RU2807348C1 - Holder of porous images, system and method for their examination - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: invention relates to means for studying the filtration properties of rocks and can be used in the oil and gas industry. In particular, a porous sample holder is claimed, filled with hydraulic fluid and containing at least one cuff located inside the holder body, into which at least one porous sample is placed. In this case, the cuff with the sample is limited on both sides by a pressure supply device, and the body is limited on both sides by flanges in such a way that at least one of the flanges is connected to a pressure supply device communicated with the holder through at least one pressure supply line and liquid supply lines through which the displacing and displaced fluids pass through a porous sample. In this case, the pressure providing device has a bayonet connection with the flanges, made in the form of at least one locking element on the pressure providing device and at least one sector groove on the flanges, complementary to the locking element. Also disclosed is a system for examining porous samples, comprising a holder for porous samples, and a method for examining porous samples.

EFFECT: increasing the efficiency of research into filtration formation processes, including by expanding the functionality of the system for studying porous samples and increasing the speed of research.

18 cl, 3 dwg

Description

Field of technology

[0001] The claimed invention can be used in the oil and gas industry and engineering geophysics and relates to the field of electrical engineering, as well as to methods for studying the filtration properties of rocks in order to extract oil by displacing it with various fluids. The present invention also relates to hydraulic systems and systems with a rotating mechanism.

State of the art

[0002] The hydraulic system is a collection of elements and mechanisms that provide action on a fluid substance for various purposes. Such systems are used in many areas of human activity, including industry, construction, geophysics, agriculture and others. This technology in geophysics is also used in studying the properties of rock samples and various fluids. In this case, the system includes a core holder - a device that allows you to simulate the physical state of a porous rock sample and processes occurring due to natural causes or human activity.

[0003] Currently, to describe the processes of displacement of oil and gas by water, assessing fluid saturation and obtaining the distribution of the fluid front, systems including plungers are used to create reservoir conditions in experiments on studying a core or proppant sample. Usually the plungers

Clamping core samples on both sides takes a long time and is difficult to disassemble due to the fact that the connection between the plungers and the pressure supply system must have very tight contact for the passage of fluid and retention of high pressure. However, slow and labor-intensive disassembly results in low experimental efficiency. Another problem lies in modeling reservoir conditions. The influence of gravity, temperature and pressure on the dynamics of fluid flow in the reservoir can be a key parameter during field development. There are several known devices and methods that allow laboratory studies of well material from oil and gas fields, including rock core samples and formation fluid.

[0004] A solution is known (RU 2775372 C1; publ. 06/30/2022; IPC: G01N 15/08, G01N 25/58), revealing an automated installation for studying filtration formation processes, containing a visual separator-meter (VSI), the first cryothermostat, connected to the VSI, a system for creating and maintaining back pressure, a system for measuring excess and differential pressure, a high-pressure PV pump, a capillary viscometer, the first and second separation tanks, the input lines of which are connected to the system for creating reservoir pressure and ensuring uninterrupted filtration of hydrocarbon fluid, the third separation tank a tank, the input line of which is connected to the system for creating formation pressure and ensuring uninterrupted filtration of formation water or a model of formation water - an aqueous saline solution corresponding in its composition and mineralization to natural formation water, a fourth separation tank, the input line of which is connected to the system for creating formation pressure and ensuring uninterrupted gas filtration, and the output line is connected to the system for measuring excess and differential pressure, the fifth separation tank, the input line of which is connected to the system for creating and maintaining back pressure when conducting studies of filtration formation processes, and the output line is connected to the VSI, while the capillary viscometer is connected with the output line of the first separation tank, with a high-pressure PV pump and with a system for measuring excess and differential pressure, and all of the above-mentioned systems, separation tanks, VSI, a capillary viscometer and a high-pressure PV pump are located in a heating cabinet, which is designed to create a reservoir temperature when conducting studies of filtration formation processes and is equipped with a second thermocryostat, and inside the heating cabinet there is a platform that is designed to accommodate a replaceable module for studying filtration formation processes, containing a sample simulating the studied formation rock,

wherein the platform is located in the heating cabinet in such a way that it is possible to connect said replaceable module to the input of the VSI and/or to the output lines of the separation tanks.

[0005] The disadvantages of this installation include the inability to rotate the core holder at a given angle. As a result, the system cannot provide high accuracy in modeling reservoir processes. In addition, the description does not disclose the mechanism for connecting the plungers with core samples, as well as the possibility of their additional fixation in the core holder, which limits the speed and reliability of fixing the samples.

[0006] Another solution close to the claimed one is known (RU 160842 U1; publ. 04/10/2016; IPC: G09B 23/40, E21C 39/00), in which a sectional model of the formation is disclosed, including a chamber, a cuff, an inlet flange, characterized in that that it consists of equal-length sections of the reservoir model, each of which is designed as an external hollow cylindrical chamber, made with annular collars at the ends, along the perimeter of which through holes are located; flanges with central capillary channels are installed on the inlet and outlet sections of the reservoir model, in the upper part of each section of the reservoir model there are fittings with pressure and temperature sensors connected by a common pressure and temperature sensor; inside each section of the reservoir model there is a cuff with the ability to place a core sample in it, made along the length with a gap larger than the outer hollow cylindrical chamber , with annular collars at the ends for connecting sections of the reservoir model to each other by inserting the collar collar into the inner hole of the sleeve, made with an upper hole for installing pressure and temperature sensors into it.

[0007] The disadvantages of this utility model also include the lack of a quick-release connection of the plungers with core samples. As a result, the core holder cannot provide high speed and reliability of sample fixation. In addition, the ring collars take a relatively long time to dismantle and are quite massive, further complicating the installation.

[0008] Another invention (US 9903826 B2; publ. 02/27/2018; IPC: G01N23/046, G01N23/20025, G01N33/241, G01N2223/616) discloses a system for conducting core flood testing, containing a core holder configured to be connected with a computed tomography (CT) system to monitor the fluid saturation of the core containing the rock sample; and a core sleeve configured to be received in the core holder, a core holder and a core sleeve separated by a bounding space, a core sleeve for receiving the core, wherein the core sleeve is configured to contact the core in response to an applied confining pressure to the core sleeve in the bounding space, and be separated from the core in response to removal of the confining pressure, creating a fracture space between the core and the core sleeve, and wherein the core is configured to receive injected hydrocarbon; an injection plate attached to a first end of the core holder for transferring injection fluids into the core, the injection plate comprising an injection end cap tapered to substantially match the inside diameter of the core sleeve to seal the injection plate and the core sleeve; and a production plate attached to the second end of the core holder for collecting at least a portion of the hydrocarbon produced from the core.

[0009] Also disclosed in the application is a system for conducting core flood testing, comprising a core holder configured to be coupled to a computed tomography (CT) scanning system for monitoring fluid saturation of a core containing a rock sample; and a core sleeve configured to be received in the core holder, a core holder and a core sleeve separated by a bounding space, a core sleeve for receiving the core, wherein the core sleeve is configured to contact the core in response to a confining pressure applied to the core sleeve in the bounding space, and be separated from the core in response to the release of confining pressure, creating a rupture space between the core and the core sleeve; and an injection plate attached to the first end of the core holder for transferring injection fluids into the core, the injection plate including a cap on the injection end substantially corresponding to the inside diameter of the core sleeve for sealing the injection plate and the core sleeve.

[0010] Also known from the patent is a method of testing a core with waterflooding, which includes performing a first core test by pouring the core inside a core holder, with the core holder installed in a horizontal position; performing a second core test by pouring the core inside the core holder, with the core holder installed in a vertical orientation; and an assessment of the gravitational impact on hydrocarbon production based on a comparison of the results of the first coreflood test and the second coreflood test.

[0011] The disadvantages of these systems and method are also that the core holder can be rotated at a given angle, but it is due to the use of a CT scanner stage, the rotation angle is measured relative to the horizontal axis

table, and the rotation mechanism itself is not disclosed in detail in the text. In addition, the mechanism for connecting the plungers with core samples is massive and cannot be quickly disassembled due to the use of at least 8 screws and nuts, which limits the speed and reliability of fixing the samples. As a result, the system also cannot provide high accuracy in modeling reservoir processes.

[0012] Another solution is also known (US 11435299 B2; publ. 09/06/2022; IPC: G01N23/046, G01N33/24, G06T11/008, G06T7/0004, G01N2223/419, G01N2223/616, G06T2207/1 0081, G06T2207/ 30181), which describes a method for determining the properties of a core sample, including placing a sample of the formation core in a pressure chamber of a core holder assembly; applying one or more pressures to the core sample in a pressure chamber; obtaining at least one computed tomographic image of the core sample; and based on the at least one computed tomographic image of the core sample, determining at least one property of the core sample as a function of the applied one or more pressures, and a core analysis system for determining properties of the core sample, comprising a core holder assembly; computed tomograph; and a core analysis control system operatively coupled to the core holder assembly and the computed tomography imaging device, the core analysis control system comprising at least one processor; and at least one non-transitory computer-readable storage medium that stores instructions, the execution of which by the at least one processor causes the core analysis system to perform the following steps: apply, through the core holder assembly, one or more pressures to a formation core sample located within core holder assembly; rotates the core holder assembly about the central longitudinal axis of the core holder assembly; obtains, using a computed tomography imager, a series of computed tomographic images of the core sample at various pitches of rotation of the core holder assembly; creates, based on a series of computed tomographic images of the core sample, a three-dimensional representation of at least a portion of the core sample using radon transformation; and also measures the displacement of at least one characteristic of the core sample due to applied pressure.

[0013] The disadvantages of this invention also lie in the fact that it is possible to rotate the core holder at a given angle, but the angle of rotation is measured from the central axis of the sample, and the rotation mechanism itself is not disclosed in detail in the text. In addition, the mechanism for connecting the plungers to the core samples is made massive, which limits the speed and reliability of fixing the samples. As a result, the system also cannot provide high accuracy in modeling reservoir processes.

[0014] The disadvantage of all the mentioned solutions is the insufficiently good quality of modeling fluid displacement processes and filtration experiments in general, associated with the inability to rotate the core holder relative to the axis that rotates the samples from a horizontal to a vertical position. In addition, the connections disclosed in the prior art do not have sufficient quick release and reliability, which also makes it difficult to conduct a large number of experiments due to the large amount of time spent preparing the core holder and core samples.

The essence of the invention

[0015] The objective of the present invention is to create a system for studying porous samples that has increased efficiency, due, among other things, to the possibility of adjusting the position of the porous sample holder in space, namely its angle of inclination, and the creation of a holder capable of quick assembly and disassembly for placement in it porous samples, as well as the development of a method that supports the claimed effectiveness.

[0016] This problem is solved by achieving the technical result of the claimed invention, which consists in increasing the efficiency of studies of filtration formation processes, including by expanding the functionality of the system for studying porous samples and increasing the speed of research. The result is also achieved due to the presence of a rotating mechanism that rotates the holder of porous samples at a given angle, which allows experiments to be carried out at different positions of the sample. In addition, the result is achieved by connecting the holder with a quick-release pressure device in the form of a bayonet connection, which ensures the reliability of the connection during the supply of pressure and fluids and the speed of preparing the holder for experiments.

[0017] The porous sample holder contains at least one cuff located inside the holder body and into which at least one porous sample is placed, wherein the cuff with at least one sample is limited on two sides by a pressure providing device, and the body is limited on two sides sides by flanges in such a way that at least one of the flanges is connected to a pressure supply device communicated with the holder through at least one pressure supply line and fluid supply lines through which the displacement and displacement fluids pass through the porous sample, while the supply device pressure device has a bayonet connection with flanges, made in the form of at least one locking element on the pressure supply device and at least one sector groove on the flanges, complementary to the element. During operation, the holder is filled with hydraulic fluid.

[0018] Porous samples can include core samples, natural and synthetic, as well as concrete samples. The combination of such objects forms a core column. The dimensions of such objects are limited by the dimensions of the holder and cuff itself.

[0019] In filtration experiments to create crimping pressure on porous samples, the holder was filled with various hydraulic fluids, including mineral, synthetic and semi-synthetic oils, silicone-based fluids, oil-water emulsions, oil-water emulsions and other types of oils. The type of liquids is selected based on the operating temperature of the holder and operating pressures. In the preferred implementation of the inventive holder, it is filled with hydraulic silicone oil. This substance is characterized by a minimal dependence of viscosity on temperature, chemical inertness to the materials from which the holder elements are made, significant incompressibility, low coefficient of thermal expansion, non-toxicity, and it also has boiling points outside the operating range of temperatures and pressures. Different types of liquid can be used in experiments aimed at studying the geomechanical properties of samples.

[0020] The cuff, together with the hydraulic fluid, provides crimping pressure on the porous samples and prevents the disintegration of the core column placed in it, due to the fact that it is sufficiently elastic and tightly encircles the porous samples without forming gaps between them. Thus, the cuff maintains a continuous flow of fluid through the column, which makes it possible to study porous samples. In its private form, the cuff can accommodate up to 6 samples, which ensures reliable data with a relatively small column size. In addition, in the preferred, but not the only version of the holder and system, measuring and injection electrodes are placed on the cuff at a certain distance. Injection and measuring electrodes, respectively emitting and receiving a signal for studying a porous sample, can be located in a cylindrical geometry coaxially with the samples under study and encircling them due to their location on the cuff isolating from the hydraulic fluid. The mentioned elements are the main tools in the use of fast and effective electrical tomography techniques in the study of porous samples, including dynamics, which allows, among other things, to obtain and build a model of the electrical resistivity of porous samples with the ability to determine the position of the front of the displacing fluid in the porous sample and with calculation saturation with displaced and displacing fluids. This technique also ensures the absence of harmful radiation and significant limitations on geometric characteristics when examining samples. The use of electrodes, and, therefore, the use of this technique, makes it possible to increase the efficiency of studying the properties of porous samples due to the reliability and speed of the data obtained.

[0021] The holder body serves to maintain pressure on the cuff, which seamlessly transfers it to the side surface of the porous samples, fixes the pressure supply device and performs a protective function. It must have sufficient strength to withstand both high pressures and temperatures, as well as possible mechanical damage that could compromise its own integrity. The presence of the housing provides the ability to create and maintain the pressure necessary for studying porous samples.

[0022] The pressure providing device applies axial pressure to the cuff containing the column of porous samples, thereby promoting the flow of fluids along the fluid supply lines through the pores in the sample. Thus, the device is directly involved in providing pressure and setting fluid flow in the system. The design feature of this device is that it has a bayonet connection with flanges, made in the form of at least one locking element on the surface of the device itself, and at least one sector groove complementary to the element is made on the holder body. This makes it possible to communicate the said elements by means of axial movement and rotation of the pressure providing device relative to the housing, which is a fast and easy connection method. Due to this, in comparison with devices known from the prior art, the pressure supply device can be easily and quickly disconnected from the cuff and from the holder body and just as quickly and easily reconnected due to the connection design. Thus, this connection allows for rapid preparation of the holder and samples for experiments, including placing the samples and holder in the working position and removing the samples from the holder. The working position is considered to be one in which the samples are in close contact with each other without gaps, and the holder has the ability to supply displacing and displaced fluids through the supply lines through the samples. As a result of the use of this compound, an increase in the speed of research is achieved by reducing the preparation time of porous samples and the holder. In a preferred implementation, the pressure supply device is made in the form of two plungers, which allows the system for studying porous samples to operate at high operating pressures, thereby increasing its efficiency. In addition, the preferred, but not the only option for the technical implementation of the device is mounting for temperature measuring instruments. These devices allow temperature control during research, which increases the efficiency of experiments by expanding the functionality of the research system. In another possible design of the device, it is configured to adjust the position of the porous sample. More specifically, during the installation of a column of samples or one sample, it is possible to adjust the position of the sample in the holder in order to ensure tighter contact between the samples and between the pressure devices, which increases the efficiency of research due to the reliability of the data obtained.

[0023] The flanges are parts of the holder body and also serve to maintain pressure on the cuff, which seamlessly transfers it to the side surface of the porous samples, fix the pressure supply device and perform a protective function. The presence of flanges also provides the ability to create and maintain the pressure necessary to study porous samples. They must have sufficient strength to withstand both high pressures and temperatures, as well as possible mechanical damage that could compromise their integrity. To fill the holder with hydraulic fluid, at least one hole is made in at least one flange to communicate the holder with the pressure supply lines. In a particular embodiment, at least one flange is made removable to allow diagnostics of the holder from the inside, which increases the efficiency of the holder and the system by increasing their reliability by preventing possible malfunctions and breakdowns.

[0024] The fluid supply lines allow the displacement and displacement fluids to flow through the sample and communicate with a pressure supply device in communication with the holder, thereby allowing the fluids to flow. Liquid supply lines can carry various fluids, including oil, water, mineralized water, kerosene, a mixture of water with kerosene or oil, drilling fluid, acid solution and others. The choice of fluid depends on the setup of the experiment.

[0025] Pressure lines fill the holder with hydraulic fluid. Pressure lines can carry a variety of hydraulic fluids, including those listed previously. It is preferable to use hydraulic silicone oil for the reason stated earlier.

[0026] The system for studying porous samples contains at least one holder for porous samples, a chamber in which the holder is placed, and a system for providing hydraulic pressure in communication with the chamber and the holder, wherein the chamber is configured to rotate the holder at a given angle inside it due to the rotary a mechanism made in the form of an axis, a bearing unit and a plate, and the device for ensuring pressure of the holder has a bayonet connection to the flanges of the holder.

[0027] The camera is a closed housing into which the holder is placed and securely fastened. The camera also performs a protective function and is designed with the ability to rotate the holder at a given angle. The advantages of the bayonet connection of the pressure supply device to the holder flanges have been described above. Rotation of the holder allows experiments to be carried out at an arbitrary angle, including from 0 to 90 degrees, for the most accurate recreation of physical processes corresponding to the conditions of a real reservoir, which ensures increased efficiency of the system by expanding its functionality. The holder can be rotated either together with the camera or independently of it. The rotation of the holder is carried out due to a rotating mechanism made in the form of an axis, a bearing unit and a plate on which the holder is placed. This allows you to quickly rotate the holder, thereby increasing the efficiency of process research due to the speed of preparing samples for them. In addition, in another version of the system, the chamber is additionally configured to regulate the set temperature. Regulation can be ensured due to the tightness of the chamber, the presence of devices for heating or cooling the system, for example, heating elements, a ventilation system, etc. This feature allows you to expand the functionality of the system, which increases the efficiency of studying filtration processes in porous samples.

[0028] The fastening of the holder is necessary to prevent mechanical damage to the holder and/or the system as a result of its rotation, which is a necessary condition for rotation. In a particular, but not the only form, it can be organized by means of holders that securely fix the holder and prevent it from sliding, which ensures the prevention of mechanical damage in the system caused by the displacement of the holder from the working position.

[0029] The hydraulic pressure system serves to inject fluid into the holder and allows for filtration experiments. It may include pumps, systems and their control devices, including those based on the feedback method, pressure sensors, flow meters and other devices that provide fluid flow under various modes.

[0030] A method for examining porous samples consists of sequential steps in which at least one porous sample is first placed in a cuff. The placement of samples must be carried out without gaps between them to ensure the reliability of the data obtained.

[0031] Next, the cuff with the sample is limited by a device for providing pressure on both sides. This allows the displacement and displacement fluids to be supplied without creating gaps between the device and the sample column.

[0032] Then, the holder and pressure supply device are filled with hydraulic fluid using a pressure supply line. This creates the crimping pressure on the porous samples necessary for experiments.

[0033] The displacement and displacement fluids are then fed alternately into the sample through the fluid supply lines.

[0034] Next, the camera with the holder located inside it is rotated at a given angle due to a rotating mechanism made in the form of an axis, a bearing unit and a plate. Rotation of the holder allows experiments to be carried out at an arbitrary angle, including from 0 to 90 degrees, for the most accurate recreation of physical processes corresponding to the conditions of a real reservoir, which ensures increased efficiency of the system by expanding its functionality.

[0035] Information about the properties of the sample is then collected. Information can be collected by various methods, including X-ray tomography, ultrasound methods and electrical tomography.

[0036] To increase the reliability of the results, information can be collected using electrodes placed on the cuff, and based on the results of information collection, a three-dimensional model of the electrical resistivity of the medium is additionally built. Another implementation of the method involves additionally determining the position of the displacing fluid front in a porous sample and calculating the saturation of porous samples with displaced and displacing fluids and providing the ability to transfer the resulting digital data to a personal computer for subsequent processing and storage. These stages make it possible to improve the quality of the information obtained, thereby increasing the efficiency of studying reservoir processes.

[0037] Also, in one variant of the method, a predetermined temperature is additionally set. In addition, in one of the variants of the method, before clamping the cuff with the sample by the pressure ensuring device, the sample fixation is adjusted. All of these features increase the efficiency of the research system. Their advantages have been described above and will be discussed in more detail below in the text.

Description of drawings

[0038] The subject matter of this application is described point by point and clearly stated in the claims. The above-mentioned objects, features and advantages of the invention will become apparent from the following detailed description, taken in conjunction with the accompanying drawings, in which:

[0039] In FIG. Figure 1 shows a block diagram of a porous sample holder.

[0040] In FIG. Figure 2 shows a block diagram of the system for studying porous samples.

[0041] In FIG. 3 is a flowchart depicting a method for studying porous samples.

[0042] These drawings are illustrated by the following positions: Holder - 1; Cuff – 2; Holder body – 3; Porous sample or core column – 4; Pressure supply device – 5; Flange – 6; Pressure supply line – 7; Liquid supply lines – 8; Mounts for temperature measuring instruments – 9; Device for adjusting sample fixation – 10; Locking element – 11; Sector groove – 12; Hydraulic fluid – 13; Camera – 14; Rotary mechanism – 15; Axle – 16; Bearing unit – 17; Stove – 18; Holder fastening – 19.

Detailed Description of the Invention

[0043] The following detailed description of the invention provides numerous implementation details intended to provide a clear understanding of

of the present invention. However, it will be apparent to one skilled in the art how the present invention can be used with or without these implementation details. In other cases, well-known methods, procedures and components are not described in detail so as not to unduly obscure the features of the present invention.

[0044] In addition, from the above discussion it is clear that the invention is not limited to the above implementation. Numerous possible modifications, alterations, variations and substitutions, while retaining the spirit and form of the present invention, will be apparent to those skilled in the art.

[0045] In FIG. Figure 1 shows a block diagram of one of the embodiments of a porous sample holder. The holder 1 of porous samples 4 contains at least one cuff 2 located inside the body of the holder 3 and into which at least one porous sample 4 is placed, while the cuff 2 with at least one sample 4 is limited on both sides by a pressure providing device 5, wherein the housing 3 is limited on both sides by flanges 6 in such a way that at least one of the flanges 6 is connected to a pressure supply device 5 communicated with the holder 1 through at least one pressure supply line 7 and liquid supply lines 8 through which the passage displacing and displacing fluids through the porous sample 4, while the pressure supply device 5 has a bayonet connection with flanges. During operation, the holder is filled with hydraulic fluid 13.

[0046] Porous samples 4 can include core samples, natural and synthetic, as well as concrete samples. The combination of such objects forms a core column. The dimensions of such objects are limited by the dimensions of the holder and cuff itself.

[0047] In filtration experiments to create crimping pressure on porous samples 4, the holder 1 was filled with various hydraulic fluids 13, including mineral, synthetic and semi-synthetic oils, silicone-based fluids, oil-water emulsions, oil-water emulsions and other types of oils. The type of liquids is selected based on the operating temperature of the holder and operating pressures. In the preferred implementation of the inventive holder 1, it is filled with hydraulic silicone oil. This substance is characterized by a minimal dependence of viscosity on temperature, chemical inertness to the materials from which the holder elements are made, significant incompressibility, low coefficient of thermal expansion, non-toxicity, and it also has boiling points outside the operating range of temperatures and pressures. Different types of liquid 13 can be used in experiments aimed at studying the geomechanical properties of samples 4.

[0048] The cuff 2, together with the hydraulic fluid 13, provides crimping pressure on the porous samples 4 and prevents the disintegration of the core column 4 placed in it, due to the fact that it is sufficiently elastic and tightly surrounds the porous samples without forming gaps between them. Cuff 2, due to its elasticity, tightly clasps sample 4, and elasticity leads to the fact that the stretched cuff 2 tends to return to its original shape and therefore tightly compresses the column 4 placed in it under the action of crimping pressure. The coverage density leads to the fact that there is practically no free space left between sample 4 and the walls of the cuff 2, which ensures the passage of displaced and displacing fluids through samples 4. Thus, the cuff 2 maintains a continuous flow of fluid through column 4, which makes it possible to study porous samples 4. Various technical implementations of the cuff 2 are known from the prior art and are obvious to a person skilled in the art. In its particular form, the cuff 2 can contain up to 6 samples 4, which ensures that reliable data is obtained with relatively little time spent preparing the column 4, due to its small size. The study of the properties of samples 4 can be carried out, among other things, with the help of sensors located on the cuff 2. In the preferred, but not the only version of the holder 1 and the system, measuring and injection electrodes are placed on the cuff 2 at a certain distance. Injection and measuring electrodes, respectively emitting and receiving a signal for studying the porous sample 4, can be located on the cuff 2, for example, in a cylindrical geometry coaxial with the samples 4 under study and encircling them. The mentioned elements are the main tools in the use of fast and effective electrical tomography techniques in the study of porous samples 4, including the dynamics of fluid displacement, which allows, among other things, to obtain and build a model of the electrical resistivity of porous samples 4 with the ability to determine the position of the front of the displacing fluid in the porous sample 4 and with the calculation of saturation with displaced and displacing fluids. This technique also ensures the absence of harmful radiation and significant limitation of geometric characteristics when studying samples 4. The use of electrodes, and, therefore, the use of this technique, makes it possible to increase the efficiency of studying the properties of porous samples 4 due to the reliability and speed of the data obtained.

[0049] The body 3 of the holder 1 serves to maintain pressure on the cuff 2, which seamlessly transfers it to the side surface of the porous samples 4, fixes the pressure providing device 5 and performs a protective function. It must have sufficient strength to withstand both high pressures and temperatures, as well as possible mechanical damage that could compromise its own integrity. For example, the housing 3 can be made of metal or alloys. The presence of housing 3 makes it possible to create and maintain the pressure necessary to study porous samples 4, since pressure is transmitted by fluids that require some kind of sealed container for their placement.

[0050] The pressure supply device 5 exerts axial pressure on the cuff 2 with a column of porous samples 4, thereby facilitating the flow of fluids along the liquid supply lines 8 through the pores in the sample 4. Thus, the device 5 is directly involved in providing pressure and setting the fluid flow rate in the system . A design feature of this device 5 is that it has a bayonet connection with flanges. Due to this, in comparison with devices 5 known from the prior art, device 5 can be easily and quickly disconnected from the cuff 2 and from the body 3 of the holder 1 and also quickly and easily connected back due to its connection design. Thus, this connection allows for quick preparation of holder 1 and samples 4 for experiments, including installing samples 4 and holder 1 in the working position and removing samples 4 from holder 1. The working position is considered to be the position in which samples 4 are in close contact with each other without gaps , and holder 1 has the ability to supply displacing and displaced fluids through supply lines 8 through samples 4. As a result of using this connection, an increase in the speed of research is achieved by reducing the preparation time of porous samples 4 and holder 1. Reducing preparation time allows for a greater number of experiments in a given period of time compared to similar holders, thereby increasing the efficiency of studies of the filtration properties of reservoir processes.

[0051] The pressure supply device 5 can be represented by various devices, for example, plungers, a hydraulic jack and plungers, pumps, and otherwise, which is obvious to a specialist. In the preferred implementation, the pressure supply device 5 is made in the form of two plungers 5, which allows the system for studying porous samples 4 to operate at high operating pressures, thereby increasing its efficiency by expanding the range of permissible pressures, allowing experiments to be carried out in a wider range of reservoir conditions. The bayonet connection of the device 5 with the holder 1 is made in the form of at least one locking element 11 on the surface of the device 5 itself, and on the body 3 of the holder 1 there is at least one sector groove 12, complementary to the element 11, as shown in Fig. 1 . This type of bayonet connection allows the said elements 11 and 12 to be connected by axial movement and rotation of the pressure providing device 5 relative to the housing 3, which is a fast and easy connection method. Other private variants of the open connection are also possible, differing in the number, shape, location and combination of grooves 12 and projections 11, obvious to a specialist. In a particular version of the pressure supply device, it contains mounts for temperature measuring instruments 9. These devices allow temperature control during research, which increases the efficiency of experiments by expanding the functionality of the research system by setting a certain temperature value and measuring it with possible change due to additional means, for example, heaters or otherwise. Temperature measuring devices can be made in the form of temperature sensors, thermocouples and thermal resistances or otherwise. In another possible design of the device, it is configured to adjust the position of the porous sample to uniquely fix the sample 4 in the holder 1. More specifically, during the installation of a column of samples 4 or one sample 4, it is possible to adjust the position of the sample 4 in the holder 1 in order to provide more close contact of samples 4 with each other and between pressure devices 5, which increases the efficiency of research due to the reliability of the data obtained. Reliability in this case is achieved due to the tight contact of the samples 4 with each other and the clasping of them by the cuff 2. In a particular case, this possibility is implemented in the form of a device for adjusting the fixation of the samples 10. The device 10 is capable of moving the device 5 along the axis, thereby varying its position relative to the cuff 2 The movement can be realized by a threaded connection between the device 5 and a lever, or a screw, or otherwise. In the presented implementation, it is performed as a screw clamp, but other implementations, both manual and automated, are obvious to a person skilled in the field.

[0052] The flanges 6 are parts of the body 3 of the holder 1 and also serve to maintain pressure on the cuff 2, which seamlessly transfers it to the side surface of the porous samples 4, fixes the pressure supply device 5 and performs a protective function. They are located on the side parts of the housing 3, for example, as shown in Fig. 1 . The presence of flanges 6 also makes it possible to create and maintain the pressure necessary to study porous samples 4, since they, together with the body 3, create a volume for liquid. In this case, the flanges 6 must have sufficient strength to withstand both high pressures and temperatures, as well as possible mechanical damage that can compromise their own integrity. Hydraulic fluid 13 may be supplied to the holder 1 in various ways, including through at least one flange 6 or housing 3. These elements may have connections or fittings for supplying fluid 13 through lines 7. In particular, to fill the holder 1 with hydraulic fluid 13 in at least one flange 6 there is at least one hole for communication of the holder 1 with the pressure supply lines 7. Other ways of filling the holder 1 with liquid 13 are obvious to the specialist. In a particular version, at least one flange 6 is made removable to make it possible to diagnose the holder 1 from the inside, which increases the efficiency of the holder 1 and the system by increasing their reliability by preventing possible malfunctions and breakdowns, as well as reducing the time for preparing samples 4 for the experiment. This property of the flange 6 can be realized using various types of connections, including, but not limited to, threaded, bayonet and others.

[0053] Fluid supply lines 8 allow the displacement and displacement fluids to flow through the sample 4 and communicate with a pressure supply device 5 in communication with the holder 1, thereby ensuring the flow of fluids. Liquid supply lines 8 can carry various fluids, including oil, water, mineralized water, kerosene, a mixture of water with kerosene or oil, drilling fluid, acid solution and others. The choice of fluid depends on the setup of the experiment.

[0054] The pressure supply lines 7 fill the holder 1 with hydraulic fluid 13. The supply lines 7 can carry various hydraulic fluids 13, including those listed previously. It is preferable to use hydraulic silicone oil for the above reason.

[0055] In FIG. 2 shows a system for studying porous samples 4, which contains at least one holder 1 of porous samples 4, a chamber 14 in which the holder 1 is placed, and a system for providing hydraulic pressure communicated with the chamber 14 and the holder 1, and the chamber 14 is rotatable holder 1 to a given angle inside it due to the rotating mechanism 15, made in the form of an axis 16, a bearing unit 17 and a plate 18, and the device for ensuring pressure of the holder 1 has a bayonet connection with the flanges of the holder 1.

[0056] Chamber 14 is a closed housing into which holder 1 is placed and securely fastened. Chamber 14 also performs a protective function and is designed to rotate holder 1 at a given angle. The holder can be either holders known from the prior art or the embodiments of holder 1 disclosed above. The shape, material and other parameters of the chamber 14 are obvious from the prior art to a specialist. The advantages of the bayonet connection of the pressure supply device to the flanges of the holder 1 have been described above. Rotation of holder 1 allows experiments to be carried out at an arbitrary angle, including from 0 to 90 degrees, for the most accurate recreation of physical processes corresponding to the conditions of a real reservoir, including the flow of displacing and displaced fluids in the rock under the influence of gravity, which ensures increased efficiency of the system by expanding its functionality. The rotation of the holder 1 can be carried out both together with the camera 14 and independently of it, i.e. The rotating mechanism 15 can rotate both the holder 1 separately and the chamber 14 with the holder 1. The rotating mechanism 15 may include an axis 16 around which the rotation is performed, a holder fixing device and a bearing assembly 17. Various designs of the rotating mechanism 15 and its parts are obvious to a person skilled in the art. .

[0057] The rotation of the holder 1 is carried out due to the rotating mechanism 15, made in the form of an axis 16, a bearing unit 17 and a plate 18 on which the holder 1 is placed, as shown in FIG. 2 . This allows you to quickly rotate the holder 1, thereby increasing the efficiency of process research due to the speed of preparing samples 4 for them. More specifically, the speed and smoothness of rotation is ensured by the design of the bearing unit 15, which ensures smooth movement of the plate 18 relative to the axis 16, which allows the holder 1 to rotate at high speed. At the same time, the plate 18 serves to fix the holder 1 to the rotating mechanism and at the same time transmits rotation to it. In addition, in another version of the system, the chamber 14 is additionally configured to regulate the set temperature. Regulation can be ensured by thermocouples located in the pressure supply device 5 and similar elements, the tightness of the chamber 14, the presence of devices for heating or cooling the system, for example, heating elements associated with the temperature control system, ventilation systems and others. This feature allows you to expand the functionality of the system, which increases the efficiency of studying filtration processes in porous samples 4 due to the possibility of expanding the range of varied parameters in experiments.

[0058] The fastening 19 of the holder 1 is necessary to prevent mechanical damage to the holder 1 and/or the system as a result of its rotation, which is a necessary condition for rotation. The mount 19 must be able to withstand the weight of the holder 1 filled with liquid 13 and samples 4, and not allow it to slip when turning. In a particular, but not the only form, the fastening 19 can be organized by means of holders 19, which reliably fix the holder 1 and prevent it from sliding due to the presence of fasteners encircling the holder 1, as shown in Fig. 2 , which ensures the prevention of mechanical damage in the system caused by displacement of the holder 1 from its working position.

[0059] A hydraulic pressure supply system (not shown) serves to inject fluid into the holder 1 and allows for filtration experiments. It may include pumps, systems and their control devices, including those based on the feedback method, pressure sensors, flow meters and other devices that provide fluid flow under various modes. Possible embodiments of the system and its components are obvious to a person skilled in the art.

[0060] In FIG. 3 shows a diagram illustrating a method for studying porous samples 4, and consists of successive steps in which at least one porous sample 4 is first placed in the cuff 2. The placement of samples 4 must be carried out without gaps between them to ensure the reliability of the data obtained, as described higher, which directly affects the efficiency of studying the properties of samples 4.

[0061] Next, the cuff 2 with the sample 4 is clamped by the pressure providing device 5 on both sides. This allows the supply of displacing and displaced fluids without creating gaps between the device and the sample column 4, which also directly affects the efficiency of the study.

[0062] The holder 1 and the pressure providing device 5 are then filled with hydraulic fluid 13 via the pressure supply line 7. This creates the crimping pressure on the porous samples 4 necessary for carrying out the experiments for the reasons previously described.

[0063] Then the displaced and displacing fluids are supplied in turn to the sample 4 through the liquid supply lines 8. The liquid supply lines 8 can carry various fluids, including oil, water, mineralized water, kerosene, a mixture of water with kerosene or oil , drilling fluid, acid solution and others. The choice of fluid depends on the setup of the experiment.

[0064] Next, the chamber 14 with the holder 1 located inside it is rotated to a given angle due to the rotating mechanism 15, made in the form of an axis 16, a bearing unit 17 and a plate 18. Rotation of the holder 14 allows experiments to be carried out at an arbitrary angle, including from 0 to 90 degrees, for the most accurate recreation of physical processes corresponding to the conditions of a real reservoir, including the flow of fluids from top to bottom under the influence of gravity, which ensures increased efficiency of the system by expanding its functionality.

[0065] Information about the properties of the sample 4 is then collected. Information can be collected by various methods, including x-ray tomography, ultrasonic methods and electrical tomography.

[0066] To increase the reliability of the results, information can be collected using electrodes placed on the cuff 2, and based on the results of information collection, a three-dimensional model of the electrical resistivity of the medium is additionally built. Injection and measuring electrodes, respectively emitting and receiving a signal for studying the porous sample 4, can be located on the cuff 2, for example, in a cylindrical geometry coaxial with the samples 4 under study and encircling them. The mentioned elements are the main tools in the use of fast and effective electrical tomography techniques in the study of porous samples 4, including the dynamics of fluid displacement, which allows, among other things, to obtain and build a model of the electrical resistivity of porous samples 4 with the ability to determine the position of the front of the displacing fluid in the porous sample 4 and with the calculation of the saturation of porous samples with displaced and displacing fluids. This technique also ensures the absence of harmful radiation and significant limitation of geometric characteristics when studying samples 4. The use of electrodes, and, therefore, the use of this technique, makes it possible to increase the efficiency of studying the properties of porous samples 4 due to the reliability and speed of the data obtained. Other methods are known from the prior art for collecting information about the properties of column 4, constructing a model of sample 4, and determining the fluid front and sample saturation. The mentioned steps make it possible to obtain comprehensive data on porous samples 4 and thereby increase the efficiency of their research.

[0067] As an additional step, it may be possible to transfer the acquired digital data to a personal computer for subsequent processing and storage. This will make it possible to use the obtained materials to adjust the operation of the system and associated calculations, which increases the efficiency of the process of studying samples 4. Various types and methods of transmitting and storing data are obvious to a specialist.

[0068] Also, in one variant of the method, a predetermined temperature in the system is additionally set. Setting the temperature can be done according to the option disclosed above or otherwise and serves to expand the array of data obtained, which leads to increased research efficiency.

[0069] In addition, in one variant of the method, before clamping the cuff 2 with the sample 4 by the pressure providing device 5, the fixation of the sample 4 is adjusted. The fixation setting serves to ensure tighter contact of the samples 4 with each other and between the pressure providing devices 5, which increases the efficiency of research due to the reliability of the data obtained. Reliability in this case is achieved due to the close contact of samples 4 with each other and the cuff 2 clasping them for the reasons described earlier.

[0070] In the presented best-of-breed implementation, the system for examining porous samples operates as follows. Sample 4 or a column of samples 4 is placed in a cuff 2 with electrodes located on it, ensuring tight contact of samples 4 with each other. Next, the cuff 2 is placed in the holder 1, and the cuff 2 is clamped on both sides by two plungers 5. After that, the flanges 6 are tightly screwed to the body 3 together with the connection of the locking elements 11 with the sector grooves 12. Then the fixation of the cuff 2 and samples 4 is adjusted using a screw pressing 10. Next, holder 1 is placed in chamber 14 on supports 19 and fixed tightly. After that, hydraulic oil 13 is supplied through the pressure supply lines 7, filling the holder 1. Next, the set temperature is set and maintained using thermal resistances and thermistors located on the mounts 9, and the chamber 14. At the next step, the displaced and displacing fluids are supplied, for example , oil and water through fluid supply lines 8 using a hydraulic pressure supply system (not shown). Then, using a rotating mechanism 15, made in the form of a plate 18 with supports 19, a bearing unit 17 and an axis 16, the holder is rotated, for example, 90 degrees counterclockwise. The dynamics of fluid displacement movement and other properties of column 4 are studied using signals from electrodes placed on collar 2, which make it possible, among other things, to construct a three-dimensional model of the electrical resistivity of the medium, determine the position of the front of the displacing fluid in the porous sample 4, and calculate the saturation of porous samples 4 displaced and displacing fluids. The collected information is transferred to a personal computer for subsequent processing and storage. At the end of the research, if necessary, the holder 1 is easily and quickly disassembled due to the presence of grooves 12 and elements 11, and samples 4 are replaced.

[0071] Thus, the mentioned elements directly affect the technical result, which consists in increasing the efficiency of studies of filtration formation processes, including by expanding the functionality of the system for studying porous samples and increasing the speed of research.

[0072] These application materials provide a preferred disclosure of the implementation of the claimed technical solution, which should not be used as limiting other, private embodiments of its implementation, which do not go beyond the scope of the requested scope of legal protection and are obvious to specialists in the relevant field of technology.

Claims (24)

1. A porous sample holder filled with hydraulic fluid and containing at least one cuff located inside the holder body and into which at least one porous sample is placed, wherein the cuff with the sample is limited on both sides by a pressure device, and the body is limited on two sides sides by flanges in such a way that at least one of the flanges is connected to a pressure supply device communicated with the holder through at least one pressure supply line and fluid supply lines through which the displacement and displacement fluids pass through the porous sample, while the supply device pressure has a bayonet connection with flanges, made in the form of at least one locking element on the pressure supply device and at least one sector groove on the flanges, complementary to the locking element. 2. A porous sample holder according to claim 1, characterized in that the pressure supply device is made in the form of two plungers. 3. A holder for porous samples according to claim 1, characterized in that the pressure supply device contains fastenings for temperature measuring instruments. 4. A porous sample holder according to claim 1, characterized in that the pressure supply device is configured to adjust the position of the porous sample. 5. The porous sample holder according to claim 1, characterized in that at least one flange is removable. 6. A porous sample holder according to claim 1, characterized in that measuring and injection electrodes are placed on the cuff at a certain distance. 7. A porous sample holder according to claim 1, characterized in that from 1 to 6 porous samples are placed in the cuff. 8. Porous sample holder according to claim 1, characterized in that hydraulic oil is used as a hydraulic fluid. 9. A system for studying porous samples containing at least one holder for porous samples, a chamber in which the holder is placed, and a system for providing hydraulic pressure communicated with the chamber and the holder, wherein the chamber is configured to rotate the holder at a given angle inside it due to the rotary a mechanism made in the form of an axis, a bearing unit and a plate on which the holder is placed, and the device for ensuring pressure of the holder has a bayonet connection to the flanges of the holder. 10. The system for studying porous samples according to claim 9, characterized in that the chamber is additionally configured to regulate the specified temperature. 11. The system for studying porous samples according to claim 9, characterized in that the holder in the chamber is fixed on supports. 12. A method for studying porous samples, in which: - at least one porous sample is placed in the cuff, - the cuff with the sample is limited by a pressure device on both sides, - the holder and pressure supply device are filled with hydraulic fluid using a pressure supply line, - the displaced and displacing fluids are supplied in turn to the sample through the liquid supply lines, - provide rotation of the camera with the holder located inside it at a given angle due to a rotating mechanism made in the form of an axis, a bearing unit and a plate on which the holder is placed, - collect information about the properties of the sample. 13. The method for studying porous samples according to claim 12, characterized in that the chamber is additionally set to a predetermined temperature. 14. The method for studying porous samples according to claim 12, characterized in that before limiting the cuff with the sample with a pressure device, the sample fixation is adjusted. 15. A method for studying porous samples according to claim 12, characterized in that information is collected using electrodes placed on the cuff. 16. The method for studying porous samples according to claim 15, characterized in that, based on the results of collecting information, a three-dimensional model of the electrical resistivity of the medium is additionally constructed. 17. The method for studying porous samples according to claim 12, characterized in that they additionally determine the position of the front of the displacing fluid in the porous sample and calculate the saturation of the porous samples with the displaced and displacing fluids. 18. The method for studying porous samples according to claim 12, characterized in that it additionally provides the ability to transfer the obtained digital data to a personal computer for subsequent processing and storage.