KR200476076Y1 - Underwater sediment sampler - Google Patents

Abstract

The underwater sediment sample collecting apparatus 1 according to the present invention has a space in which a soil sample 101 can be filled in a tubular body having a circular cross section and elongated and the upper end portion 2a and the lower end portion 2b are both An open sampling pipe (2); An upper stopper (3) coupled to an upper end (2a) of the sample collection tube (2); A lower stopper (4) coupled to a lower end (2b) of the sample collection tube (2); A nipple insertion hole 30 formed in the upper stopper 3; A nipple 5 coupled to the nipple insertion hole 30; And a cap nut detachably coupled to the nipple 5 when the nipple 5 is coupled to the upper stopper 3, A first screw portion 51a is formed on the exposed surface of the first tubular portion 51 and a third screw portion 6a is formed on the inner surface of the cap nut 6, One screw portion 51a and the third screw portion 6a of the cap nut 6 are engaged and engaged with each other.

Description

Underwater sediment sampler [0001]

The present invention relates to an underwater sediment sampler, and in particular, when a sample is taken for the purpose of surveying soil sediments immersed in water, a diver can carry it in easily and can use it easily. To a sampler for underwater sediments.

At present, dams, rivers and coasts have accumulated sand, silt, and dead fish and shellfish, and environmental pollution is increasing day by day. In order to prevent environmental pollution and establish coastal development measures by grasping the state of raw water as a water source, the composition of polluted sediments, distribution and thickness of sediments, etc., it is necessary to first acquire the soil samples of the underwater sediments in the area with a simple method This is the key. Especially, it is necessary to collect sediments of underwater soil sediments as samples to detect changes in environmental pollutants from a certain point in the past to the present. Therefore, when samples of underwater sediments are sampled, It is important to acquire it thoroughly without it.

As a method of sampling sediment in the sea from the sea, dams and lakes, there are a method in which a person (a diver) takes down a sample collecting pipe directly under the water and takes out a soil sediment to a sampling pipe and a special method such as a barge or a marine drilling ship There is a method of collecting soil sediment in the water using equipment. In the case of using barge or marine drill ship, sampling is carried out by using drilling equipment and drilling equipment. However, such sampling method using drill ship can be used for preparation of tugboat and drill ship, installation work of anchor, Transportation and so on, it is not effective as a means of investigation unless it is a deep sea area where people can hardly access.

Since most of the areas subject to environmental pollution survey in Korea are rivers, lakes, and coastal coastal areas less than 50m in depth, it is more convenient to take samples by taking divers directly rather than using special heavy equipment such as barges or drill rigs. It is much more efficient in terms of cost.

However, in the past, it has been difficult for the divers to carry sediment soil samples in the sampler in the water, which is cumbersome and time-consuming, and it is difficult to collect the samples in water thoroughly.

That is, in order to collect a sample of the underwater sediment soil, a sampling pipe in the form of a pipe is generally used. After putting the sampling pipe in the soil of the underwater sediment, the ground around the pipe is shoveled or hand- The lower end was exposed, and then the lower end of the sample sampling tube was carefully filled with a stopper. However, it was difficult and time-consuming to dig out the surrounding land. Also, when trying to fill the lower part of the sampling pipe with the plug, there was a problem that the sediment soil samples which had entered into the sampling pipe went out again It was difficult to collect sediment soil samples in an intact state.

In this situation, it has been necessary to develop a new type of underwater sediment sampler that allows divers to be easily harvested and ready for use while still easily collecting the soil samples.

In order to solve the above problems, the present invention is directed to a method for collecting a sample of sediment soil immersed in water, The present invention relates to a water sampler.

In order to attain the above object, the underwater sediment sampler provided by the present invention has a tubular body having a circular cross-sectional shape and having a space in which the soil sample (101) can be filled A sample collection tube 2 in which both the upper end 2a and the lower end 2b are opened; An upper stopper (3) coupled to an upper end (2a) of the sample collection tube (2); A lower stopper (4) coupled to a lower end (2b) of the sample collection tube (2); A nipple insertion hole 30 formed in the upper stopper 3; A nipple 5 coupled to the nipple insertion hole 30; And a cap nut detachably coupled to the nipple 5 when the nipple 5 is coupled to the upper stopper 3, A first screw portion 51a is formed on the exposed surface of the first tubular portion 51 and a third screw portion 6a is formed on the inner surface of the cap nut 6, 1 screw portion 51a and the third screw portion 6a of the cap nut 6 are engaged with each other.

In order to attain the above object, the underwater sediment sampler provided according to the present invention is characterized in that the nipple (5) has a hexagonal body portion (53) in the middle portion in the longitudinal direction thereof, The first tubular portion 51 is extended and integrally coupled in one direction and the second tubular portion 52 is integrally coupled to the hexagonal tubular body 53 in the second direction, A second threaded portion 52a is formed on the surface of the second tubular portion 52. The nipple 5 has a circular inner hole 54 in the longitudinal direction thereof, And are located on the same straight line as the first direction and are opposite in direction.

According to the present invention, a submersible sediment sampler can be easily carried and used by a diver. Once the sampler is put into the sediment soil in the water and the nipple of the upper plug is filled with the cap nut, The sediment soil sample that entered the sampling pipe does not flow out even if the sampling pipe is pulled out.

Therefore, when the underwater sediment sampler of the present invention is used, the diver does not have to dig the ground around the sampler, which makes the operation much easier than the conventional sampling method. In the case of collecting soil samples from underwater sediments using the underwater sediment sampler of the present invention, the sampling time can be shortened and the risk can be drastically lowered compared with the conventional method, thereby drastically reducing the labor cost of the workforce There are advantages to be able to.

1 is a front view of an underwater sediment sample collector 1 according to the present invention.
2 is a perspective view of an upper plug 3 coupled to an upper end 2a of the sample collecting tube 2 and an upper end 2a thereof in the underwater sediment sample collector 1 shown in FIG.
3 is a partially exploded perspective view of the underwater sediment sampler 1 according to the present invention.
4 shows the configuration of the upper stopper 3 and the nipple 5 fitted in the upper stopper in the underwater sediment sample collector 1 according to the present invention.
Fig. 5 is a sectional view showing the coupling relationship between the upper stopper 3 and the nipple 5, the cap nut 6 and the lock nut 7 in the present invention, Fig. 6 is a cross- And a coupling nut 7 are coupled to each other.
FIGS. 7 and 11 sequentially illustrate the process in which the diver P enters the water and collects the sample 101 of the underwater soil 100 using the underwater sediment sampler 1 of the present invention.

Hereinafter, the structure and effect of the underwater sediment sampler according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a front view of an underwater sediment sample collector 1 according to the present invention. 1, the underwater sediment sampler 1 according to the present invention comprises a sample sampling pipe 2 having a long elongated shape and an upper stopper 3 connected to upper and lower ends of the sample sampling pipe 2, And a lower stopper (4). The sample collection pipe 2 is a tube or pipe member having a circular cross-sectional shape, and an inner space in which a soil sample can be filled is provided at the center. Preferably, the sample collection tube 2 is made of a thermosetting plastic material so that the tube is transparent so that the inside of the tube is visible. The sample collecting tube 2 is made by dissolving a synthetic resin material as a thermosetting plastic in heat and injecting it into a molding die. For example, the sampling pipe 2 is made of polyvinyl chloride (PVC), polypropylene (PP), polyethylene (PE) , Polyethylene terephthalate (PET), acrylic resin, and the like.

The upper stopper 3 and the lower stopper 4 which are respectively coupled to the upper and lower ends of the sample collecting tube 2 are preferably made of a resilient hydrocarbon polymer (i.e., rubber) It is advantageous that a portion made of a flexible material is inserted into the upper and lower ends of the sample collecting tube 2 so as not to be easily detached. That is, the upper stopper 3 and the lower stopper 4 are forcedly fitted into the upper and lower ends of the sample collecting tube 2, and once they are inserted, they are not easily released unless they are pulled out by force. It is preferable to make the inner diameter of the upper stopper 3 and the lower stopper 4 smaller than the outer diameter of the sample sampling pipe 2.

The upper stopper 3 and the lower stopper 4 have the same shape except that only the upper stopper 3 is provided with a hole It differs from stopper (4). That is, the lower stopper 4 is in the form of a simple stopper having no hole, whereas the upper stopper 3 has a nipple 5 coupled to its upper surface 3a and a cap nut nut, 6) are combined.

In FIG. 1, reference symbol A ₁ denotes the length of the sample collection tube ₂ , and reference symbol A ₂ denotes the length of the sample in the state where the upper stopper 3 and the lower stopper 4 are fitted to the sample sampling pipe 2 Indicates the length of the sediment sample sampler 1. According to the inventor of the present invention, the length (A ₁ ) of the sample collecting tube 2 is preferably 0.5 to 1.5 m, and most advantageously, the length of 1 m is carried by the diver It was judged to be most suitable for use. The thickness of the tube material of the sample collecting tube 2 may be 0.5 to 5 mm. According to the experimental results, when the tube is made of polyvinyl chloride (PVC), a thickness of 1.0 to 2.0 mm is preferable. Of the population.

2 is a perspective view of an upper plug 3 coupled to an upper end 2a of the sample collecting tube 2 and an upper end 2a thereof in the underwater sediment sample collector 1 shown in FIG.

2, an upper stopper 3 made of a rubber material is coupled to the upper end 2a of the sample collecting tube 2 in an interference fit manner. A nipple insertion hole 30 (see FIG. 4) is formed on the upper surface 3a of the upper stopper 3 and a nipple 5 is inserted into the nipple insertion hole 30. A cap nut (6) is detachably coupled to the nipple (5).

3 is a partially exploded perspective view of the underwater sediment sampler 1 according to the present invention. The upper stopper 3 is coupled to the upper end 2a of the sample sampling tube 2 and the lower stopper 4 is coupled to the lower end 2b. The upper stopper 3 is always used in a coupled state while the lower stopper 4 is used to collect the underwater soil sample The sample collecting tube 2 is not inserted when the sample collecting tube 2 is inserted into the sample collecting tube 2 and the sample collecting tube 2 is inserted into the lower end portion 2b of the sample collecting tube 2 11).

The nipple 5 is always fixed to the upper stopper 3. The cap nut 6 inserts the sample sampling pipe 2 into the underwater soil 100 so that the soil sample 2 101 are all inserted, they are joined to the nipple 5 immediately before the sample collecting tube 2 is taken out (see Fig. 9).

4 shows the configuration of the upper stopper 3 and the nipple 5 fitted in the upper stopper in the underwater sediment sample collector 1 according to the present invention. 4, a nipple insertion hole 30 is formed in the upper surface 3a of the upper stopper 3 and a second tubular portion 52 of the nipple 5 is inserted into the nipple insertion hole 30. [ So that they are coupled in a forced fit manner. For this, the diameter of the nipple insertion hole 30 is preferably smaller than the outer diameter of the second tubular portion 52 of the nipple 5 by 0.1 to 3 mm.

The nipple 5 has an internal passage hole 54 formed along the longitudinal direction thereof. A hexagon body 53 is formed at the center of the nipple 5 with reference to FIG. 4, A first tubular body portion 51 extends above the hexagonal body portion 53 and a second tubular body portion 52 extends below the hexagonal body portion 53. 4, the upper direction of the hexagonal body portion 53 is referred to as a 'first direction', and the lower direction of the hexagonal body portion 53 is referred to as a 'second direction'. In the 'first direction' And the second tubular portion 52 is extended in the 'second direction'. A first screw portion 51a is formed on the surface of the first tubular portion 51 of the nipple 5 and a second screw portion 52a is formed on the surface of the second tubular portion 52. [ A third threaded portion 6a of the cap nut 6 is formed on the inner surface of the cap nut 6. The third threaded portion 6a of the cap nut 6 is inserted into the first tubular portion 51 of the nipple 5, 1 screw portion 51a.

When the second tubular portion 52 of the nipple 5 is pushed into the nipple insertion hole 30 from above the upper stopper 3 only the second tubular portion 52 of the nipple 5 is inserted into the nipple insertion hole 30 , And the hexagonal body portion 53 is engaged with the nipple insertion hole 30. [ At this time, when the fastening nut 7 is engaged with the second tubular portion 52 of the nipple 5 from the inside of the upper stopper 3 and the nipple 5 is fastened to the upper stopper 3, . The hexagonal body portion 53 of the nipple 5 has a hexagonal outer circumferential surface so that a person can turn it by hand or use a tool such as a wrench to easily tighten the cap nut 6. The cap nut 6 also has a hexagonal shape Therefore, the diver is easily turned by hand when the cap nut 6 is coupled to the nipple 5 underwater. In the present invention, the hexagonal body portion 53 and the cap nut 6 of the nipple 5 are formed in a hexagonal shape. Alternatively, the hexagonal body portion 53 and the cap nut 6 may be formed in different shapes such as a square shape or a pentagon shape. Belongs.

The fourth screw portion 7a is formed on the inner surface of the coupling nut 7 and the fourth screw portion 7a is engaged with the second screw portion 52a of the second tubular portion 52 of the nipple 5 Respectively.

Fig. 5 is a sectional view showing the coupling relationship between the upper stopper 3 and the nipple 5, the cap nut 6 and the lock nut 7 in the present invention, Fig. 6 is a cross- And a coupling nut 7 are coupled to each other.

5 shows the relationship between the nipple 5 and the fastening nut 7 and the cap nut 6 in the upper stopper 3. When the nipple 5 is fitted into the nipple insertion hole 30 (see Fig. 4) from above the upper stopper 3, the second tubular portion 52 of the nipple 5 is fitted into the upper stopper 3 And a part of the second tubular portion 52 is exposed to the inner space of the upper stopper 3. At this time, when the fastening nut 7 is fastened to the second tubular portion 52 of the nipple 5, the nipple 5 is firmly fixed to the upper stopper 3. Since the nipple insertion hole 30 of the upper stopper 3 is made slightly smaller than the diameter of the second tubular portion 52 of the nipple 5, Nipple insertion hole), the upper stopper tissue of the rubber material elastically tightens the nipple 5, so that there is no gap in the nipple insertion hole 30 (see FIG. 4).

In FIG. 5, reference numeral C ₁ denotes the inner diameter of the upper plug 3, C ₂ denotes the outer diameter of the upper plug ₃ , and C ₃ denotes the thickness of the material of the upper plug 3. And B ₁ indicates the height of the upper stopper 3. In the nipple 5, reference numeral E ₁ denotes the length of the first tubular portion 51, E ₂ denotes the height of the hexagonal body portion 53, E ₃ denotes the length of the first tubular portion 51, The outer diameter of the tubular portion 52, and E ₄ the inner diameter, respectively. On the other hand, in the cap nut 6, reference symbol D ₁ denotes the height of the cap nut 6, D ₂ denotes the outer diameter of the cap nut, and D ₃ denotes the inner diameter of the cap nut.

The inner diameter C ₁ of the upper stopper 3 is preferably 4.5 to 6.0 mm and the thickness C ₃ of the material of the upper stopper ₃ is 3.0 to 4.5 mm And the height B ₁ of the upper stopper 3 is preferably 3.0 to 5.0 mm. The upper stopper 3 and the lower stopper 4 are made of a resilient hydrocarbon polymer material. The upper stopper 3 and the lower stopper 4 are made of a resilient hydrocarbon polymer material and are tightly coupled to the sample collecting pipe 2, It is preferable to make it so as to be equal to or slightly smaller than the outer diameter of the sample sampling tube 2 (for example, as small as 0 to 3 mm).

The height E ₂ of the hexagonal body 53 of the nipple 5 is 2.5 to 6.0 mm and the length E ₁ of the first tubular portion 51 is 5.0 to 15.0 mm. 5 may have an inner diameter E ₄ of 5.0 to 15.0 mm and an outer diameter E ₃ of 6.0 to 17.0 mm. The inner diameter D _{3 of the} cap nut 6 may be 6.0 to 17.0 mm and the height D ₁ of the cap nut 6 The outer diameter (D ₂ ) may be 13.0 to 20.0 mm. The inner diameter (F ₂ ) of the coupling nut 7 can be set to 6.0 to 17.0 mm, and the outer diameter (F ₁ ) can be set to 13.0 to 20.0 mm.

Referring to FIG. 6, the inner diameter (G ₁ ) of the sample collecting tube 2 may be 40.0 to 60.0 mm, and the thickness (G ₃ ) may be 0.7 to 2.0 mm. Preferably, the inner diameter (G ₁ ) of the sample sampling tube 2 is set to be 46.0 to 50.0 mm, and the thickness (G ₃ ) is set to be 1.0 to 1.5 mm.

FIGS. 7 and 11 sequentially show the process of collecting the sample 101 of the underwater soil 100 by using the underwater sediment sample sampler 1 of the present invention as the sampler (P) .

FIG. 7 shows a state in which the diver P, which is a sampler, enters the water and prepares to put the lower end of the sample collecting tube 2 into the underwater soil 100. At this time, the lower stopper 4 (see FIG. 1) is not filled in the lower end of the sample collecting tube 2, and only the upper stopper 3 is coupled to the upper end. A nipple 5 is coupled to the upper stopper 3, and the cap nut 6 is not engaged. Therefore, the inner passage hole 54 of the nipple 5 is in communication with the inside of the sample collecting tube 2.

FIG. 8 shows a process in which the diver P, which is a sample collector, pushes the sample collection tube 2 into the underwater soil 100. The underwater soil (100) is not hard because it is immersed in water. Therefore, when the sample is taken by pushing the sampling pipe (2), the sampling pipe (2) easily enters into the underwater soil (100). At this time, the underwater soil 100 enters the internal space of the sample collecting pipe 2 and becomes the soil sample 101. Since the internal passage hole 54 of the nipple 5 is opened, The water W originally contained therein exits through the inner passage hole 54 of the nipple 5 and out of the sample collecting pipe 2. The water W is introduced into the sampling pipe 2 through the inner passage hole 54 of the nipple 5,

9 shows a state in which the diaphragm P has inserted the cap nut 6 into the nipple 5 after the sample collecting tube 2 is inserted to a desired depth. The nipple 5 is filled with the cap nut 6 so that the pressure inside the sample collecting tube 2 is fixed so that even if the diver P as the sample collector pulls up the sample collecting tube 2 and pulls it out, The soil sample 101 that has already been contained in the soil sample 2 is not dropped down but remains as it is (see FIG. 10).

10, since the sample collection tube 2 is taken out of the underwater soil 100 and a hollow space 102 is formed, a negative pressure is applied to the sample sampling tube 2, so that the soil sample 101 is sampled It does not flow out of the pipe (2). Thus, using the underwater sediment sampler (1) of the present invention, the soil sample can be easily placed in the sample collection pipe (2) without digging the surrounding land.

Fig. 11 shows a view in which the diver P as a sample collector inserts the lower stopper 4 into the lower end portion 2b (see Fig. 3) after the underwater sediment sample sampler 1 is completely taken out. When the lower stopper 4 is coupled to the lower end of the sample collecting tube 2, the inside of the sample collecting tube 2 is completely sealed, and thus the soil sample 101 can be completely secured.

As described above, the underwater sediment sampler according to the present invention does not need to grasp the surrounding soil after inserting the sample collecting pipe into the underwater soil. Simply putting the cap nut 6 on the nipple (3) of the upper stopper 5), it is possible to safely collect soil samples.

The submersible sediment sampler according to the present invention can be easily carried and used by the diver. If the sampler is put into the soil in the water and the cap nut is filled in the nipple of the upper plug, sound pressure is caught inside the sampling pipe Even when the sample collection pipe is pulled out, there is an advantage that the soil sample that has entered the sample collection pipe does not flow out. Therefore, there is an advantage that the efficiency of the sampling can be greatly improved.

Therefore, when the underwater sediment sampler of the present invention is used, the diver does not have to dig the ground around the sampler, which makes the operation much easier than the conventional sampling method. In the case of collecting underwater soil samples using the underwater sediment sampler of the present invention, the sampling time can be shortened and the risk can be drastically lowered compared with the conventional method, and the labor cost of the worker can be greatly reduced There is an advantage.

1: Submerged sediment sample sampler 2: Sampling sampler
2a: upper end portion 2b: lower end portion
3: Upper cap 3a: Upper surface
3b: side portion 4: lower stopper
5: nipple 6: cap nut
6a: third thread portion 7: fastening nut
7a: fourth thread portion 30: nipple insertion hole
51: first pipe portion 51a: first screw portion
52: second tubular portion 52a: second threaded portion
53: hexagonal body portion 54: inner passage hole
100: underwater soil 101: soil sample
102: empty space P: diver
W: Water

Claims (6)

A tubular body having a circular cross section and having a space in which the soil sample 101 can be filled in the tubular body and having a top end 2a and a bottom end 2b, (2);
An upper stopper (3) coupled to an upper end (2a) of the sample collection tube (2);
A lower stopper (4) coupled to a lower end (2b) of the sample collection tube (2);
A nipple insertion hole 30 formed in the upper stopper 3;
A nipple 5 coupled to the nipple insertion hole 30; And
And a cap nut (6) detachably coupled to the nipple (5)
The nipple 5 has a first screw portion 51a on the surface of the first tubular portion 51 exposed to the outside of the upper stopper 3 when the nipple 5 is coupled to the upper stopper 3,
The nipple 5 has a circular inner hole 54 in its longitudinal direction and the inner hole 54 communicates with the interior of the sample collection tube 2,
A third screw portion 6a is formed on the inner surface of the cap nut 6 so that the first screw portion 51a of the nipple 5 and the third screw portion 6a of the cap nut 6 are engaged with each other, And,
The inner penetration hole 54 of the nipple 5 is inserted into the cap 2 so that the soil sampled in the sample sampling pipe 2 does not flow out even if the sample extractor P pulls out the sample sampling pipe 2. [ And a negative pressure can be generated inside the sample collecting pipe (2) when the nut (6) is closed. The hinge device according to claim 1, wherein the nipple (5) has a hexagonal body portion (53) at an intermediate portion in the longitudinal direction, and the first tubular portion (51) And a second tubular portion (52) is integrally coupled to the second tubular portion (52) in a second direction of the hexagonal body portion (53). The second tubular portion (52) (52a)
Wherein the second direction is located on the same straight line as the first direction and the directions are opposite to each other. The nipple insertion hole (30) is formed on the upper surface (3a) of the upper stopper (3), and the diameter of the nipple insertion hole (30) Is smaller by 0.1 to 3 mm than the outer diameter of the cylindrical portion 52,
Wherein the nipple (5) is coupled to the nipple insertion hole (30) by interference fit. The method according to claim 2 or 3,
Further comprising a coupling nut (7) coupled to the second tubular portion (52) of the nipple (5)
When the nipple 5 is fitted into the nipple insertion hole 30 of the upper surface 3a from above the upper surface 3a of the upper stopper 3, The fourth threaded portion 7a formed on the inner surface of the coupling nut 7 is connected to the second tubular portion 52 of the nipple 5 on the inner surface of the second tubular portion 52, And is engaged with the second screw portion (52a). The method according to claim 1,
The sample collection tube 2 is made of any one of thermosetting plastic materials including polyvinyl chloride (PVC), polypropylene, polyethylene, polyethylene terephthalate and acrylic resin,
The inner diameter of the upper plug (3) and the lower plug (4) is larger than the outer diameter of the sample collecting tube (2) The upper stopper 3 and the lower stopper 4 are coupled to the upper end 2a and the lower end 2b of the sample collecting tube 2 in an interference fit manner, Underwater sediment sampler. The underwater sediment sampler according to claim 1, wherein the length of the sample collection pipe (2) is 0.5 to 1.5 m, and the thickness of the pipe material of the sample collection pipe (2) is 0.5 to 5 mm.

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