KR101643328B1 - Hydro-guard - Google Patents

Abstract

Disclosed is a hollow wall maintaining device for a hydraulic test of an unconsolidated alluvial layer. The hollow wall maintaining device including a guard casing for maintaining a hollow wall capable of being connected by drilling equipment (rod) and a filter having excellent open porosity (water permeability) on an inner wall of the guard casing is inserted into the unconsolidated alluvial layer. According to this, the hollow wall maintaining device for the hydraulic test of the unconsolidated alluvial layer is capable of preventing not only the collapse of the hollow wall within a hydraulic test area when performing the hydraulic test of the unconsolidated alluvial layer such as sand, gravel, clay, and the like in the middle of a boring investigation, but also a decrease in water permeability caused by injecting a testing water while preventing the precipitation of dig slime in a lower part of the test area, thereby improving the reliability of a hydraulic test result and a calculation of a hydrologic constant of subsoil based on the hydraulic test result while improving the accuracy of the test and enlarging a stratum of the unconsolidated alluvial layer where the hydraulic test is applicable.

Description

(Hydro-guard) for a hydraulic test of unconsolidated alluvial deposits [

The present invention relates to hydraulic tests at the time of geological or geotechnical investigations, and more particularly, to drilling of boreholes in an unconsolidated alluvial layer such as sand, gravel, and clay during drilling, During the test, it is possible to prevent the collapse of the walls in the hydraulic test zone in the borehole, to prevent the bottom precipitation of the slime as a by-product in the borehole, and to improve the error of the hydraulic test due to the test environment in the non- And to improve the reliability of the test results while proceeding accurately. The present invention also relates to a pneumatic holding device for a hydraulic test of a nonconsolidated alluvial layer.

In general, when designing and constructing civil engineering works for bridges, tunnels, dams, underground storage bases, radioactive waste disposal facilities, riverside filtration facilities and subways, the mathematical (groundwater) characteristics of the target strata (ground) Safety, and environment due to facilities.

Therefore, in the past, tests were conducted to determine the distribution characteristics of the strata through drilling and the repair characteristics of the strata (eg, sand, clay, gravel, weathered rock, rock, etc.) And so on.

At this time, there are various methods such as a permeability test, a pumping test, an instantaneous impact test, a hydraulic test and an injection test as the test methods for calculating the hydraulic constants. It is possible to identify it through the change of groundwater level.

The analytical method of the hydraulic test is based on the exact area of the test section in the target stratum and the homogeneous stratigraphic distribution within the test section as a whole, resulting in lower reliability of the calculated constants when errors occur .

On the other hand, in the case of carrying out a hydraulic test on a target stratum composed of unconsolidated alluvial layers (eg sand, gravel, clay), as shown in FIG. 1, The outer casing 100 is inserted into a non-cemented layer as a target layer and a piercing rod 200 is inserted through the inside of the outer casing 100 to form a hydraulic test section a1 for a hydraulic test in the non- The rod 200 is lifted through the drilling equipment and separated from the casing 100. The test water for the hydraulic test is injected or pumped into the casing 100, (Water permeability) in the test section (a1) was observed by observing the water level change of the test section (a1).

However, when the rod 200 is lifted to the outside of the borehole using the drilling equipment before the test water is injected into the hydraulic test section a1, conventionally, the soil 200 in the hydraulic test section a1 in the non- (A1) for a hydraulic test can not be properly secured due to the low cohesive force of the unconsolidated alluvial layer and the disadvantage that it is difficult to accurately check the area of the hydraulic test zone (a1) The slurry 300 precipitated by the excavation of the unconsolidated alluvial layer due to the collapse of the pore wall occurs while the precipitated slime 300 is not precipitated due to the lower precipitation of the outer casing 100, In the alluvial test bed, it is impossible to perform the hydraulic test in the noncorrosive alluvial bed, which is the obstacle that reduces the permeability of the test water supplied during the test water supply (injection). Or reliability of the test result is deteriorated.

In this case, it is necessary to derive the hydraulic constants including the water quantity (water quantity) coefficient by detecting the change of groundwater level over time. In this case, the water quantity (water quantity) of the hydraulic test section (a1) (a1) is a major factor in the mathematical constant calculation formula. In the past, from the lifting of the rod 200, the air wall in the hydraulic test zone a1 has collapsed and the water permeability capacity And the area for the repair test section (a1) can not be properly confirmed.

Published Japanese Patent Application No. 10-2009-0002448 (Publication date 2009.01.09) Japanese Patent Application Laid-Open No. 10-2013-0103987 (Publication date 2013.09.25)

SUMMARY OF THE INVENTION Accordingly, the present invention has been made to solve the above-mentioned problems occurring in the prior art, and it is an object of the present invention to provide a guard casing for a pneumatic wall which can be connected with a drilling rig, and a filter having an excellent hole- This makes it possible to prevent the walls from collapsing in the test area during the drilling test in the unconsolidated alluvial layer (sand, gravel, clay, etc.) during drilling. In addition, it is possible to prevent the lowering of the test section of the excavated slime while preventing the reduction of the permeability due to the test water injection. It is also possible to apply the hydraulic test in the nonconsolidated alluvial layer. This allows the repair of nonconsolidated alluvial deposits to improve the reliability of the calculation of the hydraulic constants according to the results of the hydraulic tests and the results Gongbyeok to provide a holding device for the purpose would have.

In order to accomplish the above object, the present invention provides an airless wall maintenance apparatus for an unconfined alluvial floor repair test, comprising: an outer casing connected to a drilling rig and forming a borehole for a hydraulic test on the unconsolidated allotment layer by the drilling rig; A hollow wall holding part for moving the water along the inner side of the outer casing to form a plurality of cutting holes as a tube to be supplied or injected with test water for a hydraulic test and to prevent a hollow wall from collapsing in a hydraulic test zone in the borehole; A slime collecting part coupled to a lower end side of the hollow wall holding part and inserted and fixed in the bottom of the borehole in the unconsolidated uppermost layer; And a control unit that is provided on an inner wall surface of the hollow wall holding unit and is inserted and fixed at an upper end of the slurry collecting unit to hold the hollow wall holding unit in a hydraulic test zone in the borehole, A tubular type filter unit having a constant rate so that a permeability test is performed on the unconsolidated alluvial layer through the incision hole; .

The hollow wall retaining portion may include: a first rod body; A second rod body coupled to the first rod body; A third rod body coupled to the second rod body; A porous wall tube coupled to the third rod body and having a plurality of cut-out holes formed at an outer periphery at regular intervals and coupled to the inner wall surface of the filter portion; .

In addition, the inner upper end of the hollow wall maintenance tube is formed with a detent jaw which restricts the upper flow so as to prevent the filter unit from escaping from the cut hole formed at equal intervals when the filter unit is coupled to the inner wall surface.

Further, a hook is formed at one end of the outer casing.

The first and second rod bodies are connected to each other by a first seal member which is provided at the joint portion of the second and third rod bodies to prevent leakage of the test water to be injected into contact with the inner wall of the upper end of the outer casing. And a second sealing member which contacts the inner wall surface of the lower end of the outer casing for fixing the position while blocking the leakage of the test water to be injected into the bonding portion of the hollow wall maintenance tube and a hooking portion for hooking the hooking jaw of the outer casing Respectively.

In addition, the first and second seal members are ring structures of a rubber material, and the engagement portions are metal ring structures.

In addition, the slime collecting unit is formed by combining an insertion cone for inserting and fixing the bottom of a borehole in a non-cemented alluvial layer as a target ground layer.

As described above, the present invention provides a pneumatic wall holding device comprising a guard casing for holding a pneumatic wall connectable with a drilling rig (rod), and a filter having an opening ratio (water passage capability) on the inner wall surface of the guard casing, It is possible to prevent collapse of the inner wall in the repair test section during the drilling test in the unconsolidated alluvial layer (sand, gravel, clay, etc.) during drilling, It is possible to apply the hydraulic test in the nonconsolidated alluvial layer by preventing the decrease of the permeability due to the test water injection while preventing the bottom sediment of the slime test section. The reliability of the calculation of the mathematical constant according to the present invention can be expected to be improved.

1 is a state diagram showing a conventional repair test.
2 is a perspective view of an embodiment of the present invention, which is a combined perspective view of a pneumatic holding device used for hydraulic testing in an unconsolidated alluvium;
Figure 3 is an assembled cross-sectional view of a pneumatic holding device used for hydraulic testing in an unconsolidated alluvium as an embodiment of the present invention.
4 is an exploded perspective view of a pneumatic holding device used for hydraulic tests in an unconsolidated alluvium layer according to an embodiment of the present invention;
Fig. 5 is a state diagram showing a state in which a hydraulic holding test is performed by injecting a pneumatic holding device into an unconsolidated alluvial layer of a target stratum according to an embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a perspective view of a pneumatic holding device used for a hydraulic test in a nonconsolidated alluvial layer according to an embodiment of the present invention. FIG. 3 is a perspective view of a pneumatic wall used for a hydraulic test in a non- 4 is an exploded perspective view of a pneumatic holding device used for hydraulic testing in an unconsolidated alluvial layer as an embodiment of the present invention.

2 to 4, the air holding apparatus for the hydraulic test of the unconsolidated alluvial layer according to the embodiment of the present invention includes an outer casing 10, a blank holding unit 20 for a hydraulic test, a slime A slime collecting unit 30 for collecting the slime, and a filter unit 40. [

The outer casing 10 is a tubular structure connected to a drilling rig. The drilling rig 11 is formed at one end of the outer casing. The drilling rig drills a borehole for repair testing in the upper and lower layers, .

The hollow wall holding portion 20 is a tubular body to which test water for a hydraulic test is supplied or injected. The hollow wall holding portion 20 has a plurality of cutting holes 20a formed on the outer periphery thereof. The hollow holding portion 20 moves along the inside of the outer casing 10, 22 and 23 and the air wall maintenance tube 24 in order to prevent the air wall from collapsing in the test section a1.

The first rod tube body 21 has a hollow portion (not shown in the figure) through which test water can be supplied or injected. An outer threaded portion (not shown in the figure) for coupling with the second rod tube body 22 ).

The second rod tube body 22 has a hollow portion (not shown in the figure) capable of supplying or injecting the test water and an inner threaded portion at the other end for fastening the outer thread of the first rod tube body 21 And an outer thread (not shown in the drawing) for coupling with the third rod body 23 is formed at one end.

The third rod body 23 has a hollow portion (not shown in the figure) capable of supplying or injecting the test water and an inner thread at the other end for fastening an outer thread of the second rod body 22 And an outer thread (not shown in the drawing) for coupling with the hollow wall maintenance tube 24 is formed at one end.

The first and second rod bodies 22 and 23 are connected to each other at a joint portion of the first and second rod bodies 22 and 23, So that the sealing member 25 is engaged.

The hollow wall maintenance tube 24 has a hollow portion (not shown in the figure) capable of supplying or injecting test water, and has an inner thread, which is fastened to the outer thread of the third rod body 23 (Not shown) for coupling with the slime 30 is formed at one end, and a plurality of cut-out holes 20a are formed at equal intervals at the outer circumference The filter portion 40 having a tubular shape is coupled to the inner wall surface.

At this time, when the filter unit 40 is coupled to the inner wall surface, the filter unit 40 is prevented from escaping from the cutout hole 20a formed at equal intervals, So that a stop jaw 24a is formed to limit an upper flow of the filter unit 40. [

Here, the third rod body 23 and the air holding tube 24 are connected to each other by interrupting the leakage of the test water supplied or injected into the outer casing 10, And the engaging portion 27 engaging with the engaging protrusion 11 of the outer casing 10 is engaged with the second sealing member 26. [

That is, the first and second sealing members 25 and 26 are ring-shaped members made of a rubber material, and the locking portion 27 is a metal ring structure. The locking portion 27 is a ring- The outer casing 10 is moved to the upper end when it is desired to carry out a hydraulic test while preventing the air wall from being collapsed. At this time, the outer casing 10 is stuck on the engagement protrusions 11 formed on the outer casing 10, And the tube 24 is guided to be located in the borehole repair test section a1 for the repair test.

The slurry collecting part 30 has a hollow part (not shown in the figure) through which test water can be supplied or injected, and the other end has an inner thread (Not shown) for coupling with the insertion cone 31 is formed at one end of the borehole, so that the borehole bottom portion in the non-cemented alluvial layer as the object layer is inserted and fixed And to capture the slime in the borehole.

At this time, the insertion cone 31 is inserted into the slime collecting part 30 so that the slime collecting part 30 can be firmly inserted and fixed at the bottom of the borehole in the non-consolidated upper layer, An inner thread (not shown) is formed at the other end of the insertion cone 31 so as to be engaged with an outer thread of the slime collecting part 30. [

The filter unit 40 is a pipe-like structure having a certain aperture ratio (for example, about 20%). The filter unit 40 is coupled to the inner wall surface of the hollow wall holding unit 20, When the test water is supplied or injected into the hollow wall holding portion 20 in a state where the hollow wall holding portion 20 is located in the hydraulic test section a1 in the borehole, ), And the hydraulic test (evaluation of penetration ability) in the nonconsolidated alluvial layer made through the above-mentioned method.

Here, the filter unit 40 can smoothly maintain the flow (inflow, outflow) of the test water (or the ground water), while the gravel (e.g., sand, gravel, etc.) It is preferable to configure a double filter type so as to prevent the air from flowing into the inside of the hollow wall maintenance tube 24 through the cutout hole 20a.

As shown in FIGS. 2 to 5, a pneumatic holding device for a hydraulic test of an unconsolidated alluvial layer according to an embodiment of the present invention includes a casing 10 connected to an unshown drilling rig The borehole for the hydraulic test is pierced through the outer casing 10 to the unconsolidated alluvial layer, which is the object layer.

Next, the first to third rod bodies 21, 22, 23, the wall maintenance tube 24, the slime collecting part 30, and the insertion cone 31 are inserted through the inside of the outer casing 10, And the filter unit 40 are inserted to insert the slime collecting unit 30 into the bottom of the borehole through the insertion cone 31. The borehole maintenance body 24 is inserted into the borehole And placed in the repair test section (a1).

At this time, the outer casing 10 is moved to the upper end of the borehole through a drilling rig so that the outer casing 10 is located outside the first, second and third rod bodies 21, 22, Respectively.

The first and second rod bodies 22 and 23 and the first rod body 23 and the air wall holding tube 24 are connected to each other by a first ring structure The two sealing members 25 and 26 are not only closely contacted with the inner wall surface of the outer casing 10 but also formed with the second sealing member 26 together with the third rod body 23, (27), which is a metal ring structure provided at a coupling portion of the outer casing (10), is caught by a coupling protrusion (11) formed at one end of the outer casing (10) The air-wall position tube 24 is precisely positioned in the borehole repair test zone a1 to prevent the air wall in the repair test zone a1 from being collapsed.

Next, when test water (or ground water) for the hydraulic test is supplied or injected through the first rod body 21, the test water supplied or injected is supplied to the second and third rod bodies 22 and 23, The hollow wall holding tube 24, the slurry collecting unit 30, and the insertion cone 31, and maintains a certain water level.

At this time, the test water having a predetermined water level as described above may be passed through a cut-off hole (not shown) formed in the hollow wall maintenance tube 24 as well as a tubular-shaped filter portion 40 coupled to the inner wall surface of the hollow wall- 20a), and it is possible to test without error the amount of water permeability (flowability) in the non-cemented alluvial layer having low adhesion from the free flow of the test water, It is possible to precisely calculate the repair constant according to the result without error.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments.

10: outer casing 11:
20; A blank wall retaining portion 20a; Incision hole
21; A first rod body 22; The second rod tube
23; A third rod body 24; Retaining tube
24a; Stop chin 25; The first sealing material
26; A second sealing member 27; [0030]
30; A slime collecting unit 31; Insert cone
40; The filter unit

Claims (7)

An outer casing connected to the drilling equipment to form a borehole for a hydraulic test on the unconsolidated alluvial layer by the drilling equipment, and having a stopping jaw formed at one end thereof;
A hollow wall holding part for moving the water along the inner side of the outer casing to form a plurality of cutting holes as a tube to be supplied or injected with test water for a hydraulic test and to prevent a hollow wall from collapsing in a hydraulic test zone in the borehole;
A slime collecting part coupled to a lower end side of the hollow wall holding part and inserted and fixed in the bottom of the borehole in the unconsolidated uppermost layer; And
Wherein the slurry collecting part is formed in an inner wall surface of the hollow wall holding part and is inserted and fixed in the upper end of the slurry collecting part, A tubular type filter unit having a constant rate so that a water permeability test is performed in a nonconsolidated alluvial layer formed through a cutting hole; Wherein said at least one of said at least one of said at least two of said at least two at least two of said at least two of said at least one of said at least two of said at least one of said at least one of The apparatus according to claim 1,
A first rod body;
A second rod body coupled to the first rod body;
A third rod body coupled to the second rod body;
A porous wall tube coupled to the third rod body and having a plurality of cut-out holes formed at an outer periphery at regular intervals and coupled to the inner wall surface of the filter portion; Wherein said at least one of said at least one of said at least two of said at least two at least two of said at least two of said at least one of said at least two of said at least one of said at least one of 3. The method of claim 2,
And a stopping jaw for limiting an upper flow is formed at an inner upper end of the hollow wall maintenance tube so as to prevent the filter portion from being separated from the cutout hole formed at equal intervals when the filter portion is coupled to the inner wall surface. Air retaining device for alluvial repair tests. delete 3. The method of claim 2,
And a first seal member, which is in contact with the inner wall of the upper end of the outer casing for fixing the position while blocking the leakage of the test water supplied or injected into the second and third rod bodies,
A second seal member which contacts the inner wall surface of the lower end of the outer casing for fixing the position while blocking the leak of the test water supplied or injected into the joint portion of the third rod body and the air wall maintenance tube, And a retaining portion for retaining the jaw is engaged with the retaining portion. [6] The apparatus of claim 5, wherein the first and second sealing members are ring structures of a rubber material, and the engagement portions are ring structures of a metal material. The apparatus as claimed in claim 1, wherein the slurry collecting unit is configured to combine an insertion cone for inserting and fixing the borehole bottom in a non-cemented alluvial layer as a ground layer to be tested.

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