KR101728734B1 - pretreatment method for measurement on degradation of polymer for enhanced oil recovery and method thereof - Google Patents

Abstract

The present invention relates to a pretreatment method of measuring a decomposition rate of a polymer for enhanced oil recovery, capable of simulating a reservoir environment with low oxygen atmosphere when measuring a decomposition rate of a polymer for an oil recovery enhancing method in order to improve an accuracy of measurement through a reduction of dissolved oxygen in a sample. The method comprises: a first step of selecting an analysis target polymer and a mixing concentration, but preparing a measurement target solution by injecting and mixing the polymer, selected in a globe box filled with inert gas, into a solvent of which sodium chloride content is controlled to be matched with an analysis target reservoir; a second step of measuring an initial state value of the measurement target solution, but stacking a sealing oil film on an upper surface of the measurement target solution by sequentially injecting the prepared measurement target solution and sealing oil, which is selected to have a lower gravity than the measurement target solution, into a storage container; and a third step of sealing the upper part of the storage container and then withdrawing the container from the globe box, but aging the container at a temperature corresponding to the reservoir.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pretreatment method for measuring the decomposition rate of a polymer for improving petroleum recovery and a method for measuring decomposition rate of a polymer for promoting recovery of petroleum,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pretreatment method for measuring the decomposition rate of a polymer for improving petroleum recovery and a method for measuring the decomposition rate of a polymer for improving petroleum recovery, And a method for measuring the decomposition rate of a polymer for improving the recovery of oil.

In general, petroleum is present in pores of deep reservoirs, and drilling of reservoirs can provide a way for petroleum to reach primary production through natural energy, such as the pressure in the reservoir and the expansion properties of the oil primary recovery).

On the other hand, the above-mentioned natural energy is gradually reduced according to the production of petroleum, so that even though the remaining oil exists in the reservoir, it can not be produced. In this first production, only 10-20% of the reservoir oil can be produced .

In this case, the replacement of the reduced natural energy and injection of water into the injection wells results in secondary recovery of petroleum in the reservoir, and water flood in which the water is injected into the reservoir has a low viscosity And 20% to 30% of production of petroleum by fingering.

Polymer flooding, one of the enhanced oil recovery methods, is an alternative to the hydraulic method, in which a high viscosity polymer solution is injected into the reservoir to increase the recovery of petroleum.

At this time, hydrolyzed polyacrylamide (HPAM) is most widely used as a polymer because of its low cost, high solubility and high viscosity. Such a polymer has a problem in that when it receives heat in a solution state in which various substances are dissolved, the viscosity retention ability is deteriorated through thermal / chemical decomposition.

Therefore, it is essential to measure the thermal / chemical degradation rate of the polymer in order to design the polymer injection method.

At this time, the decomposition rate of the polymer is greatly influenced by the dissolved amount of oxygen ions, but oxygen ions hardly exist under the conditions of the reservoir layer. Therefore, in the conventional method of measuring the degradation rate, which is performed under a solution condition in which oxygen ions are dissolved, there is a problem that the decomposition rate of the polymer in the reservoir layer can not be accurately predicted.

Conventionally, a method of sealing a mixed solution in a sealed container and sealing it through a firearm is used for minimizing the reaction between the oxygen ion and the polymer mixed solution. However, not only the risk of safety accident caused by the fire was high, There is a problem that the sealed container permeates into the mixed solution and the accuracy of the measurement result is lowered.

Korean Patent No. 10-1450528

In order to solve the above problems, the present invention provides a pretreatment method for measuring the decomposition rate of a polymer for improving the recovery of oil, which improves the measurement accuracy through reduction of dissolved oxygen in the sample, and a method for measuring the decomposition rate of the polymer for improving the recovery of oil The problem is solved.

In order to solve the above problems, the present invention provides a pretreatment method for measuring the decomposition rate of a petroleum recovery promoting polymer in which a reservoir environment of a low-oxygen atmosphere is simulated in measuring a decomposition rate of a polymer used in a petroleum recovery enhancement method, A first step of preparing a solution to be measured by injecting and mixing at a selected concentration of the mixture in a solvent having a sodium chloride content adjusted so that the selected polymer corresponds to the reservoir to be analyzed in a glove box filled with an inert gas, ; Wherein the initial state value of the measurement target solution is measured and the hermetic oil selected to have a specific gravity lower than the specific gravity of the prepared measurement target solution and the measurement target solution is sequentially injected into the storage container to form a sealed oil film on the upper surface of the measurement target solution A second step of forming a laminate; And a third step in which the upper end of the storage container is sealed and withdrawn from the glove box, wherein the drawn storage container is subjected to aging treatment at a temperature corresponding to the storage layer, and a pretreatment method for measuring the decomposition rate of the oil recovery promoting polymer .

Also, in the method for measuring the decomposition rate of a polymer for improving oil recovery, in which a reservoir environment of a low-oxygen atmosphere is simulated in measuring the decomposition rate of the polymer used in the petroleum recovery enhancement method, the polymer to be analyzed and the concentration of the mixture are selected, A first step in which the selected polymer is mixed with the selected concentration of the polymer in a box to prepare a solution to be measured; A second step of measuring a first viscosity of an initial state of the solution to be measured and storing the prepared solution to be measured in a storage container; A third step in which the upper end of the storage container is sealed and drawn out from the glove box, and the drawn storage container is aged to a temperature corresponding to the analysis target storage layer; And a fourth step of measuring a second viscosity of the aging-treated solution to be measured to calculate a decomposition rate of the polymer solution.

Through the above solution, the present invention provides the following effects.

First, since the measurement target solution prepared in the inert gas atmosphere is injected into the storage container together with the hermetic oil, a low dissolved oxygen amount of 5 ppb or less can be maintained and it can be simulated similar to the reservoir environment in a low oxygen atmosphere. The decomposition rate of the polymer, which is an essential design parameter of the polymer, can be accurately and economically calculated.

Secondly, since the sealing oil with low specific gravity floats on the upper surface of the solution to be measured and forms a gas-impermeable sealed oil film on a single surface covering the cross-sectional area of the storage container, oxygen The contact of ions can be stably interrupted.

Thirdly, since the sealed oil film is provided in a fluid state, oxygen ions can be stably blocked even when the volume of the solution to be measured changes, so that the cost for maintaining the inert gas atmosphere in the aging treatment for a long period of time can be reduced, The economic efficiency of the process can be improved.

Fourth, since the dissolved oxygen amount of the solution to be measured can be measured even in a glove box of a negative pressure which can not use a general dissolved oxygen measuring device through the ampoule type dissolved oxygen measuring kit, the measurement error of the decomposition rate due to dissolved oxygen can be reduced.

1 is a flow chart showing a method for measuring the decomposition rate of a polymer for improving oil recovery according to an embodiment of the present invention.
BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a method for measuring the decomposition rate of a polymer for improving oil recovery,
3 is a view illustrating a mixing process of a polymer and a solvent in a method of measuring the decomposition rate of a polymer for improving petroleum recovery according to an embodiment of the present invention.
4 is a view showing an example of a solution to be measured and a sealed oil film contained in a storage container in the method of measuring the decomposition rate of the polymer for improving oil recovery according to an embodiment of the present invention.
FIG. 5 is a graph showing dissolved oxygen amount of a measurement target solution according to an aging period in a method of measuring decomposition rate of a polymer for improving petroleum recovery according to an embodiment of the present invention. FIG.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, a pretreatment method for measuring the decomposition rate of a polymer for improving oil recovery and a method for measuring a decomposition rate of a polymer for improving oil recovery according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a flowchart illustrating a method of measuring the decomposition rate of a polymer for improving the recovery of oil according to an embodiment of the present invention. FIG. 2 is a view showing a method of measuring the decomposition rate of a polymer for improving oil recovery, FIG. 3 is a view illustrating a process of mixing a polymer and a solvent in a method of measuring the decomposition rate of a polymer for improving oil recovery according to an embodiment of the present invention. FIG. 4 is a cross- FIG. 5 is a graph showing an example of a measurement target solution and a sealed oil film stored in a storage container in a method of measuring the decomposition rate of a polymer for improving the recovery of oil. And the amount of dissolved oxygen in the solution to be measured is shown in FIG.

Here, the polymer is preferably a high molecular substance such as HPAM (hydrolyzed polyacrylamide) used in a petroleum recovery promotion method, and is understood as a concept encompassing a material having a physical property to form a viscosity upon mixing with a solvent.

At this time, in the oil recovery enhancement method such as the polymer injection method, the mixed solution of the polymer and the solvent is injected into the reservoir layer, and the production amount of the oil can be increased when the mixed solution injected into the reservoir maintains a higher viscosity than the petroleum.

That is, when the mixed solution maintains a viscosity higher than that of petroleum, it can be uniformly dispersed and injected into the medium of the reservoir without viscous fingering to increase the production amount of petroleum. At this time, the phenomenon of viscous resin phenomenon means that pure water or brine can not spread in the medium of the reservoir due to low viscosity and flows only to a specific channel.

On the other hand, since the polymer can be decomposed thermally or chemically, the viscosity of the polymer can be degraded. Therefore, the polymer thermal / chemical decomposition ratio under the environmental conditions of the reservoir during the design of the oil recovery enhancement method, The rate of change of viscosity of the mixed solution is the main variable.

Since the oxygen present in the atmosphere has a great influence on the decomposition rate of the polymer, the following is a method for measuring the decomposition rate of the polymer, which provides a measurement condition similar to that of the reservoir environment in a low oxygen atmosphere so that measurement errors due to oxygen present in the atmosphere are reduced. A preprocessing method and a decomposition rate measuring method using the same will be described in detail.

As shown in FIGS. 1 to 5, the method for measuring the decomposition rate of the polymer for improving the recovery of oil according to the preferred embodiment of the present invention includes the steps of pre-processing (s10, s20, s30, s40) .

Here, the preprocessing process (s10, s20, s30, s40) of the polymer is a process of preparing a mixed solution for the polymer to be analyzed, that is, a solution to be measured, and aging the preliminarily prepared solution under environmental conditions in which the reservoir is simulated .

The decomposition rate calculation step (s50) of the polymer refers to a process of calculating a substantial decomposition rate by comparing the first viscosity of the initial measurement target solution with the second viscosity of the measurement target solution after the aging treatment.

First, referring to FIGS. 1 and 2, the polymer 1b to be analyzed and the mixed concentration are selected (s10). That is, the polymer to be applied to the oil recovery improvement method is selected, and the concentration of the polymer is selected according to the analysis purpose.

Here, the polymer may be selected as a material which is mixed with a solvent to increase the production amount of petroleum to form an appropriate viscosity, and which is low in production cost and easy to be mixed with a solvent. The mixing concentration of the polymer may be selected in consideration of the viscosity change rate upon mixing of the solvent, the viscosity characteristics of the oil embedded in the analysis target storage layer, and the like. Of course, the polymer and the mixed concentration can be arbitrarily adjusted corresponding to various design parameters of the oil recovery enhancement method.

When the polymer to be analyzed and the mixed concentration are selected, the selected polymer 1b is mixed with the selected concentration of the polymer 1b in the glove box 10 filled with the inert gas 3, (s10).

In detail, the glove box 10 is a device for preventing contamination during handling of materials sensitive to moisture, oxygen, carbon dioxide, etc., and includes a body having a work space 11 formed therein, a transfer path 10 communicating with the work space 11, , And a purifier for removing water and oxygen from the work space (11).

At this time, the transfer path is provided with a vacuum valve for removing foreign substances, moisture, oxygen and the like by vacuum, and a filling valve for filling inert gas, and in the operation state of the vacuum valve and the filling valve, Lt; / RTI >

That is, when the vacuum valve and the filling valve are operated with the inert gas 3 such as nitrogen, argon or the like filled in the body, the inert gas 3 in the working space 11 is maintained, ) And the solvent 1a to which the polymer 1b is to be mixed can be transferred to the working space 11 along the transfer path.

The main body is made of a translucent material, and the operator visually confirms the work space 11 through the rubber gloves provided at one side and can perform the preprocessing process (s10, s20, s30, s40) of the polymer .

Here, the solvent (1a) may be a pure water or a solution prepared under chemical conditions corresponding to the reservoir layer. For example, the solvent (1a) may be provided with a salt water whose sodium chloride (NaCl) content is adjusted to correspond to the seawater condition of the reservoir.

Accordingly, the degradation rate of the polymer due to the chemical environmental condition of the reservoir layer can be measured during the aging treatment of the measurement target solution (1) in which the solvent (1a) and the polymer (1b) are mixed.

Since the polymer 1b and the solvent 1a are mixed in the working space 11 in the negative pressure state filled with the inert gas 3, the amount of dissolved oxygen in the solution to be measured Can be reduced.

At this time, the work space 11 is provided with a stirring base 30b for forming a rotating magnetic field and a magnetic stirring device 30 including a stir bar 30a rotated by a rotating magnetic field. When the mixing vessel 20 such as a beaker is disposed above the stirring base 30b, the stir bar 30a is inserted into the mixing vessel 20.

When the polymer 1b and the solvent 1a are injected into the mixing vessel 20, a rotating magnetic field is generated in accordance with the operation of the stirring base 30b, and the rotating magnetic field of the stir bar 30a The solvent 1a and the polymer 1b can be stirred and mixed by rotation.

At this time, since the polymer (1b) can be decomposed at a high shear stress in a chain-like molecular structure, the rotation speed of the stir bar (30a) is preferably set according to the concentration of the polymer, The rotating speed of the stir bar 30a may be set to 100 to 500 rpm.

Of course, the step of stirring the polymer (1b) and the solvent (1a) may further include injecting an inert gas into the solvent (1a). At this time, the inert gas can be injected into the solvent (1a) contained in the mixing vessel (20) through a tube or the like, and serves to separate oxygen ions dissolved in the solvent (1a). Accordingly, the dissolved oxygen amount in the measurement target solution 1 can be reduced similarly to the reservoir environmental condition in the low-oxygen atmosphere.

When the polymer (1b) and the solvent (1a) are mixed, the degree of filtration is preferably measured according to the passage amount of the measurement target solution (1) with respect to the filtration member having a predetermined gap.

The polymer 1b may form a micro-gel in the course of stirring. Such a micro-gel may cause an error in measuring the viscosity of the solution 1 to be measured or may block the voids in the reservoir medium have. At this time, whether the microgel is formed can be confirmed through the filtration degree, and the measurement error can be minimized in the subsequent viscosity measurement process.

Specifically, the filtration member has a gap of a size permitting the measurement target solution (1) to pass therethrough, and is mounted to the lower opening of the cylindrical cell. The degree of filtration can be calculated by measuring the volume of the solution to be measured which has passed through the filtration member at a predetermined time interval after injecting a certain amount of the measurement object solution 1 into the cylindrical cell. At this time, the inert gas is injected into the cylindrical cell at a preset pressure, and the time required for measuring the degree of filtration can be significantly reduced.

Filtration degree = (T _{200 ml} - T _{180 ml} ) / (T _{80 ml} - T _{60 ml} )

T _xml is the time required for the volume of the measurement solution discharged to the bottom of the cylindrical cell to become x ml. If the value of the above equation is in the range of 1 to 1.2, It can be judged that the microgel does not exist in the object solution 1. [

At this time, when a microgel is present in the solution 1 to be measured, it is preferable to regulate the stirring speed of the stir bar 30a to perform the stirring process. Thereby, the measurement target solution (1) is subjected to the aging treatment in a state in which the polymer (1b) is uniformly mixed in the solvent (1a), and the viscosity before and after the aging treatment can be measured and compared. The accuracy can be significantly improved.

On the other hand, when the measurement target solution 1 is prepared (s10), an initial state value of the measurement target solution 1, that is, a first viscosity with respect to the initial state of the measurement target solution 1 is measured (s20) .

Herein, the initial state refers to a state before the measurement object solution 1 is subjected to the aging treatment, and the first viscosity measured and the viscosity measured for the measurement object solution 1 after the aging treatment are compared, Can be calculated.

At this time, a part of the prepared solution 1 to be measured is transferred to a viscosity measuring device such as a rheometer to measure viscosity, and the remaining solution 1 to be measured is stored in the storage container 40 in the glove box 10 (S30).

Here, the step of measuring the first viscosity of the solution 1 to be measured may further include the step of measuring the dissolved oxygen amount of the solution 1 to be measured through a dissolved oxygen measurement kit which measures the dissolved oxygen amount according to the color change .

In detail, the working space 11 of the glove box 10 is in a state in which internal air is continuously discharged through the vacuum valve and negative pressure is formed, so that it is impossible to use a general dissolved oxygen measuring device.

At this time, the dissolved oxygen measurement kit is provided with an ampoule coated on the inner surface of the indicator, whose color changes according to the amount of dissolved oxygen. When the solution 1 to be measured is sucked into the ampoule, the color of the indicator changes, The dissolved oxygen content of the solution 1 to be measured can be measured by comparing the hue of the indicator with the indicator color.

If the measured dissolved oxygen amount is equal to or greater than a predetermined reference value, an inert gas is injected into the measurement target solution 1.

For example, the reference value may be set to 50 ppb or less. When the dissolved oxygen amount is 50 ppb or more, a large deviation may occur between the decomposition rate of the polymer and the decomposition rate of the solution to be measured during the aging treatment in a low- It is preferable that the process of injecting the inert gas and measuring the dissolved oxygen amount are repeated until the dissolved oxygen amount of the object solution 1 becomes 50 ppb or less.

1 to 4, the solution to be measured 1 is stored in the storage container 40 in a state of being treated to have a dissolved oxygen amount less than a reference value. The sealed oil selected to have a specific gravity less than the measurement target solution (1) is subsequently injected into the upper part of the measurement target solution (1) stored in the storage container (40). At this time, it is preferable that the hermetic oil is provided as a mineral oil having low reactivity with the solution to be measured (1), the polymer to be analyzed, salt and the like.

In detail, the storage container 40 may include a container body 40a having an opened upper portion and a sealing cap 40b attached to and detached from the upper opening of the container body portion 40a.

That is, when a predetermined amount of the measurement target solution 1 is injected into the container body portion 40a, the sealed oil is supplied to the upper portion of the measurement target solution 1 accommodated in the lower portion of the container body portion 40a, Can be injected.

Since the closed oil has a lower specific gravity than the measurement target solution 1, the closed oil floats along the upper surface of the measurement target solution 1, and the closed oil film 2 ) May be laminated. That is, the upper surface of the measurement object solution 1 accommodated in the container body portion 40a can be covered by the sealed oil film 2.

Here, the sealed oil film 2 forms a shielding layer which is in close contact with the inner wall surface of the vessel body portion 40a and the upper surface of the solution 1 to be measured, by gas permeability. Accordingly, even when the storage container 40 is drawn out of the glove box 10, the contact between the measurement target solution 1 and the oxygen ions can be blocked.

At this time, the amount of the sealed oil to be injected is set so that the sealed oil film 2 forms an integrated single surface covering the entire upper surface of the object solution 1 from the inner wall surface of the container body portion 40a. The cross-sectional area of the base 40 is preferably set.

In other words, the sealing oil injected into the container body portion 40a is mixed with the surface tension of the container body 40a so that the sealing oil can be agglomerated without being divided into a plurality of droplets on the upper surface of the object solution 1, It is preferable to inject a sufficient amount in consideration of the cross-sectional area.

Meanwhile, when the sealed film 2 is formed (s30), the sealing cap 40b is coupled to the upper opening of the container body 40a (s40).

The sealing cap 40b is coupled to the upper end of the container body 40a in the work space 11 filled with the inert gas 3 so that an inert gas (3) can be filled.

Since the contact of the measurement target solution 1 with the gas such as oxygen is blocked through the sealed oil film 2 formed on the upper surface of the measurement target solution 1, The sealing of the storage container 40 can be completed only by a simple process of covering the opening with the sealing cap 40b.

Accordingly, a hazardous process of melting and sealing the upper opening of the storage container 40 with a fire can be eliminated, and a safety accident caused by a firearm and contamination of the measurement target solution 1 due to breakage of the storage container 40 Can be prevented.

Then, the storage container 40 is taken out of the glove box 10 in an upper sealed state, and aged in an environmental condition corresponding to the analysis target storage layer (s40). Here, the aging treatment means a process for simulating the state where the solution 1 to be measured is injected into the reservoir during the oil production period using the oil recovery enhancement method.

In detail, the storage container 40 drawn out from the glove box 10 is placed in a heating chamber heated to a predetermined temperature. Here, the heating chamber refers to a device that keeps the internal space at the predetermined temperature.

Here, the temperature may be set to correspond to the reservoir environment, may be arbitrarily set according to the purpose of analysis, and may be set to be less than the boiling point of the measurement target solution (1) so that disturbance of the sealed oil film (2) Preferably set.

In this case, since the sealed oil film 2 is provided in a fluid fluid state, even when the volume of the measurement target solution 1 changes due to heating, the upper surface of the measurement target solution 1 and the upper surface of the vessel body portion 40a So that the contact of the oxygen ions to the measurement metabolism solution 1 can be stably blocked.

Accordingly, the environment of the low-oxygen atmosphere in the low-oxygen atmosphere can be simulated even in the course of the aging treatment of the measurement target solution 1 drawn out from the glove box 10 in the inert gas atmosphere, and the dissolved oxygen amount of the measurement target solution 1 changes The degradation rate of the polymer can be accurately measured.

In addition, it is possible to stably simulate the reservoir environment of the low-oxygen atmosphere in the long-term aging treatment, which takes a short time of 2 or 3 days and a long time of 1 or 2 months, The cost can be reduced and the economical efficiency of the decomposition rate measurement process can be improved.

Specifically, FIG. 5 shows the amount of dissolved oxygen by the aging period when the solution to be measured having a polymer concentration of 3000 ppm and a brine concentration of 5000 ppm was aged at a temperature of 90 ° C. As shown in FIG. 5, in the initial state, the solution to be measured had a dissolved oxygen amount of 5 ppb and the dissolved oxygen amount of 5 ppb after the aging treatment at 2 days, 3 days, 7 days, 10 days, 21 days, 28 days, .

On the other hand, when the measurement target solution 1 is aged (s40), the second viscosity of the aged measurement target solution 1 is measured to calculate the decomposition rate (s50).

That is, when the solution 1 to be measured is drawn out from the container 40, the viscosity of the solution 1 is transferred to a viscosity measuring device such as a rheometer to measure the second viscosity. At this time, the sealed state of the solution to be measured 1 can be released only by separating the sealing plug 40b of the storage container 40, so that the convenience of the viscosity measurement process can be improved.

Degradation rate (%) = μ _AA / μ _BB × 100

The decomposition rate can be calculated in the same manner as described above. [Mu] _AA means the first viscosity of the initial state before the aging treatment, and [mu] _BB means the second viscosity after the aging treatment.

The aging treatment of the plurality of measurement target solutions in which the concentration of the saline solution is changed under the same temperature condition can calculate the chemical decomposition rate of the polymer. When the measurement target solution of the same salt concentration is aged at a plurality of temperature conditions, The thermal decomposition rate can be calculated.

The viscosity before and after the aging treatment of the measurement target solution 1 is accurately compared with the pretreatment process (s10, s20, s30, s40) of the polymer and the polymer degradation rate calculation process (s50) .

Thus, the thermal / chemical degradation rate of the polymer can be accurately measured, and it is possible to provide an underlying technology for a reliable polymer injection design.

As described above, the present invention is not limited to the above-described embodiments, and variations and modifications may be made by those skilled in the art without departing from the scope of the present invention. And such modifications are within the scope of the present invention.

1: Measuring object solution 2:
3: inert gas 10: glove box
20: mixing vessel 30: magnetic stirring apparatus
40: storage container

Claims (8)

A pretreatment method for measuring the decomposition rate of a polymer for improving petroleum recovery in which a reservoir environment in a low-oxygen atmosphere is simulated when measuring a decomposition rate of a polymer used in a petroleum recovery enhancement method,
The polymer to be analyzed and the mixed concentration are selected and injected and mixed at a selected concentration of the mixture in a solvent whose sodium chloride content is controlled such that the selected polymer corresponds to the reservoir to be analyzed in a glove box filled with an inert gas, ;
Wherein the initial state value of the measurement target solution is measured and the hermetic oil selected to have a specific gravity lower than the specific gravity of the prepared measurement target solution and the measurement target solution is sequentially injected into the storage container to form a sealed oil film on the upper surface of the measurement target solution A second step of forming a laminate; And
And a third step in which the upper end of the storage container is sealed and withdrawn from the glove box, and the drawn storage container is subjected to aging treatment at a temperature corresponding to the storage layer. The method according to claim 1,
Wherein the second step comprises setting the amount of the sealed oil to be injected in accordance with the cross-sectional area of the storage container so that the sealed oil film forms an integrated single surface covering the entire upper surface of the solution to be measured from the inner wall surface of the storage container Wherein the pretreatment method is used for measuring the decomposition rate of the polymer for improving petroleum recovery. The method according to claim 1,
The second step measures the dissolved oxygen amount of the measurement target solution through a dissolved oxygen measurement kit that measures the dissolved oxygen amount according to the color change,
And introducing an inert gas into the measurement target solution when the dissolved oxygen amount of the measured solution to be measured is not less than a preset reference value. The method according to claim 1,
Wherein the first step includes measuring the degree of filtration according to the passage amount of the measurement target solution with respect to the filtration member having a predetermined gap. The pretreatment method for measuring the decomposition ratio of the polymer for promoting the recovery of the petroleum. The method according to claim 1,
Wherein the third step includes placing the storage container in a heating chamber heated to a predetermined temperature,
Wherein the temperature is set to be less than a boiling point of the measurement target solution so that disturbance of the sealed oil film is prevented. A pretreatment method for measuring decomposition rate of a polymer for enhancing petroleum recovery. A method for measuring the decomposition rate of a polymer for oil recovery enhancement in which a reservoir environment of a low-oxygen atmosphere is simulated in measuring a decomposition rate of a polymer used in a petroleum recovery enhancement method,
A first step of preparing a solution to be measured by mixing the selected polymer with the selected polymer in a glove box filled with an inert gas while selecting a polymer to be analyzed and a mixed concentration;
A second step of measuring a first viscosity of an initial state of the solution to be measured and storing the prepared solution to be measured in a storage container;
A third step in which the upper end of the storage container is sealed and drawn out from the glove box, and the drawn storage container is aged to a temperature corresponding to the analysis target storage layer; And
And a fourth step of measuring a second viscosity of the aging-treated solution to be measured to calculate a decomposition rate of the polymer solution. The method according to claim 6,
Wherein the second step includes the step of successively injecting a hermetically sealed oil selected to have a specific gravity less than the solution to be measured into the upper portion of the stored solution to be measured to form a sealed oil film on the upper surface of the solution to be measured By weight based on the total weight of the polymer. The method according to claim 6,
Wherein the first step comprises injecting the selected polymer into a solvent whose sodium chloride content is adjusted so that the selected polymer corresponds to the reservoir layer and mixing the polymer.

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