KR101185762B1 - A vertical type deposits sampler - Google Patents

Abstract

PURPOSE: A vertical deposit sampler is provided to accurately analyze the physical and chemical properties of soil by gathering soil sample without a structural change. CONSTITUTION: A vertical deposit sampler comprises a first outer pipe(200), a second outer pipe(100), and a soil gathering pipe. A rotary blade(210) is formed on the inner surface of the first outer pipe. The second outer pipe is rotated by a connection member(120) connected to a bearing(110), and the first outer pipe is vertically transferred to the inside soil. The soil gathering pipe is inserted into the second outer pipe and gathers soil.

Description

A vertical type deposits sampler

The present invention relates to a vertical deposit sampler.

In general, the process of sampling the sedimentary layer while forming boreholes in the sedimentary layer must be performed in order to determine the optimal conditions necessary for the design of all civil engineering works. Sampling processes have been indispensable to obtain data.

In this sampling process, as the pipe-type collector, which is hit or transmitted with the power means, is introduced into the strata, the strata as deep as the intruder is filled. It is pulled out to the ground to check the strata of the sample from the outside.

"Soil sample collector" of Korean Patent Application No. 10-2006-0062607 discloses a tubular collector received a conventional blow, Figure 1 shows such a soil sampler.

In the case of the soil sampler due to the blow, the soil is compressed by the instantaneous blow and the compressed soil sample is collected. Therefore, there is a problem in analyzing the physicochemical characteristics and structure of the strata.

In addition, Japanese Patent Application No. 2002-129117, "Soil Sample Collection Method", discloses a tubular sampler receiving a rotational force, and FIG. 2 shows a soil sampler by such rotational force.

The soil sampler by the rotational force also had the phenomenon that the soil is twisted and distorted by the rotational force, which causes a problem in analyzing the exact physicochemical properties and structure of the strata.

An object of the present invention is to prevent soil distortion due to compression, torsion, etc. of the collected sample of the soil sampler by the impact or rotational force as described above, and to collect the exact structure of the soil as it is without change.

Vertical sediment collector according to the present invention comprises a hollow first outer tube including a rotary blade formed on the inner peripheral surface; The second hollow of the second outer tube is connected by a bearing coupled to the outside, the connection member coupled to the bearing, the hollow of the second outer tube is transmitted only when the vertical force of the first outer tube is rotated without rotation It includes an outer tube, characterized in that the soil is collected from the second outer tube.

Vertical sediment collector according to another embodiment according to the present invention comprises a hollow first outer tube including a rotary blade formed on the inner peripheral surface; The second hollow of the second outer tube is connected by a bearing coupled to the outside, the connection member coupled to the bearing, the hollow of the second outer tube is transmitted only while the rotation of the first outer tube without rotation Outer tube; And a hollow soil collecting tube inserted into the second outer tube and collecting the soil.

In addition, according to the present invention, the soil collecting pipe is longer than the second outer pipe, the top of the soil collecting pipe is formed with a through hole that can be inserted into the rod to remove the soil collecting pipe from the second outer pipe It is characterized by.

In addition, according to the present invention, an excavation blade is included in the bottom surface of the first outer tube.

In addition, according to the present invention, an excavation blade is included in the bottom surface of the second outer tube.

In addition, according to the present invention, the soil collecting pipe has a dividing line, characterized in that the soil can be separated in half after harvesting.

Vertical sediment collector according to the present invention comprises a hollow first outer tube including a rotary blade formed on the inner peripheral surface; The second hollow of the second outer tube is connected by a bearing coupled to the outside, the connection member coupled to the bearing, the hollow of the second outer tube is transmitted only while the rotation of the first outer tube without rotation Outer tube; A hollow soil collecting pipe inserted into the second outer pipe and collecting soil; And it characterized in that it comprises a support frame for supporting the first outer tube and the second outer tube.

Further, according to the present invention, the first outer tube and the second outer tube is characterized in that the upper end portion is rotatably connected in the longitudinal direction while being rotated by the guide portion installed in the support frame.

In addition, according to the present invention, the first outer tube is characterized in that rotatable by being connected by a rotary motor.

Soil extraction method according to the vertical sediment collector according to the present invention is an excavation step of excavating the soil by rotating the first hollow outer tube including a rotary blade formed on the inner peripheral surface; The second hollow of the second outer tube is connected by a bearing coupled to the outside, the connection member coupled to the bearing, the hollow of the second outer tube is transmitted only while the rotation of the first outer tube without rotation Soil harvesting step that the soil is collected in the outer tube; And a collecting step of collecting the soil collected by separating the second outer tube from the first outer tube.

As another embodiment according to the present invention, a method for collecting soil by a vertical sediment collector includes an excavation step of digging a soil by rotating a first hollow outer tube including a rotary blade formed on an inner circumferential surface thereof; It is connected to the outside of the first outer tube by a bearing coupled to the outside, the connection member coupled to the bearing, even if the first outer tube rotates while transmitting only the force transmitted vertically of the first outer tube A vertical transfer step of vertically transferring soil to the hollow second outer tube; And a soil harvesting step of inserting and coupling the inside of the second outer tube, the soil being vertically transported along the second outer tube to the hollow soil collecting tube for collecting the soil.

In addition, according to the present invention, the soil collection pipe is separated from the second outer pipe, characterized in that it comprises a collection step of collecting the soil collected by dividing the soil collection pipe.

The vertical sediment sampler according to the present invention is effective in accurately analyzing various data such as the physicochemical properties and structure of the soil since the soil sample to be collected is not compressed or twisted, so that the soil itself can be collected without distortion. to be.

Figure 1 shows a schematic diagram of a conventional hitting soil sampler.
Figure 2 shows a schematic diagram of a conventional rotary vertical soil sampler.
3 is a schematic view of the first non-rotating outer tube and the second outer tube according to the present invention.
Figure 4 shows the bottom surface of the first outer tube according to the present invention.
5 shows a second outer tube as another embodiment according to the present invention.
6 is a schematic view of a vertical sediment collector according to the present invention.
7 is a flowchart illustrating a soil collecting method by a vertical sediment collector according to the present invention.
8 is a flowchart showing a soil collecting method by a vertical soil extractor as still another embodiment according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. First, it should be noted that the same components or parts among the drawings denote the same reference numerals whenever possible. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted so as not to obscure the subject matter of the present invention.

Figure 1 shows a conventional blow vertical soil sampler, Figure 2 shows a conventional rotary vertical soil sampler.

3 is a schematic view of the first non-rotating outer tube and the second outer tube according to the present invention.

As shown in FIG. 3, the non-rotating second outer tube 100 according to the present invention is located outside of the hollow first outer tube 200 and is coupled to the first outer tube 200. And a connection member 120 coupled with the bearing 110. That is, the outer circumferential surface of the second outer tube 100 is coupled to each other by the bearing 110 coupled to the outer circumferential surface of the first outer tube and the connecting member 120 coupled to the bearing 110, thereby connecting the first outer tube ( Even if the 200 is rotated, the bearing 110 coupled to the first outer tube 200 absorbs the rotational force so that only the bearing 110 rotates, and the second outer tube 100 is non-rotating.

Rotating blade 210 is inclined on the inner circumferential surface of the first outer tube 200, the soil is excavated along the rotary blade 210 while the first outer tube 200 is rotated, the first outer tube 200 is soil It is excavated and transported inside.

The excavated soil is excavated while being transported upward along the rotary blade 210 formed on the inner circumferential surface of the first outer tube 200.

The first outer tube 200 receives a rotational force and a vertical force transferred into the soil, is connected to the outside of the hollow first outer tube 200 by the bearing 110, the connection member 120 connected to the bearing 110 By the second outer tube 100 is rotated without a vertical force of the first outer tube 200 transmitted to the connecting member 120 is transmitted to be vertically transported into the soil at the same time as the first outer tube (200). .

The second outer tube 100 to be vertically conveyed has a hollow shape, and soil is collected in the hollow of the second outer tube 100, and is vertically lowered by gradual rotation of the first outer tube 200 instead of instantaneous blow. Soil collected by the transfer to the second outer tube 100 is the soil collected is not subjected to compressive force.

In addition, since only the first outer tube 200 rotates, and the second outer tube 100 is in a non-rotating state, the soil to be collected is also not twisted.

Since the second outer tube 100 is connected to each other by the bearing 110 coupled to the first outer tube 200 and the connecting member 120 coupled to the bearing 110 and vertically transferred into the soil, the connection When the length of the member 120 is increased, the vertical resistance is increased during vertical transfer to the soil, so the problem occurs in the transfer, it is preferable that the length of the connection member 120 is as short as possible, the bearing 110 itself Most preferably, it functions as the connecting member 120.

When the bearing 110 itself functions as the connecting member 120, since the first outer tube 200 and the inner tube 100 is connected by the bearing 110, the first outer tube by the interval of the bearing 110 Between the outer circumferential surface of the (200) and the outer circumferential surface of the second outer tube (100) is spaced, and when the soil is introduced into the spaces spaced apart, the frictional resistance between the first outer tube (200) and the second outer tube (100) occurs In order to prevent the soil from entering between the space between the outer circumferential surface of the first outer tube 200 and the outer circumferential surface of the second outer tube 200, the protruding ring on the outer circumferential surface near the lower end of the first outer tube (200) 230 is installed.

The protruding ring 230 may be coupled to the first outer tube 200, but the protruding ring 230 may be installed on an outer circumferential surface near the bottom of the second outer tube.

Figure 4 shows the bottom surface of the first outer tube according to the present invention.

As shown in Figure 4, the bottom surface of the first outer tube 200 according to the present invention is formed in the wedge shape of the excavating blade 220 toward the vertical downward sharply.

Excavation blade 220 formed on the bottom surface of the first outer tube 200 is to improve the excavation of the soil when the first outer tube 200 is moved forward into the soil while rotating to smoothly transfer into the soil It plays a role.

5 shows a second outer tube as another embodiment according to the present invention.

As shown in Figure 5, the hollow second outer tube 100 according to the present invention is configured in a double tube shape, another soil harvesting pipe 300 is inserted therein, the soil harvesting pipe 300 Soil is taken from.

Since the hollow second outer pipe 100 and the soil collecting pipe 300 need only be inserted and removed, the hollow is inserted between the inner wall of the second outer pipe 100 and the outer wall of the soil collecting pipe 300. Is inserted in close contact.

Soil collected from the hollow soil collecting pipe 300 is the rotational force of the first outer pipe 200 is absorbed by the bearing 110 connected to the second outer pipe 100, only the vertical force of the first outer pipe (200) The second outer pipe 100 is transferred to the hollow soil collection pipe 300 in close contact with the second outer pipe 100, and only the vertical force of the first outer pipe 200 is transmitted as it is, so that the soil is twisted or compressed. It can be collected without receiving.

Soil harvesting pipe 300 has a longer length than the second outer pipe 100, the second outer pipe 100 to the top of the soil harvesting pipe 300, that is, protruded longer than the second outer pipe (100) The through hole 310 that can be removed by inserting the rod 320 to facilitate the removal of the soil collection pipe 300 is formed.

After the soil is collected in the soil collecting pipe 300, if the rod 320 is inserted into the through hole 310 to remove the soil collecting pipe 300 from the second outer pipe 100 and applied upward Soil harvesting pipe 300 is removed from the second outer pipe (100).

In addition, the soil harvesting pipe 300 has a dividing line 330 is formed in the longitudinal direction, it is possible to split the soil harvesting pipe 300 in half, the soil harvesting pipe 300 is removed from the second outer pipe (100) After being divided into halves along the dividing line 330 of the soil collecting pipe 300, the collected soil is immediately exposed to the outside, and soil analysis is easy.

The lower end surface of the second outer tube 100 also includes a wedge-shaped excavation blade 220 such as the excavation blade 220 of the lower end surface of the first outer tube 200 to the soil of the second outer tube 100. It may be easier to vertical transfer of.

6 is a schematic view of a vertical sediment collector according to the present invention.

As shown in FIG. 6, the vertical soil extractor 1 according to the present invention includes a hollow first outer tube 200 and a first outer tube 200 including a rotary blade 210 formed on an outer circumferential surface thereof. Located in the first outer tube 200 and the bearing 110 is coupled to the coupling member 120 is coupled, even if the rotation of the first outer tube 200 without rotating the vertical force of the first outer tube 200 Only the second outer tube 100 is inserted into the interior of the second outer tube 100, the soil collecting pipe 300, the first outer tube 200 and the second outer tube to collect the soil. And a support frame 400 for supporting 100.

The support frame 400 is provided with a level gauge (not shown) to help adjust the horizontal when the support frame 400 is installed.

Soil may be collected by the hollow soil collecting tube 300, as described in Figure 3, without the hollow soil collecting tube 300, the soil may be collected directly from the second outer tube (100).

The first outer tube 200 is a rotary blade 210 is formed at the lower end to help the excavation of the soil, the upper end is coupled to the guide portion 410 installed on the support frame 400 is rotated along the guide portion 410 While being transported in the longitudinal direction, the first outer tube 200 is transported along the guide part 410 when excavation of the soil.

The second outer tube 100 is also coupled to the guide portion 410 installed in the support frame 400 is transported while being guided in the longitudinal direction along the guide portion 410.

The first outer tube 200 is connected to the rotary motor 500 coupled to the support frame 400 to be rotatable, and the rotary motor 500 is connected to each other in the form of a belt and a pulley to the first outer tube 200. It may be connected to each other in the form of a sprocket and a chain.

7 is a flowchart illustrating a soil collecting method by a vertical sediment collector according to the present invention.

As shown in Figure 7, in the soil collection method according to the vertical soil extractor according to the invention excavation to excavate the soil by rotating the first hollow outer tube 200, including a rotary blade 210 formed on the inner peripheral surface Step (S100), which is located outside the first outer tube 200 is coupled to the connection member 120 by a bearing 110, the first outer tube without rotation even if the first outer tube 200 is rotated Soil harvesting step (S200), the soil is collected in the second outer tube 100 of the hollow that is transmitted only the vertical force (200), and the second outer tube 100 is separated and collected from the first outer tube (200) Characterized in that it comprises a collection step (S300) for collecting the soil.

This, as shown in Figure 3, shows a soil collection method of directly collecting the soil in the second outer tube (100),

When the second outer pipe 100 described in FIG. 5 is a double pipe, and the hollow soil collecting pipe 300 is separately placed inside the second outer pipe 100, the vertical soil as another embodiment as follows. Soil collecting method by harvester is possible.

8 is a flowchart illustrating a soil collecting method by a vertical sediment collector as another embodiment according to the present invention.

As shown in FIG. 8, the soil collecting method by the vertical soil extractor according to another embodiment of the present invention rotates the first outer tube 200 of the hollow including a rotary blade 210 formed on an inner circumferential surface thereof. Excavation step (S100) to excavate, is located outside the first outer tube 200 is coupled to the connection member 120 by a bearing 110, while the first outer tube 200 is rotated without rotation Vertically coupled step (S150), the soil is vertically transferred to the hollow second outer tube 100 is transmitted only the vertical force of the first outer tube 200, and inserted into the inside of the second outer tube 100, It includes a soil harvesting step (S200) in which the soil is vertically transported along the second outer pipe (100) to the hollow soil collection pipe (300) for collecting the soil.

In addition, the soil collected in the soil harvesting pipe 300 in the soil harvesting step is separated from the soil collecting pipe 300 from the second outer pipe 100, the dividing line formed along the longitudinal direction of the soil collecting pipe (300) The collection step (S300) for collecting the soil collected by dividing along the (330).

While the invention has been shown and described in connection with specific embodiments thereof, it is conventional in the art that various changes, modifications and variations are possible without departing from the spirit and scope of the invention as indicated by the appended claims. Anyone who knows the knowledge of is easy to know.

1: vertical sediment collector 100: second outer tube
110: bearing 120: connecting member
200: first outer tube 210: rotary blade
220: excavator blade 230: protruding ring
300: soil collection pipe 310: through hole
320: rod 330: dividing line
400: support frame 410: guide part
500: rotating motor
S100: Excavation step S150: Vertical feed step
S200: Soil Collection Step S300: Collection Step

Claims (12)

A hollow first outer tube including a rotary blade formed on an inner circumferential surface thereof;
The bearing is coupled to the outside of the first outer tube, is connected by a connection member coupled to the bearing,
It includes a hollow second outer tube that is rotated without transmitting even if the first outer tube rotates, only the vertical force of the first outer tube,
Vertical sediment collector, characterized in that the soil is collected from the second outer tube. A hollow first outer tube including a rotary blade formed on an inner circumferential surface thereof;
The bearing is coupled to the outside of the first outer tube, is connected by a connection member coupled to the bearing,
A hollow second outer tube to which only the vertical force of the first outer tube is transmitted while the first outer tube is rotated without rotation; And
Inserted inside the second outer tube, the vertical sediment collector, characterized in that it comprises a hollow soil collecting pipe for collecting the soil. The method of claim 2,
The soil collecting pipe is longer than the second outer pipe, the top of the soil collecting pipe is characterized in that the vertical through-hole is formed to be inserted into the rod to remove the soil collecting pipe from the second outer pipe Soil Harvester. The method of claim 3,
Vertical sediment collector, characterized in that the excavation blade is included on the bottom surface of the first outer tube. The method of claim 4, wherein
Vertical sediment collector, characterized in that the excavation blade is included on the bottom surface of the second outer tube. The method of claim 5,
The soil harvesting pipe has a split line, the vertical sediment harvester, characterized in that the soil is separable after separation. A hollow first outer tube including a rotary blade formed on an inner circumferential surface thereof;
Is connected to the outside of the first outer pipe by a bearing coupled to the outside, the connection member coupled to the bearing,
A hollow second outer tube to which only the vertical force of the first outer tube is transmitted while the first outer tube is rotated without rotation;
A hollow soil collecting pipe inserted into the second outer pipe and collecting soil; And
And a support frame for supporting the first outer tube and the second outer tube. The method of claim 7, wherein
And the first outer tube and the second outer tube are connected to each other in a longitudinal direction while being rotatable by a guide installed in the support frame at an upper end thereof. The method of claim 8,
The first outer tube is connected to the vertical by the rotary motor, sedimentary collector, characterized in that the rotatable. An excavation step of digging the soil by rotating a hollow first outer tube including a rotary blade formed on an inner circumferential surface;
The second hollow of the second outer tube is connected by a bearing coupled to the outside, the connection member coupled to the bearing, the hollow of the second outer tube is transmitted only while the rotation of the first outer tube without rotation A soil collecting step of collecting soil in the outer tube; And
And a collecting step of collecting the soil collected by separating the second outer tube from the first outer tube. An excavation step of digging the soil by rotating a hollow first outer tube including a rotary blade formed on an inner circumferential surface;
It is connected to the outside of the first outer tube by a bearing coupled to the outside, the connection member coupled to the bearing, even if the first outer tube rotates while transmitting only the force transmitted vertically of the first outer tube A vertical transfer step of vertically transferring soil to the hollow second outer tube; And
And a soil harvesting step of inserting and coupling the inside of the second outer pipe, the soil harvesting step of collecting the soil vertically transported along the second outer pipe to the hollow soil collecting pipe for collecting the soil. Soil collecting method by The method of claim 11,
And separating the soil collecting pipe from the second outer pipe, and collecting the soil collected by dividing the soil collecting pipe.

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