KR101271474B1 - Supporter for squeezer cell - Google Patents

Abstract

PURPOSE: A supporter for a squeezer cell for collecting pore water is provided to easily position a squeezer cell on a straight line with a pressing body even though the vessel is shaken. CONSTITUTION: A supporter for a squeezer cell(2) for collecting pore water comprises a bottom surface(100), a cell seating face(20), a side contact surface(30), a scanner seating unit(40), and a scanner fixing member(50). The bottom surface can be seated on a table. The cell seating surface is formed at a position spaced upwardly from the bottom, and the squeezer cell is seated on the bottom surface. The side contact surface is extended upwardly from an edge portion of the cell seating surface and extended along a circumference corresponding to an external side wall shape of the squeezer cell, thereby being in contact with the lateral surface of the squeezer cell. A scanner(3) connected to a pore water outlet(2a) of the squeezer cell seated on the cell seating surface is seated on the scanner seating unit. The scanner fixing member fixes the scanner to prevent the movement of the scanner connected to the pore water outlet while the scanner is positioned in the scanner seating unit.

Description

Stand for squeezer cell to collect pore water {SUPPORTER FOR SQUEEZER CELL}

The present invention relates to a squeezer related apparatus, which is an equipment for obtaining pore water from a subsea deposit sample obtained through a subsea deposit drilling operation.

Ocean exploration is underway for the purpose of finding resources on the seabed such as oil, natural gas and gas hydrate.

In general, the marine exploration method uses a seismic probe or an unmanned submersible to first investigate exploration of the existence of seabed resources such as petroleum, natural gas, and gas hydrate.

The seismic wave detection method shows that the rate of transfer of the seismic wave of pure gas hydrate is faster than that of the sediment layer. The sediment layer containing gas hydrate is faster than the sediment layer containing no gas hydrate, and the seismic cross section shows seismic chimney. Chimney is an exploration method based on the presence of gas hydrates and the like on top thereof.

The unmanned submersible exploration method is an exploration method that detects the presence of gas hydrates by measuring the concentration of methane gas by inserting a probe into the sea bottom because methane gas is released when gas hydrates are present on the sea bottom.

When it is determined that there is a seabed resource such as gas hydrate through the seismic detection method or unmanned submersible exploration method as described above, by directly drilling down the drilling device to the bottom surface of the corresponding point to check whether there is no seabed resources.

Korean Patent Registration No. 10-0978143 discloses the structure of a seabed sediment drilling device.

Thus, various kinds of data are obtained by analyzing the sea sediments that have been drilled. There is a process of obtaining pore water (moisture contained in the sea sediments) from the sea sediments.

Korean Patent Application No. 10-2007-0028038 discloses a technique for collecting pore water contained in a seabed sediment.

The main equipment used in this process is a squeezer.

The squeezer is a structure in which the bottom sediment is filled in a container-type squeezer cell in which a drain hole is perforated at the bottom, and the sea sediment filled in the squeezer cell is pressurized to discharge the pore water contained in the rotary sediment through the drain.

By the way, pore water collection using a squeezer is often performed in a marine vessel.

In order to facilitate the collection of pore water using a squeezer, the pressurized body and the squeezer cell should be positioned in a straight line.

However, the marine vessels had a lot of difficulties in keeping the squeezer cell and the pressurizer in a straight line because of the ripple caused by the waves.

Korea Patent Registration No. 10-1048528 Korean Patent Application No. 10-2007-0028038

The present invention is to solve the above problems, and more particularly, to provide a squeezer cell pedestal for pore water collection to facilitate the squeezer pressurizer and squeezer cell in a straight line even in marine vessels. have.

It is also intended to facilitate connecting the syringes so that the pore water discharged from the squeezer cell naturally flows into the syringe.

In the present invention, the bottom surface of the squeegee cell is formed to draw a circumference corresponding to the outer sidewall shape of the squeezer cell and the flat cell settled surface forms a form having a side contact surface where the sidewall of the squeezer cell has a predetermined height. By providing the base for the squeezer cell, it is easy to ensure that the pressurizing body of the squeezer and the squeezer cell are located in a straight line.

In addition, the syringe can be connected to the pore water outlet of the squeezer cell, but the syringe fixing means is provided to prevent the release of the syringe due to the pressure generated during the pore water collection process.

The pedestal for squeezer cells of the present invention has a bottom surface that can be placed on a table.

In addition, it has a flat cell settled surface formed at a position spaced from the bottom surface to the top to allow the squeezer cell for filling the sea sediment.

In addition, it has a shape extending upward from the edge portion of the cell settle surface, and has a lateral contact surface extending in a circumference corresponding to the outer side shape of the squeezer cell to contact the side of the squeezer cell.

Moreover, it is fixed to the lower part of the press body of a squeezer, but is fixed to the position which becomes in line with the press body of a squeezer.

The base for the squeezer cell of the present invention is formed by drawing a circumferential surface corresponding to the outer sidewall shape of the squeezer cell and the flat cell settled surface where the bottom surface of the squeezer cell is formed so that the squeezer cell has a side contact surface where the side contacts. When the base for the squeezer cell of the present invention is fixed in line with the pressurizing body, the squeezer cell can be easily positioned in line with the pressurizing body of the squeezer even in a ship with shaking.

In addition, there is further provided with a syringe fixing means for fixing the syringe so as not to move the syringe connected to the pore water outlet in a state in which the syringe connected to the pore water outlet of the squeezer cell placed on the cell settle is placed and the syringe settled portion is not moved. If it is, the pressure generated during the pore water collection process is characterized in that the connection of the syringe is prevented from being released, and the pore water can be easily introduced into the syringe.

In addition, when a filter is disposed between the syringe and the pore water outlet of the squeezer cell, there is an effect of preventing foreign matter from being included in the pore water filled in the syringe.

In addition, the side contact surface has an intact cylindrical shape or a cylindrical shape in which some points are opened, and the inner surface of the upper portion into which the squeezer cell is inserted forms an inclined surface so that the diameter thereof becomes narrower toward the lower side, and the squall slides along the inclined surface. If the position is set to descend while descending, there is a feature that it is easy to accurately position the squeezer cell in the set position even if the wave is high due to the high wave.

1 is a schematic view for explaining the state of use of the squeezer cell pedestal for collecting the pore water of the present invention
Figure 2 is a schematic diagram for explaining the squeezer cell pedestal for collecting the pore water of the present invention shown in Figure 1
A: exploded perspective view
B: section
3 and 3 are schematic views for explaining that the side wall forming surface is a semi-cylindrical structure

Hereinafter, the technical idea of the present invention will be described more specifically with reference to the accompanying drawings.

It is to be understood, however, that the appended drawings illustrate only typical embodiments of the present invention and are not to be considered as limiting the scope of the invention.

The present invention relates to a squeezer-related apparatus used to collect pore water from a seabed sediment, and more particularly, to ensure that the pressurizer 1 and the squeezer cell 2 of the squeezer are in a straight line even in a marine vessel with shaking. It is to provide a squeegee cell pedestal 100 for pore water collection to facilitate.

That is, in the process of collecting the pore water through the squeezer, the seawater deposit is put into the squeezer cell 2 and the pressure body 1 is lowered to allow the pressurizer 1 to pressurize the seawater deposit in the squeezer cell 2. It is to be discharged through the pore water outlet (2a) located in the lower portion of the squeezer cell (2).

In order to perform this pore-water collection process intact, it is necessary to position the squeezer cell 2 filled with the sea sediment in the lower part of the press body, and to exactly line the press body 1.

By the way, the marine vessels were shaken due to the waves, it was difficult to accurately position the squeezer cell (2) in the set position.

The squeezer cell pedestal 100 of the present invention for solving such a problem has a bottom surface 10 that can be placed on a table.

In addition, it has a flat cell settled surface 20 which is formed at a position spaced upwardly from the bottom surface 10 to seat the squeezer cell 2 for filling the sea sediment.

In addition, the side contact surface 30 forms a shape extending upward from the edge portion of the cell settlement surface 20 and extends in a circumference corresponding to the outer sidewall shape of the squeezer cell 2 so that the side surfaces of the squeezer cell 2 come into contact with each other. Has

The base 100 for the squeezer cell of the present invention is fixed to the lower portion of the pressurizer 1 of the squeezer, but is fixed to a position in line with the pressurizer 1 of the squeezer.

That is, the positioning of the squash (setting to a position located in line with the pressurizer 1 of the squeezer) can be achieved only by placing the squeezer cell 2 in the base 100 for the squeezer cell of the present invention. (If the bottom surface 10 and the side of the squeezer cell 2 is in contact with the cell settlement surface 20 and the side contact surface 30, positioning is completed.)

Therefore, even if the marine vessel is shaken, it is easy to position the squeezer cell 2 in line with the press body 1.

The side contact surface 30 may be embodied in various forms such as a cylindrical shape corresponding to both sides of the squeezer cell 2 or a semi-cylindrical shape corresponding to only a part of the side surface.

However, it is desirable to implement an intact cylindrical shape.

Of course, it is also effective to form a cylindrical shape that is not an intact cylindrical shape but a part of the lateral opening is open, that is, a cylindrical shape as a whole.

In this structure, the inner surface of the upper end portion into which the squeezer cell 2 is inserted forms an inclined surface 31 such that the diameter thereof becomes narrower toward the lower side, so that the squeezer cell 2 slides down along the inclined surface 31 to be lowered and positioned. Can be implemented to be set.

Such a structure is characterized in that the squeezer cell 2 can be positioned very precisely at a set position, but its operation is very easy.

In particular, it is easy to accurately position the squeezer cell 2 at a set position even when the ship is shaken largely due to the high wave.

In addition, when the squeezer cell 2 is inserted into the space formed by the side contact surface 30, the smaller the gap between the outer surface of the squeezer cell 2 and the space, the better the holding force of the squeezer cell 2 is.

In the case where the side contact surface 30 does not form an intact cylindrical shape as shown in FIG. 3, the cylindrical shape is cut in half, and the squeezer cell 2 is removed even when the squeezer cell 2 is placed in the set position, the squeegee is removed. The position of the squeezer cell 2 can be changed by moving the low cell 2 (at least two points in contact with the side contact surface 30 (including a point in contact with the bottom surface 10 at least) Is more than 4 points), the positioning of the squeezer cell 2 is relatively accurate.)

In the present invention, the pore water discharged to the pore water outlet 2a of the squeezer cell 2 naturally flows into the syringe 3, so that the continuity of the work may be excellent.

To this end, it may be further provided with a syringe seat portion 40, the syringe (3) is connected to the pore water discharge port (2a) of the squeezer cell (2) is placed on the cell seat surface 20 is placed.

In this case, simply connecting the syringe 3 may cause a situation in which the pore water does not flow smoothly into the syringe 3.

Specifically, a phenomenon in which the connection state of the syringe 3 is released due to the pressure in the pressurizing body 1 of the squeegee pressurizes the squeezer cell 2 may occur.

In order to prevent such a problem may be further provided with a syringe fixing means 50 for fixing the syringe 3 so that the syringe (3) connected to the pore water outlet (2a) in a state positioned in the syringe seat portion 40 does not move. .

The syringe fixing means 50 may be implemented in various forms such as a clamp form used for fixing an object in various industrial fields.

Specifically, a form having a pressurizing body 51 for pressurizing the syringe 3 and a pressurizing force control means for generating a pressing force so that the pressing body 51 pressurizes the syringe 3 or preventing the pressing force from occurring. Can be implemented as:

The pressing force control means is fastened to a fixed portion as shown in the accompanying drawings, it can be implemented in the form of a bolt 52 and the like to press the syringe pressing body 51 by a fastening force.

Moreover, it can also be implemented by the method of using magnetic force or frictional force (such as a wedge method).

In the present invention, between the syringe 3 and the pore water outlet 2a of the squeezer cell 2 can be implemented so that the filter 60 for filtering foreign matter is located.

In this case, foreign matters can be prevented from being included in the pore water filled in the syringe 3.

1.Pressurized body
2. Squeezer Cell
2a. Pore water outlet
3. Syringe
10. Bottom surface
20. Cell
30. Side contact surface
31. Slope
40. Syringe Settlement
50. Syringe fixing means
51. Syringe Pressurized Body
52. Bolt
60. Filter
100. Squeegee Base

Claims (5)

delete In the squeezer related apparatus used to extract the pore water from the sea sediment,
A bottom surface 10 seated on the table;
A flat cell settlement surface 20 formed at a position spaced upwardly from the bottom surface 10 so as to settle the squeezer cell 2 for filling the sea sediment;
A side contact surface 30 which forms a shape extending upward from an edge portion of the cell receiving surface 20 and extends in a circumference corresponding to the outer sidewall shape of the squeezer cell 2 so that the side surfaces of the squeezer cell 2 come into contact with each other. ;
A syringe seat portion 40 in which a syringe 3 connected to the pore water outlet 2a of the squeezer cell 2 placed on the cell seat surface 20 is placed;
And a syringe fixing means (50) for fixing the syringe (3) so that the syringe (3) connected to the pore water outlet (2a) is not moved while being positioned in the syringe set portion (40).
A squeezer cell pedestal for collecting pore water, which is fixed to a lower portion of the squeezer's pressurizer (1) and fixed to a position in line with the pressurizer (1) of the squeezer.
The method of claim 2,
Between the syringe (3) and the pore water outlet (2a) of the squeezer cell (2a) is a filter 60 for filtering foreign matter is located, the pedestal for squeezer cell for pore water collection.
The method of claim 2,
The syringe holding means (50) is a syringe pressing body (51) for pressing the syringe (3); And
And a pressing force control means for generating a pressing force so that the syringe pressing body (51) pressurizes the syringe (3) or preventing the pressing force from being generated.
4. The method according to claim 2 or 3,
The side contact surface 30 has a cylindrical shape of an intact shape or a portion of the open cylindrical,
The inner surface of the upper end portion into which the squeezer cell 2 is inserted forms an inclined surface 31 such that the diameter thereof becomes narrower toward the lower side thereof, so that the squall cell slides down along the inclined surface 31 and descends to set its position. Base for squeezer cell for harvesting.

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