR102619463B1 - Sampling device for underground soil and fluid oil - Google Patents

Abstract

The present invention relates to an underground soil and fluid oil sampling device, and in detail, a tubular perforated pipe 100, a cutting shoe 150, and a perforated module (M1) for cannulating the perforated pipe 100 to a target depth predetermined by the user. ); and a soil collection module (M2) is inserted at the rear end of the perforated pipe 100 to collect a soil sample. The soil sample from deeper underground can also be collected by extending the length using an extension rod. Additionally, after collecting a soil sample, oil sampling from the soil can be performed by inserting an oil collection module (M3) that can collect oil samples. Therefore, as a single device, both soil samples and oil samples can be collected through one construction, which can significantly shorten the sampling time compared to when sampling using multiple devices, and because sampling is performed at the same location, The reliability of sampling analysis results is excellent. In addition, the components required for soil sampling and oil sampling are shared, but because the configuration is compact, the manufacturing cost of the sampler device can be reduced.

Description

Sampling device for underground soil and fluid oil}

The present invention relates to underground soil and fluid oil sampling devices.

After industrialization, groundwater or soil contamination caused by hazardous chemicals and wastes has become a problem due to global industrial development and population growth, and interest in efficient management and restoration is increasing. In particular, as industrial development progresses, oil usage has increased significantly, and accordingly, the number of storage facilities such as tanks for storing oil, gas stations, factories, and related processing facilities continues to increase. Meanwhile, oil and hazardous chemicals leaking from these facilities are accelerating the contamination of soil and groundwater.

Meanwhile, in order to efficiently identify and manage such soil contamination, collecting soil samples is considered very important, and various methods for this are known, for example, drilling in the form of a screw and then inserting a soil sampler into the ground to sample the soil. This method of collecting samples is commonly used. Meanwhile, a general sampler for collecting underground samples has a tubular shape, and when the soil is struck or drilled, the soil flows directly into the sampler, allowing various types of soil to be collected depending on the depth.

In relation to this, in order to accurately determine the condition of the soil, the soil and the fluid oil contained in the soil must be collected separately to increase the reliability of the sampler analysis results. To this end, if a soil sampler and a fluid oil sampler device must be equipped at the same time, the cost is high. As it increases, maintenance, repair, and management are difficult, and the sampling process is complex and complex, which can lead to significant losses in terms of time and cost.

Prior Document 1: Korean Patent Publication No. 10-2016-0107897 (published on September 19, 2016)

The technical object of the present invention is to provide a sampler that can prevent the reliability of sample analysis from being lowered due to sampling at different locations when collecting soil samples and oil samples.

In addition, the technical object of the present invention is to provide a sampler that can minimize the sampling cost by constructing the sampler at a relatively low cost.

Additionally, the technical problem of the present invention is to provide a sampling device that can increase the reliability of oil sampling.

According to one embodiment of the present invention, it relates to a sampling device inserted into the ground, comprising: a tubular perforated pipe 100 having one or more openings 101 formed on a side thereof; A cutting shoe 150 is provided in a tubular shape and is fastened to the front end of the perforated pipe 100, and the outer peripheral surface of the front end is chamfered at a predetermined angle; And a perforation module (M1) for intubating the perforated tube 100 to a target depth pre-specified by the user, wherein the perforation module (M1) includes a rod-shaped rod portion inserted into the rear end of the perforated tube 100 ( 200); And a perforated hole that is fastened to the front end of the rod unit 200 and is positioned so that a portion of the front end is exposed to the outside in the front end direction of the cutting shoe 150, and has a bar shape but whose diameter narrows toward the front end to facilitate underground insertion. It may include a pin 210;

In addition, after collecting the perforated module (M1) from the perforated pipe 100, a soil collection module (M2) is inserted into the rear end of the perforated pipe 100, and the soil collection module (M2) is connected to the cutting shoe (150). A tube-shaped collection pipe (300) that is provided with a receiving space to accommodate the soil sample (S1) flowing into the cutting shoe (150) as it is inserted into the ground; And the collection pipe 300 is fastened to the rear end of the collection pipe 300 to seal it so that the collected soil sample (S1) does not leak to the outside, but allows the soil sample (S1) to flow into the collection pipe 300. ) A coupler 350 in which an exhaust hole 352 is formed to discharge the air inside to the outside; It includes, and the soil sample (S1) inside the collection pipe (300) can be collected by collecting the soil collection module (M2).

In addition, a non-porous pipe 110 is provided in the shape of a tube having the same inner and outer diameters as the perforated pipe 100 and is fastened to the rear end of the perforated pipe 100, and the soil collection module M2 is, An extension rod 200' having a length corresponding to the hollow pipe 110 and fastened to the rear end of the coupler 350 may be further provided.

In addition, after collecting the soil sampling module (M2) from the perforated pipe 100, an oil sampling module (M3) is inserted into the rear end of the perforated pipe 100, and the oil sampling module (M3) is provided in a rod shape. an oil collection rod 400 located inside the perforated pipe 100; and a plurality of oil adsorption members 410 provided on the outer peripheral surface of the oil collection rod 400 and arranged along the longitudinal direction, and adsorbing oil flowing in from the soil through the opening 101. By collecting the module M3, the oil sample S2 adsorbed on the oil adsorption member 410 can be collected.

A non-porous pipe 110 is provided in the shape of a tube having the same inner and outer diameters as the perforated pipe 100 and is fastened to the rear end of the perforated pipe 100, and the oil collection module M3 includes the perforated pipe ( An extension rod 200 ′ having a length corresponding to that of 100 and fastened to the rear end of the oil collection rod 400 may be further provided.

In addition, the rod part 200, the oil collection rod 400 or the coupler 350 is inserted into the rear end, and the outer diameter corresponds to the inner diameter of the perforated pipe 100 or the non-porous pipe 110. A center cap 500 is further provided with a diameter and corrected to be located on the central axis of the perforated pipe 100 or the non-porous pipe 110, and is located at the rear end of the center cap 500 and is struck, so that the perforated pipe ( A perforation drive cap 510 for inserting 100 into the ground may be further provided.

In addition, a collection drive head that is fastened to the rear end of the rod unit 200, the oil collection rod 400 or the coupler 350, has a flange 610 formed on the outer peripheral surface of the rear end, and has a thread formed on the inner peripheral surface. It can be provided.

In addition, the soil sampling module (M2) may further include a tubular inner case 310 provided to be in contact with the inner peripheral surface of the sampling pipe 300.

A fixing ring 320 is fastened to the front end of the collection pipe 300 and seals the space between the inner peripheral surface of the collection pipe 300 and the outer peripheral surface of the inner case 310 to prevent the soil sample (S1) from entering the space. It can be provided.

In addition, the opening 101 is opened in a rectangular shape, and the opening 101 is a rectangular vertical type having a long length in the same vertical direction as the longitudinal direction of the perforated pipe 100 or a long length in the horizontal direction. It may be a horizontal type with a rectangular shape.

According to the present invention, both soil samples and oil samples can be collected through one device through one construction, so the sampling time can be significantly shortened compared to the case of sampling using multiple devices, and sampling is performed at the same location. Therefore, the reliability of the sampling analysis results is excellent.

In addition, according to the present invention, the components required for soil sampling and oil sampling are shared with each other, but because the configuration is compact, the manufacturing cost of the sampler device can be reduced.

Figure 1 is a cross-sectional view and a front view of each configuration of an underground soil and fluid oil sampling device according to an embodiment of the present invention.
2 to 7 are diagrams showing the procedure for collecting soil samples and oil samples through a sampling device capable of collecting underground soil and fluid oil according to an embodiment of the present invention.
Figure 2 is a diagram showing an underground soil and fluid oil sampling device according to an embodiment of the present invention, where <a> is a cross-sectional view showing drilling through a perforation module to a sampling point in the ground, and <b> is a drive head for collection. This is a cross-sectional view showing removing the perforated module through .
Figures 3 and 4 are diagrams showing the collection of soil samples through an underground soil and fluid oil sampling device according to an embodiment of the present invention. <c> in Figure 3 is a step of preparing a soil collection module, and <d> is a step of positioning the soil sample (S1) within the soil sampling module through the soil sampling module, and <e> and <f> in FIG. 4 are cross-sectional views showing removing the soil sampling module from the perforated pipe.
Figure 5 is a cross-sectional view showing that the underground soil and fluid oil sampling device according to an embodiment of the present invention is extended to collect a primary soil sample (S1) or a soil sample (S1) located at a deeper level. , <g> in Figure 5 shows that a non-porous pipe is connected to the rear end of the perforated pipe, and an extension rod 200' is connected to the tip at the rear end of the coupler to extend the length, and <g> and <h> in Figure 5 , <i> and <j> in Figure 6 are cross-sectional views showing collecting the secondary soil sample (S1).
FIG. 7 is a diagram showing collecting an oil sample (S2) through a sampling device capable of collecting underground soil and fluid oil according to an embodiment of the present invention. <k> in FIG. 7 represents the oil collection module as a perforated pipe. It shows that the oil flowing in through the opening is collected by inserting it into the hole, and <l> in FIG. 7 is a cross-sectional view showing the oil collection module being removed from the perforated pipe and the non-porous pipe.

Hereinafter, with reference to the attached drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily implement the present invention. However, the present invention may be implemented in various different forms and is not limited to the embodiments disclosed below. In addition, in order to clearly disclose the present invention in the drawings, parts not related to the present invention are omitted, and identical or similar symbols in the drawings indicate identical or similar components.

The purpose and effect of the present invention can be naturally understood or become clearer through the following description, and the purpose and effect of the present invention are not limited to the following description.

The purpose, features and advantages of the present invention will become clearer through the following detailed description. Additionally, in describing the present invention, if it is determined that a detailed description of known techniques related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description will be omitted. Hereinafter, embodiments according to the present invention will be described in detail with reference to the attached drawings.

Referring to FIG. 1, the underground soil and fluid oil sampling device according to an embodiment of the present invention collects soil samples (S1) at a target depth by inserting them into the ground, and sequentially collects fluid oil samples (S2) together. It is about a sampling device that can For this purpose, the present invention includes a perforated tube 100 having an opening 101 formed on the side, a cutting shoe 150 fastened to the front end of the perforated tube 100, and a perforated module (M1) for cannulating the perforated tube 100 to a pre-specified target depth. ), a soil collection module (M2) for collecting soil at a target depth, and an oil collection module (M3) for collecting fluid oil at a target depth. In addition, a non-porous pipe 110 capable of extending the length of the perforated pipe 100 according to the target depth and an extension rod 200' capable of extending the length of each module may be further provided. In addition, a center cap 500 and a drive cap 510 for drilling holes for installation of each module and a drive head 600 for collection may be further provided. From now on, each configuration will be described in detail with reference to the drawings.

The perforated pipe 100 is provided in a tube shape to collect a soil sample (S1) at a target depth in the ground, and one or more openings 101 are formed on the side to collect oil. In detail, the perforated pipe 100 is provided in the shape of a pipe having a long length in the longitudinal direction, and an opening 101 is formed on the side to allow oil flowing in from the soil at a target depth to flow into the inside. One or more openings 101 may be arranged along the longitudinal direction of the perforated pipe 100 having a tubular shape, and may be provided in more detail. The opening 101 may be provided in various shapes such as circular, oval, polygonal, square, or rectangular. In the present invention, the description is based on the fact that it is provided in a rectangular shape. More specifically, the opening 101 is provided in a rectangular shape, and is of a vertical type having a long length in the same vertical direction as the longitudinal direction of the perforated pipe 100, or a horizontal type having a long rectangular shape having a long length in the horizontal direction. It can be provided.

The cutting shoe 150 is provided in a tube shape to facilitate insertion of the perforated pipe 100 into the ground of the soil, or to facilitate the introduction of the soil sample (S1) into the collection pipe 300, which will be described later. am. The cutting shoe 150 is provided with a shorter length than the perforated pipe 100, and for ease of insertion and introduction as described above, the front end of the cutting shoe 150 may have an edge formed. In detail, the outer peripheral surface of the front end of the cutting shoe 150 may have an inclined surface 151 formed at a predetermined angle so that the width becomes narrower toward the front end. More specifically, the outer peripheral surface of the front end of the cutting shoe 150 may be formed to be chamfered at a predetermined angle.

Referring to Figure 2, the perforation module (M1) is a component that intubates the perforated pipe 100 at a target depth pre-designated by the user, and is fastened to the rod-shaped rod portion 200 and the front end of the rod portion 200. It may include a perforated pin 210.

The rod portion 200 is provided in a rod shape and is inserted into the rear end of the perforated pipe 100. Accordingly, the outer diameter of the rod portion 200 is smaller than the inner diameter of the perforated pipe 100. In addition, it is preferable that the length of the rod unit 200 corresponds to the length of the perforated pipe 100 or is longer than the perforated pipe 100.

The perforated pin 210 is configured to facilitate underground insertion, is fastened to the front end of the rod portion 200, and is positioned so that the front end of the perforated pin 210 is partially exposed to the outside in the shear direction of the cutting shoe 150. It can be. In addition, the perforated pin 210 may have a shape whose diameter narrows toward the front end to increase insertion into the ground. That is, the front end of the perforated pin 210 may have an edge-like shape. In addition, the perforated pin 210 is fastened to the front end of the rod portion 200 so that it is partially exposed to the outside in the shear direction of the cutting shoe 150, and the outer peripheral surface of the perforated pin 210 and the inner peripheral surface of the cutting shoe 150 are provided. The space between them may be provided to be sealed. Therefore, the edged shear shape of the perforated pin 210 increases the insertion ability into the ground, but prevents unnecessary soil from flowing into the space between the perforated pin 210 and the cutting shoe 150 when inserted into the ground.

Referring to FIGS. 3 and 4 , after the perforated pipe 100 reaches the target depth pre-designated by the user through the perforated module M1, the perforated pipe 100 is removed from the perforated pipe 100 and collected.

Next, the soil collection module (M2) is inserted into the rear end of the perforated pipe 100, and the perforated pipe 100 is further inserted into the soil with the soil collection module (M2) inserted. A soil sample (S1) can be collected, and the soil sample (S1) can be collected by collecting the soil collection module (M2).

This soil collection module (M2) is provided at the rear end of the collection pipe 300 and the collection pipe 300, which is provided in a tube shape to accommodate the soil sample (S1) flowing into the cutting shoe 150. A coupler 350 may be included to prevent the soil sample S1 from leaking to the outside.

The collection pipe 300 is inserted into the perforated pipe 100, and as the cutting shoe 150 is inserted into the ground, a receiving space is created to accommodate the soil sample (S1) flowing into the cutting shoe 150. It may be provided in a tubular shape. The length of the collection pipe 300 may be provided to correspond to the length of the perforated pipe 100.

The coupler 350 is fastened to the rear end of the collection pipe 300 and accommodated within the collection pipe 300 to prevent the collected soil sample (S1) from leaking to the rear end of the collection pipe 300. It is a configuration that seals the space. The front end of the coupler 350 may be screw-coupled with the rear end of the collection tube 300, and the rear end of the coupler 350 has a tip 351 protruding in the rear end direction so that the center cap 500, which will be described later, can be inserted. It is provided as much as possible, and a thread may be formed on the tip 351 so that a collection drive or an extension rod 200', which will be described later, can be screwed together. In addition, the coupler 350 seals the soil sample (S1) contained in the collection pipe 300 so that it does not leak, but penetrates the inside and outside so that the soil sample (S1) can be sequentially received inside the collection pipe 300. A discharge hole 352 may be formed to discharge the air in the collection pipe 300 to the outside.

As an additional example, referring to FIGS. 1 and 3, the soil collection module (M2) protects the collection pipe 300, protects the soil sample (S1) from the collection pipe 300, or collects the collection pipe 300. An inner case 310 may be further provided to easily remove the soil sample S1 from the collection tube 300. The inner case 310 may be provided in a tube shape, and may be provided with an outer circumferential surface of a size that contacts the inner circumferential surface of the collection tube 300.

In this case, a problem may occur where the soil sample (S1) flows into the space between the collection pipe (300) and the inner case (310). To solve this, the inner peripheral surface and inner surface of the collection pipe (300) are attached to the front end of the collection pipe (300). A fixing ring 320 that seals the space between the outer peripheral surfaces of the case 310 may be further provided. The fixing ring 320 is provided in a tubular shape and may be provided on the rear outer peripheral surface to be screw-coupled with a thread formed on the front inner peripheral surface of the collection tube 300. In order to block the soil sample (S1) from flowing into the space between the collection pipe 300 and the inner case 310, the fixing ring 320 may be formed so that the inner or outer peripheral surface protrudes further inward or outward, and the inner case When 310 is made of a soft material, it can be implemented in a direction in which the inner case 310 is screwed together when screwed to the collection tube 300, and can be provided in various other shapes.

For example, the outer peripheral surface of the fixing ring 320 is formed with an outer jaw that protrudes further in the outward direction, so that the fixing ring 320 can be screwed together with the inner case 310 and the collection tube 300 overlapped on the inside of the outer lip. You can. In this case, the thread formed on the outer peripheral surface of the fixing ring 320 must be screwed together with the thread formed on the front inner peripheral surface of the inner case 310.

In another example, an inner jaw protruding in the inner direction is formed on the inner peripheral surface of the fixing ring 320, and the front end of the inner case 310 is located on the inner jaw to seal the space between the collection tube 300 and the inner case 310. A catalog can also be implemented.

Referring to FIG. 5, the soil sample (S1) is first collected through the soil collection module (M2) as described above, and then the soil sample (S1) at a deeper depth is collected secondarily using a hollow tube (110). It is further provided, and the soil collection module (M2) may further include an extension rod (200').

The perforated pipe 100 is inserted into the ground, but the inner diameter is the same as the inner diameter and outer diameter of the perforated pipe 100 at the rear end of the perforated pipe 100 in order to collect the soil sample (S1) at a deeper depth than the length of the perforated pipe 100. And a tube-shaped imperforate pipe 110 having an outer diameter may be further provided and fastened. The perforated pipe 100 and the non-porous pipe 110 may have all shapes except the opening 101 having the same shape.

In addition, since the internal length is lengthened by the hollow pipe 110, the soil collection module (M2) may further include an extension rod (200'). In detail, the extension rod 200' is provided to be fastened to the rear end of the coupler 350, and the extension rod 200' may be provided with a length corresponding to the non-porous pipe 110 or the perforated pipe 100. .

Referring to FIG. 7, the soil collection module (M2) is collected from the perforated pipe 100 to collect the soil sample (S1), and then the oil collection module (M3) is further inserted at the rear end of the perforated pipe 100 to collect the oil in the soil. can be collected. The oil collection module (M3) may include an oil collection rod 400 and an oil absorption member 410.

The oil collection rod 400 is provided in a rod shape and is located inside the perforated pipe 100. Therefore, the oil collection rod 400 must be provided to have an outer diameter smaller than the inner diameter of the perforated pipe 100. In addition, the oil collection rod 400 is preferably provided with a length corresponding to the length of the perforated pipe 100.

The oil absorption member 410 is provided on the oil collection rod 400 and collects oil flowing in from the opening 101 formed on the side of the perforated pipe 100 by adsorbing it. The oil adsorption member 410 may be provided on the outer peripheral surface of the oil collection rod 400 and may be provided in plural pieces arranged along the longitudinal direction. At this time, the oil adsorption members 410 may be provided to be in contact with each other, but each neighboring oil adsorption member 410 may be provided to be spaced apart from each other at a predetermined distance to distinguish samples according to the depth of the soil. The oil adsorption member 410 may be made of various materials capable of adsorbing or receiving oil, and may be a porous material. For example, the oil absorption member 410 may be a sponge.

In detail, the sponge may be a melamine-based or polyurethane-based porous sponge. More specifically, it may be made of melamine-based resin. Specifically, a coating solution is prepared by mixing polydimethylsiloxane and cyclohexane, and the polydimethylsiloxane solution is prepared by mixing the polydimethylsiloxane base solution and the curing agent. It may be a coating solution prepared by mixing a polydimethylsiloxane solution and cyclohexane.

Next, the cleanly washed sponge is immersed in the coating solution for 0.5 to 1.5 hours to absorb the coating solution on the surface and inside of the porous sponge, and then soaked under vacuum conditions, specifically in a vacuum desiccator for 2 hours. It may be performed by vacuum treatment.

Meanwhile, degassing may occur within the vacuum desiccator. Meanwhile, a coating layer may be uniformly formed on the surface of the sponge while the vacuum treatment is performed in the vacuum desiccator. Next, the coating solution coated on the sponge is cured. Specifically, the coating process may be carried out by placing the coated sponge in a vacuum oven at a temperature range of 100 to 140° C. and curing it for 1 to 3 hours.

Through this step, the surface of the sponge is modified with hydrophobic polydimethylsiloxane (PDMS). The sponge has superhydrophobic properties, and specifically, the surface of the sponge or polydimethylsiloxane (PDMS) exhibits superhydrophobic properties with a contact angle of 150° or more, specifically 151.5°. Specifically, when the sponge is immersed in water for 10 seconds, the adsorption capacity for diesel in water may be 26 g/g or more, specifically 26.35 g/g or more.

In addition, when the sponge is immersed in water for 10 seconds to adsorb underwater diesel and the adsorption experiment of squeezing it by hand is repeated 10 times, the adsorption performance for underwater diesel may be maintained at more than 88%.

Meanwhile, when the target depth is at a deep depth, the oil receiving module may further include an extension rod 200', like the extension rod 200' of the soil sample (S1) module. The extension rod (200') may be provided as the same extension rod (200') as the extension rod (200') of the soil sample (S1) module, and is fastened to the rear end of the oil collection rod (400). (400) and the oil adsorption member 410 may pass through the non-porous pipe 110 and reach the depth where the perforated pipe 100 is located.

By removing the oil collection module M3 from the perforated pipe 100 or the non-porous pipe 110 as described above, the oil adsorbed and collected on the oil adsorption member 410 can be recovered.

On the other hand, when the perforated pipe 100 is inserted into the ground and placed at a specific depth pre-designated by the user, or the perforated pipe 100 is inserted into the ground at a specific depth to collect the soil sample (S1) into the collection pipe 300. In order to insert the perforated pipe 100 into the ground, a center cap 500 and a perforated drive cap 510 may be further provided.

In detail, the center cap 500 is damaged, bent, or in an unwanted direction because each component located inside the perforated pipe 100 is not located on the same central axis line as the perforated pipe 100 when each hitting component is struck. In order to prevent insertion into the ground, each component can be positioned on the same central axis as the central axis of the perforated pipe 100.

The center cap 500 may be provided to be inserted into the rear end of the rod portion 200 of the perforated module (M1). Additionally, the center cap 500 may be provided to be inserted into the rear end of the oil collection rod 400. Additionally, the center cap 500 may be provided to be inserted into the rear end of the coupler 350. This center cap 500 has a rod portion 200 having a relatively small outer diameter compared to the inner diameter of the perforated pipe 100, and a tip 351 located at the rear end of the oil collection rod 400 or coupler 350. (100) or be positioned on the same central axis line as the central axis of the impermeable pipe (110). Therefore, the center cap 500 has an opening at the front end so that it can be inserted and inserted into the tip 351 located at the rear end of the rod portion 200, the oil collection rod 400, or the coupler 350, and has an outer diameter. It is provided with a diameter corresponding to the inner diameter of the perforated pipe 100 or the non-porous pipe 110, and can be corrected to be positioned on the central axis of the perforated pipe 100 or the non-porous pipe 110.

The rear end of the center cap 500 may be further provided with a perforated drive cap 510 for striking, and the front end of the perforated drive cap 510 is opened into a shape that can accommodate the center cap 500. It is provided. The perforated pipe 100 can be inserted into the ground by applying a blow to the outer peripheral surface of the rear end of the perforated drive cap 510.

Meanwhile, in order to recover the perforated module (M1), soil collection module (M2), or oil collection module (M3) from the perforated pipe 100 or non-perforated pipe 110, the rear end of the rod portion 200 of the perforated module (M1) The collection drive head 600 is fastened to the tip 351 at the rear end of the coupler 350 of the soil collection module (M2), or is fastened to the rear end of the oil collection rod 400 of the oil collection module (M3). may be further provided. The collection drive head may be provided with a flange 610 formed on the outer peripheral surface of the rear end in order to more easily collect each component. In addition, a thread may be formed on the inner peripheral surface of the rear end of the collection drive head so that a mechanical or physical device for recovery can be connected.

The preferred embodiments of the present invention described above have been disclosed for illustrative purposes, and those skilled in the art will be able to make various modifications, changes, and additions within the spirit and scope of the present invention, and such modifications, changes, and additions will be possible. should be regarded as falling within the scope of the above patent claims.

Those of ordinary skill in the technical field to which the present invention pertains can make various substitutions, modifications and changes without departing from the technical spirit of the present invention. Therefore, the present invention is limited to the above-described embodiments and the accompanying drawings. It is not limited by

In the above-described exemplary system, the methods are described on a flowchart basis as a series of steps or blocks; however, the invention is not limited to the order of the steps, and some steps may occur simultaneously or in a different order than other steps as described above. You can. Additionally, those skilled in the art will understand that the steps shown in the flowchart are not exclusive and that other steps may be included or one or more steps in the flowchart may be deleted without affecting the scope of the present invention.

100: perforated pipe 101: opening
110: Military tube 150: Cutting shoe
151: slope
200: Rod part 210: Perforated pin
200`: Extension rod
300: Collection tube 310: Inner case
320: fixing ring
350: Coupler 351: Tip
352: discharge hole
400: Oil collection rod 410: Oil adsorption member
500: Center cap 510: Perforated drive cap
600: drive head for collection 610: flange
M1: Perforation module M2: Soil collection module
M3: Oil extraction module
S1: Soil sample S2: Oil sample

Claims (10)

Pertaining to a sampling device inserted into the ground,
A tubular perforated pipe (100) with one or more openings (101) formed on its side;
A cutting shoe 150 is provided in a tubular shape and is fastened to the front end of the perforated pipe 100, and the outer peripheral surface of the front end is chamfered at a predetermined angle; and
It includes a perforation module (M1) for cannulating the perforated tube 100 to a target depth pre-specified by the user,
The perforated module (M1) is,
A rod-shaped rod portion 200 inserted into the rear end of the perforated pipe 100; and
A perforated pin is fastened to the front end of the rod unit 200 and positioned so that a portion of the front end is exposed to the outside in the front end direction of the cutting shoe 150, and has a bar shape with a diameter that narrows toward the front end to facilitate underground insertion. (210); Includes,
After collecting the perforated module (M1) from the perforated pipe 100, a soil collection module (M2) is inserted into the rear end of the perforated pipe 100, and the soil collection module (M2) is connected to the cutting shoe 150. A tube-shaped collection pipe (300) that is provided with a receiving space to accommodate the soil sample (S1) flowing into the cutting shoe as it is inserted into the ground; And the collection pipe 300 is fastened to the rear end of the collection pipe 300 to seal it so that the collected soil sample (S1) does not leak to the outside, but allows the soil sample (S1) to flow into the collection pipe 300. ) A coupler 350 in which an exhaust hole 352 is formed to discharge the air inside to the outside; Includes, collecting the soil sample (S1) inside the collection pipe (300) by collecting the soil collection module (M2),
After collecting the soil sampling module (M2) from the perforated pipe 100, an oil sampling module (M3) is inserted into the rear end of the perforated pipe 100, and the oil sampling module (M3) is provided in a rod shape and An oil collection rod (400) located inside the perforated pipe (100); and a plurality of oil adsorption members 410 provided on the outer peripheral surface of the oil collection rod 400 and arranged along the longitudinal direction, and adsorbing oil flowing in from the soil through the opening 101. An underground soil and fluid oil sampling device that collects an oil sample (S2) adsorbed on the oil adsorption member (410) by collecting the module (M3).
delete According to claim 1,
A non-porous pipe (110) is provided in the shape of a tube having the same inner and outer diameters as the perforated pipe (100) and is fastened to the rear end of the perforated pipe (100),
The soil sampling module (M2) is an underground soil and fluid oil sampling device further provided with an extension rod (200') having a length corresponding to the hollow pipe (110) and fastened to the rear end of the coupler (350).
delete According to claim 1,
The oil collection module (M3) is further provided with an extension rod (200') having a length corresponding to the perforated pipe (100) and fastened to the rear end of the oil collection rod (400). An underground soil and fluid oil sampling device.
According to any one of claims 1 and 3,
It is inserted into the rear end of the rod portion 200, the oil collection rod 400, or the coupler 350, and has an outer diameter corresponding to the inner diameter of the perforated pipe 100 or the non-porous pipe 110. A center cap 500 is further provided for correcting the position to be located on the central axis of the perforated pipe 100 or the non-porous pipe 110,
An underground soil and fluid oil sampling device further provided with a perforation drive cap 510 that is located at the rear end of the center cap 500 and inserts the perforated pipe 100 into the ground by hitting it.
According to any one of claims 1 and 3,
A collection drive head 600 is fastened to the rear end of the rod unit 200, the oil collection rod 400, or the coupler 350, has a flange 610 formed on the outer peripheral surface of the rear end, and has a thread formed on the inner peripheral surface. Further equipped with underground soil and fluid oil sampling devices.
According to claim 1,
The soil collection module (M2) is,
An underground soil and fluid oil sampling device further comprising a tubular inner case 310 provided to contact the inner peripheral surface of the collection pipe 300.
According to claim 8,
A fixing ring 320 is fastened to the front end of the collection pipe 300 and seals the space between the inner peripheral surface of the collection pipe 300 and the outer peripheral surface of the inner case 310 to prevent the soil sample (S1) from entering the space. Equipped with underground soil and fluid oil sampling device.
According to claim 1,
The opening 101 is opened in a rectangular shape,
The opening 101 is a vertical type of a rectangular shape having a long length in the same vertical direction as the longitudinal direction of the perforated pipe 100, or a horizontal type of a rectangular shape having a long length in the horizontal direction. An underground soil and fluid oil sampling device. .

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