KR101210838B1 - Apparatus and method for measuring permeability of core samples using water - Google Patents

Abstract

PURPOSE: A device and a method using water for measuring the transmissivity of a specimen are provided to measure the long-term transmissivity of the specimen such as cement sealing rock constituting carbon dioxide underground storage strata or injection well saving supercritical carbon dioxide in the underground. CONSTITUTION: A device using water for measuring the transmissivity of a specimen comprises the specimen, a sleeve, a cell(100), an oven(120), a fluid pump, a pump, a first pressure measuring device(160), a second pressure measuring device, a pressurizing bolt, a valve, a fluid collecting unit(195), an electronic balance(190). The sleeve surrounds the specimen. The specimen is inserted into the cell and a fluid injection space is formed in the outer side of the sleeve. The fluid pump supplies a fluid to the cell. The pump supplies salty water to the specimen in the inside of the cell in the upstream of the cell. The first pressure measuring device measures the pressure of the cell in the upstream of the cell. The second pressure measuring device measures the pressure of the cell in the downstream of the cell. The pressurizing bolt pressurizes the specimen in the inside of the sleeve, thereby fixing the same. The valve measures the pressure of the salty passed through the cell, thereby controlling a flow of the salty water. The fluid collecting unit collects the salty water from the valve. The electronic balance measures the weight of the salty water collected in the fluid collecting unit.

Description

Apparatus and method for measuring the transmittance of a sample using water {APPARATUS AND METHOD FOR MEASURING PERMEABILITY OF CORE SAMPLES USING WATER}

The present invention relates to an apparatus for measuring water permeability and a method thereof, and more particularly, to an apparatus for measuring water permeability over a long period of time, in which a layer or rock containing carbon dioxide is stored underground, or a sealing material for preventing the outflow of carbon dioxide stored in the soil. It is about a method.

In connection with the recent increase in global environmental conservation, a method of underground storage of carbon dioxide emitted from various industries and the like has been devised.

In the underground storage of carbon dioxide, the site selection of the storage is also important, but the airtight technology that prevents underground stored carbon dioxide from leaking to the outside is also very important.

Under the high temperature and high pressure conditions, the carbon dioxide stored underground exists as supercritical carbon dioxide which is liquid in terms of density but gaseous in terms of viscosity.

The supercritical carbon dioxide is stored while filling the pores constituting the underground storage strata, or stored while being dissolved in the brine filling the pores of the underground storage strata, or stored by chemical reactions with the brine filling the pores of the underground storage strata. It is known.

At this time, it is known that the carbon dioxide in the supercritical state pressurizes the fluid which is present in the form of water, usually brine, while pressurizing the underground storage strata.

On the other hand, when the underground storage of carbon dioxide is terminated, that is, when the underground pressure of carbon dioxide stored in the underground storage reaches a saturation state, the injection well for carbon dioxide underground storage is sealed / closed.

At this time, in the injection well for underground storage of carbon dioxide pressure is generated by the carbon dioxide in the supercritical state, by this pressure, the pressure is transmitted to all directions of the underground storage strata, thereby cracking the carbon dioxide underground storage strata ( The possibility of outflow of carbon dioxide through cracks, etc. is generated, and thus the possibility of carbon dioxide outflowing to the upper part of the injection well for the underground storage, that is, the ground surface, becomes very high.

In order to more accurately grasp the behavior of supercritical carbon dioxide in the carbon dioxide underground storage strata, it was necessary to take a core sample that forms the carbon dioxide underground storage strata and accurately grasp the diffusion behavior of various substances in these core samples.

On the other hand, cement is currently used as a sealing material for sealing the injection well for underground storage of carbon dioxide.

The cement for sealing the injection well should be kept in a sealed state for a long time after the underground storage of carbon dioxide is finished, as described above, the injection well by means of supercritical carbon dioxide under high temperature and high pressure stored underground High temperature and high pressure are also applied to the sealing cement, and water pressurized by the pressure generated by the supercritical carbon dioxide under the high temperature and high pressure at this time. As described above, salt water also pressurizes the sealing cement. .

The prior art related to the present invention is Korean Patent No. 10-1118622 (2012.06.06. Notification).

It is an object of the present invention to provide an apparatus and method for measuring transmittance using water capable of measuring a long-term transmittance of a sample such as a rock forming a carbon dioxide underground storage layer or a cement sealing the carbon dioxide underground storage layer. It is done.

In order to solve the said subject, the transmittance | permeability measurement apparatus of the sample using water of this invention is a sample; A sleeve surrounding the sample; A cell into which a sample surrounded by the sleeve is inserted, and having a space in which fluid is injected outside the sleeve; An oven in which the cell is built; A fluid pump for supplying the fluid to the cell; A pump for supplying saline to the sample in the cell upstream of the cell; A first pressure gauge for measuring pressure in the cell upstream of the cell; A second pressure gauge for measuring pressure in the cell downstream of the cell; A pressure bolt for pressing and fixing the sample embedded in the sleeve; A valve connected to a downstream side of the cell and measuring the pressure of the brine passing through the cell to control the behavior of the brine; A fluid collector connected to the valve and collecting the brine from the valve; And an electronic scale for measuring the weight of the brine collected in the fluid collection unit.

Here, the sleeve is preferably made of stainless steel.

In addition, the apparatus for measuring the transmittance of a sample using water of the present invention may further include a flowmeter for measuring the flow rate of the gas flowing out of the fluid collection unit.

The apparatus may further include a pressure pump for adjusting the pressure of the fluid in the cell.

The apparatus may further include a fixed disk provided upstream and downstream of the sample.

It is preferable that the said fluid is oil.

Moreover, it is preferable that the said oil pressurizes the sleeve which surrounds the said sample in the said cell.

It is also particularly preferred that the oven is controlled by the temperature of the carbon dioxide underground reservoir.

In order to solve the above problems, the method for measuring the transmittance of a sample using water of the present invention, mounting the sample in the cell; Putting the cell into an oven; Pressurizing the cell with a fluid; Pressurizing the cell with brine; And measuring the flow rate of water to the sample by measuring the flow rate of the brine flowing out of the cell, wherein the water transmittance is characterized by the following equation.

[Mathematical Expression]

From here,

K = transmittance in mD, millidarcies

μ = viscosity (unit: cP, centipoise)

L = length of the sample in cm

A = cross-sectional area of the sample in cm ²

t = time in seconds

V = t Volume of fluid flowing for seconds (unit: cm ³ )

P ₁ = inlet pressure (absolute pressure)

P ₂ = outlet pressure (absolute pressure).

Herein, the fluid is preferably oil.

It is also particularly preferred that the oven is controlled by the temperature of the carbon dioxide underground reservoir.

The apparatus may further include a pressure pump for adjusting the pressure of the fluid in the cell.

According to the present invention, it is possible to simulate and measure the water permeation rate of cement over a long period of time as a sealing material for sealing an injection well storing underground rocks or supercritical carbon dioxide forming the carbon dioxide underground storage strata.

In addition, according to the present invention, it is possible to measure the absolute or relative transmittance of the water over a long period of time.

1 is a conceptual diagram schematically showing an apparatus for measuring the transmittance of a sample using water according to a preferred embodiment of the present invention.
FIG. 2 is an enlarged view showing in more detail a cell periphery of the transmittance measuring apparatus shown in FIG. 1.
3 is a flow chart schematically showing a method for measuring the transmittance of a sample using water according to a preferred embodiment of the present invention.

Advantages and features of the present invention, and methods of achieving the same will become apparent with reference to the embodiments described below in detail in conjunction with the accompanying drawings. It should be understood, however, that the invention is not limited to the disclosed embodiments, but is capable of many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, To fully disclose the scope of the invention to those skilled in the art, and the invention is only defined by the scope of the claims.

Like reference numerals refer to like elements throughout.

Hereinafter, an apparatus and a method of measuring transmittance of a sample using water according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

First, the sample referred to in the present invention is a rock or other stratum component which forms the injection strata for storing carbon dioxide underground, and a sample taken by using a core drill for permeability test or cement as a sealant for sealing a carbon dioxide injection well. Pointed to a sample taken a part of the core sample, in the case of cement, since it is difficult to extract after closing the injection well for storing carbon dioxide underground storage, in the present invention is prepared in advance to prepare a size suitable for use.

1 is a conceptual diagram schematically showing an apparatus for measuring a sample transmittance using water according to a preferred embodiment of the present invention.

Referring to FIG. 1, an apparatus for measuring transmittance of a sample using water according to a preferred embodiment of the present invention includes a cell 100, a sample 110, and an oven 120.

In addition, the cell 100 has a hand oil pump 130 for imparting a sealing pressure to the sample 110 in the cell 100 through appropriate piping, and the sealing pressure applied to the cell 100. The pressure device for adjusting the pressure, preferably the pressure pump 140, and the first pressure gauge 160 and the second pressure gauge 170 for measuring the pressure in the cell 100 is connected.

It should be remembered that the direction of water delivery in FIG. 1 runs from the left side to the right side of the drawing, so that the upstream side referred to herein refers to the left side in FIG. 1, and the downstream side points to the right side in FIG. 1.

In addition, although some of the drawings may be exaggerated in order to highlight specific aspects of the present invention, such exaggeration does not limit the scope of the present invention.

In addition, it will be appreciated that the various piping shown in the figures is used to supply pressure or fluid between components even if not mentioned otherwise.

The sample 110 is inserted into the cell 100.

At this time, it is preferable that the sample 110 is formed in a size suitable for insertion into the cell 100 as described above.

The cell 100 into which the sample 110 is inserted is located in the oven 120.

At this time, the oven 120 is for simulating a high temperature situation in the environment where the carbon dioxide is stored underground in a supercritical state.

The oven 120 inserts the cell 100 into which the sample 110 is inserted into the oven 120, and then, at a predetermined temperature, preferably, at a temperature similar to that of the ground to be simulated, or of the collected core sample. It can be set to underground temperature.

On the other hand, the first pressure gauge 160 measures the pressure applied to the sample 110 inside the cell 100 on the upstream side of the cell 100.

In addition, the second pressure measuring system 170 measures the pressure applied to the sample 110 inside the cell 100 on the downstream side of the cell 100.

In addition, the pressure pump 140 is for adjusting the sealing pressure applied to the cell 100, and reads the sealing pressure applied to the cell 100 by the third pressure measuring system 145, and the sealing pressure is equal to or less than the reference value. It acts to pressurize the oil so as not to.

For reference, the first sealing pressure applied to the cell 100 is given by the hand oil pump 130.

An upstream side of FIG. 1 is provided with an impedance measuring device 10 for measuring impedance due to pressure or temperature change applied to the sample 110 in the cell 100.

The impedance measuring apparatus 10 may further include an impedance measuring sensor (not shown) attached to the sample 110 in the cell 100.

Further, in addition to the above configuration, the upstream side of FIG. 1 contains a brine tank 50 for containing brine, a first control valve 42 for controlling the brine supply of the brine tank 50, and the first agent. 1 a brine syringe pump 60 for supplying the brine supplied through the control valve 42 at a constant pressure to a constant speed, a water tank 70 for containing water, and the brine tank 50 The second control valve 72 as a three-way valve for controlling the supply of brine and water from the water tank 70, and water and / or brine supplied through the second control valve 72 into the cell 100. A hydraulic cylinder 74 for supplying and a third control valve 76 for controlling the supply of the water and / or the brine are further included.

The combination of brine and water is for simulating both the presence of brine, the presence of water, or the simultaneous presence of brine and water in simulating the underground storage environment of carbon dioxide.

Hereinafter, even if described as brine, it should be understood to mean brine or water, or a combination (mixture) of brine and water.

Meanwhile, on the downstream side of FIG. 1, the second pressure measuring system 170 for measuring the downstream pressure applied to the sample 110 in the cell 100, the back pressure regulating valve or the reverse pressure regulating pressure at the downstream side of the cell 100. A valve (BPR) 180 called a pressure regulator, a fluid collector 195 for collecting the fluid flowing out of the valve 180, and an electronic scale for measuring an accurate weight of the fluid collector 195 ( 190, a flow meter 200, and the like are provided.

The valve 180 passes through the sample 110 inserted into the cell 100 on the upstream side of the cell 100 and exits the downstream side of the cell 100 (including saline and water). If exceeded, they are delivered to the fluid collection unit 195.

The fluid collector 195 collects the fluid (salt and water) that has flowed out through the valve 180, and the exact weight of these fluids flows out of the electronic scale 190 installed under the fluid collector 195. Weighing is measured by

The gas discharged from the fluid collection unit 195 passes through the flow meter 200 and the discharge amount thereof is measured.

The gas may be a gas contained in the sample, or may be a gas contained in brine or water for simulation.

FIG. 2 is an enlarged view illustrating in more detail the periphery of the cell 100 of the transmittance measuring apparatus shown in FIG. 1.

As can be seen in Figure 2, the apparatus for measuring the transmittance of the sample using water according to the present invention is inserted into the oven 120, the cell 100 included in the oven 120, and the cell 100 The sample 110 is included.

As described in FIG. 1, the transmittance measuring device according to the present invention is a first pressure measuring system for measuring the pressure of the salt water / water applied to the sample 110 on an upstream side of the cell 100 into which the sample 110 is inserted. 160 and a second pressure gauge 170 for measuring the salt / water pressure applied to the sample 110 on the downstream side of the cell 100 into which the sample 110 is inserted.

1, the brine tank 50 containing the brine for supplying the cell 100 is further connected to the upstream side of the cell 100 in which the sample 110 is inserted.

On the downstream side of the cell 100, a valve 180 for controlling the pressure of the brine and carbon dioxide flowing out by the pressure in the cell 100 on the downstream side of the cell 100 is connected.

Here, the sample 110 inserted into the cell 100 may be surrounded by a sleeve (106, 106 '; hereinafter 106) of the stainless material for the corrosion prevention and high pressure resistance.

Preferably, the sleeve 106 is in close contact with the sample 110 to seal the sample 110. The material of the sleeve 106 seals the sample 110 with the pressure from the upstream side. Sufficient material is enough.

The diameter of the sleeve 106 is preferably a diameter substantially the same as the diameter of the sample 110 inserted into the cell 100, the outer side of the sample 110 and the sleeve 106 is as close as possible, when the sealing pressure is applied, Particularly preferably, the sample 110 is completely compressed to prevent brine or the like from escaping between the sample 110 and the sleeve 106.

In addition, fixing disks 108 and 109 are inserted into the upstream and downstream sides of the sample 110 to prevent the sample 110 from being pushed out and to facilitate the installation of various pipes such as the salt water supply pipe. There may be.

The diameter of the fixed disks 108 and 109 is preferably the same as the diameter of the sample 110.

Here, the fixed disks 108 and 109 are most preferably in the form of porous disks, but if necessary, the fixed disk 108 is formed of a stainless steel material to withstand the corrosion caused by iron, more preferably salt water 109).

When using the fixed disks 108 and 109 made of stainless steel, it is particularly preferable that a plurality of holes are drilled for the transmission of brine and the passage of various pipes.

Seals (not shown) for sealing the left and right sides of the cell 100 on the upstream and downstream sides of the fixed disks 108 and 109, that is, the outer side of the sample 110 extending in the left and right directions of the sample 110. It is preferable that is formed.

Each of the seals includes a first pressure gauge 160 and a second pressure gauge 170, a brine supply tank 50 for supplying brine, a valve (BPR) 180, and the like (pipe) (not shown). It may be connected to the cell 100 through.

The pipe for impedance measuring sensor (not shown) connected to the impedance measuring apparatus 10 may be further passed through the tube.

The sealing body may be configured to be separably coupled to both the upstream side and the downstream side, but the upstream side is screw-coupled to be freely separable, and the downstream side is preferably fixed.

Alternatively, the upstream side seal may be fixed and the downstream side seal may be screwed to freely separate, but in the case of additionally including an impedance measuring sensor (not shown), the mounting of the sample 110 may be performed. It may be difficult to set separate or accurate impedance measurement locations.

On the outer side of the sleeve 106 surrounding the outer side of the sample 110, there is a space A formed between the inside of the cell 100, and in this space A, the hand oil pump of FIG. The oil supplied by the hand oil pump 130 is filled.

The oil is supplied by the hand oil pump 130 to provide a sealing pressure to the cell 100.

At this time, it is very preferable that the upstream side and the downstream side of the sleeve 106 are formed in a ⊂ and ⊃ shape in the space A so as to maintain and preserve the sealing pressure applied to the cell 100.

As described above, the sealing pressure is adjusted by the pressure pump 140, the adjustment is controlled by the third pressure gauge 145.

Here, the pressurizing pump 140 is a structure which can provide the pressure required for the transmittance | permeability measurement when a salt water permeates the sample 110 over a long period of time over a long period of time.

The cell 100 is formed with pressure bolts 102 and 104 which serve to additionally support and hold the sample 110 in the sleeve 106 outside the space A forming the sealing pressure.

The pressing bolts 102 and 104 serve to support the sample 110 and prevent the sample 110 from being pushed to the downstream side by the pressure supplied from the upstream side.

As mentioned above, after the description of the transmittance | permeability measurement apparatus of the sample using water of this invention, below, the method of the transmittance | permeability measurement apparatus of the sample using water is demonstrated.

3 is a flow chart schematically showing a method for measuring the transmittance of a sample using water according to a preferred embodiment of the present invention.

Referring to Figure 3, the method for measuring the transmittance of a sample using water of the present invention, the large step, the step of mounting the sample in the cell (S310), the step of putting the cell into the oven (S320), the cell is charged with brine It includes the step (S330), and measuring the transmittance (S340).

First, the step (S310) of mounting the sample in the cell, preparing the sample 110 formed to fit the diameter of the sleeve 106 and the length of the cell 100 in advance, and one side of the seal (not shown) and / Alternatively, both sides are opened, and the sample 110 is inserted into the sleeve 106.

As mentioned above, it is preferable that the sealing body (not shown) open only one of them rather than opening both the upstream and downstream sides.

After the sample 110 is mounted on the cell 100, the upstream side and the downstream side of the cell 100 are completely sealed using a sealant (not shown).

In this case, optionally, the first pressure gauge 160, the second pressure gauge 170, the valve BPR 180, and an impedance measurement sensor (not shown) may be connected.

Next, the step (S320) of injecting the cell into the oven is a step of injecting the cell 100 into which the sample 110 is inserted into the oven 120.

Subsequently, as described above, the hand oil pump 130 is used to fill the space A surrounding the sleeve 106 outside the sample 110 to provide the initial sealing pressure.

In addition, in the step S320 of injecting the cell into the oven, the cell 100 is put into the oven 120, and then the temperature of the oven 120 is set to a temperature similar to that of the place where carbon dioxide is stored underground. By doing so, the CO2 underground storage environment can be simulated.

Next, in step S330, the cell is pressurized and charged with brine by opening a first control valve 42 connected to the brine tank 50 and controlling the brine supply. do.

At this time, the brine is filled into the cell 100 through the brine syringe pump 60 attached to the brine tank 50, optionally mixed with water in the water tank 70 through the second control valve 72. May be

More preferably, brine, water, or a mixture of brine and water is pressurized and supplied to the cell 100 by the hydraulic cylinder 74.

Here, the threaded upstream seal (not shown) is configured to be movable from upstream to downstream by pressurization of the brine, water, or the brine and water mixture pressurized and supplied by the hydraulic cylinder 74. May be

In this case, in consideration of the movement of the upstream sealing body (not shown) to the downstream side, it is preferable to give a slight margin to the pipe connecting portion so that the connecting portion does not become excessive even when the upstream sealing body (not shown) moves.

Preferably, the movement of the upstream side sealing body (not shown) to the downstream side may be moved to the solenoid valve so as to be moved based on the pressure value of the first pressure measuring system 160 indicating the pressure of the brine to be pressurized. It may also be operated by.

Therefore, the pressure of the brine applied to the sample 110 in the cell 100 can be adjusted more accurately.

More preferably, the supply of brine may be adjusted to be supplied at a constant pressure in accordance with the pressure value of the second pressure gauge 170 indicating the downstream pressure of the sample 110 in the cell 100.

Here, the pressure pump 140 and the third pressure gauge 145 are preferably configured to continuously correct the pressure drop due to the brine passing through the sample 110 and exiting the downstream side of the cell 100.

Next, in step (S340) of measuring the transmittance, the brine introduced by pressurization from the upstream side of the cell 100 passes through the sample 110 and then flows out of the brine to the downstream side of the cell 100. At 195, the precise weight of the collected brine is measured by the electronic scale 190, and the amount of other gas that has exited the fluid collection unit 195 is measured by the flow meter 200. .

Some but other gases may be dissolved in the brine.

By continuously measuring the exact weight of the brine collected by the fluid collection unit 195 in the electronic balance 190 it is possible to measure the transmittance of the brine passing through the sample (110).

In addition, when the amount of other gas exiting the fluid collection unit 195 is measured by the flow meter 200, the transmittance of the other gas that has passed through the sample 110 may be measured. However, in the present invention, since the amount of other gases is negligibly small, it should be understood that the measurement of the transmittance of other gases does not have much meaning.

At this time, the transmittance of the brine can be measured by the following equation.

[Mathematical Expression]

From here,

K = transmittance in mD, millidarcies

μ = viscosity (unit: cP, centipoise)

L = length of the sample in cm

A = cross-sectional area of the sample in cm ²

t = time in seconds

V = t Volume of fluid flowing for seconds (unit: cm ³ )

P ₁ = inlet pressure (absolute pressure)

P ₂ = outlet pressure (absolute pressure).

As described above, since the transmittance measurement of the sample using water can be performed over a long period of time, the present invention can be applied to both the absolute transmittance test and the relative transmittance test of water.

In this case, the absolute transmittance test of water may be defined as a transmittance test value for each test, and the relative transmittance test of water may be defined as a ratio of a previous transmittance test value and a current transmittance test value. Alternatively, the relative transmittance test may be defined based on the initial transmittance test value and defined as a ratio with the water transmittance test value for each experiment.

As mentioned above, although the apparatus and method for measuring the transmittance of a sample using water according to a preferred embodiment of the present invention have been described as examples, such description is merely illustrative, and common knowledge in the technical field to which the present invention pertains. Those skilled in the art will understand from the above description that the present invention can be variously modified or implemented in accordance with the present invention.

10: impedance measuring device 42: first control valve
50: brine tank 60: brine syringe pump
70: water tank 72: second control valve
74: hydraulic cylinder 76: third control valve
100: cell 102, 104: pressurization bolt
106 (106 '): sleeve 108, 109: fixed disk
110: sample 120: oven
130: hand oil pump 140: pressure pump
160: the first pressure measuring system 170: the second pressure measuring system
180: valve (BPR) 190: electronic balance
195: fluid collector 200: flow meter
S310: mounting the sample on the cell
S320: step of putting the cell into the oven
S330: pressurizing the cell with brine
S340: measuring the water transmittance

Claims (12)

sample;
A sleeve surrounding the sample;
A cell into which a sample surrounded by the sleeve is inserted, and having a space in which fluid is injected outside the sleeve;
An oven in which the cell is built;
A fluid pump for supplying the fluid to the cell;
A pump for supplying saline to the sample in the cell upstream of the cell;
A first pressure gauge for measuring pressure in the cell upstream of the cell;
A second pressure gauge for measuring pressure in the cell downstream of the cell;
A pressure bolt for pressing and fixing the sample embedded in the sleeve;
A valve connected to a downstream side of the cell and measuring the pressure of the brine passing through the cell to control the behavior of the brine;
A fluid collector connected to the valve and collecting the brine from the valve;
An electronic scale for measuring the weight of the brine collected in the fluid collection unit;
≪ / RTI >
Device for measuring the transmittance of a sample using water.
The method of claim 1,
The sleeve,
Characterized in that the material is stainless steel,
Device for measuring the transmittance of a sample using water.
The method of claim 1,
Further comprising a flow meter for measuring the flow rate of the gas flowing out of the fluid collector,
Device for measuring the transmittance of a sample using water.
The method of claim 1,
Further comprising a pressure pump for regulating the pressure of the fluid in the cell,
Device for measuring the transmittance of a sample using water.
The method of claim 1,
Characterized in that it further comprises a fixed disk provided upstream and downstream of the sample,
Device for measuring the transmittance of a sample using water.
The method of claim 4, wherein
The fluid is,
It is an oil,
Device for measuring the transmittance of a sample using water.
The method according to claim 6,
The oil,
It is characterized by pressing the sleeve surrounding the sample in the cell,
Device for measuring the transmittance of a sample using water.
The method of claim 1,
Characterized in that the oven is controlled by the temperature of the carbon dioxide underground reservoir,
Device for measuring the transmittance of a sample using water.
Mounting a sample in the cell;
Putting the cell into an oven;
Pressurizing the cell with a fluid;
Pressurizing the cell with brine;
Measuring the permeability of water to the sample by measuring the flow rate of the brine flowing out of the cell,
The transmittance of the water,
It is characterized by the following formula,
Method of measuring the transmittance of a sample using water.

[Mathematical Expression]

From here,
K = transmittance in mD, millidarcies
μ = viscosity (unit: cP, centipoise)
L = length of the sample in cm
A = cross-sectional area of the sample in cm ²
t = time in seconds
V = t Volume of fluid flowing for seconds (unit: cm ³ )
P ₁ = inlet pressure (absolute pressure)
P ₂ = outlet pressure (absolute pressure).
The method of claim 9,
The fluid is characterized in that the oil,
Method of measuring the transmittance of a sample using water.
The method of claim 9,
Characterized in that the oven is controlled by the temperature of the carbon dioxide underground reservoir,
Method of measuring the transmittance of a sample using water.
The method of claim 9,
Further comprising a pressure pump for regulating the pressure of the fluid in the cell,
Method of measuring the transmittance of a sample using water.

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