BR102016021330A2 - METHOD OF PRODUCTION OF SYNTHETIC PERMOPOROUS PROOF BODIES WITH CONTROLLED POROSITY FOR PHYSICAL SIMULATION OF UNDERGROUND FLUID FLOW - Google Patents

Abstract

Method for the production of controlled porosity standard permeable porous specimens for the physical simulation of groundwater flow, consisting of the production of permeable porosity specimens with controlled porosity and permeability using 3d printers. This method makes it possible to reproducibly construct permoporous specimens that meet pre-established porosity and permeability values and thus can be used as synthetic physical standards for the physical simulation of fluid flow in pores of rocks. underground. The high level of automated control allows not only homogeneous permoporous specimens to be printed in a controlled manner, but also heterogeneous and anisotropic specimens.

Description

(54) Title: METHOD OF PRODUCTION OF PERMOPOROUS PROOF BODIES SYNTHETIC PATTERNS WITH CONTROLLED POROSITY FOR PHYSICAL SIMULATION OF UNDERGROUND FLUID FLOW (51) Int. Cl .: B33Y 50/00; B33Y 80/00; G01N 1/28; G01N 08/15; G01N 33/24; (...) (52) CPC: B33Y 50/00, B33Y 80/00, G01N 1/2806, G01N 15/08, G01N 33/24, E21B 49/00 (73) Holder (s): TECHNOLOGY CENTER OF INFORMATION RENATO ARCHER - CTI (72) Inventor (s): JORGE VICENTE LOPES DA SILVA; PAULO DORE FERNANDES;

MARCELO FERNANDES DE OLIVEIRA; IZAQUE ALVES ΜΑΙΑ; PAULO INFORÇATTI NETO; PEDRO YOSHITO NORITOMI; DANIEL TANORI KEMMOKU (74) Attorney (s): FLÁVIA SALIM LOPES (57) Summary: METHOD OF PRODUCTION OF PERMANEOUS PROOF BODIES SYNTHETIC PATTERNS WITH CONTROLLED POROSITY FOR PHYSICAL SIMULATION OF FLUID FLOORING OF SUBSTANCES, SUBSTANCES, SUBSTANCES, SUBSTANCES, SUBSTANCES, SUBSTANCES, SUBSTANCES, with controlled porosity and permeability, using 3D printers. This method makes it possible to construct, in a reproductive way, permoporous specimens that meet pre-established porosity and permeability values and that, in this way, can be used as synthetic physical standards for physical simulation of fluid flow in the pores of rocks underground. The high level of automated control allows not only homogeneous permoporous specimens to be printed in a controlled manner, but also heterogeneous and anisotropic specimens.

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METHOD OF PRODUCTION OF PERMOPOROUS BODIES

SYNTHETIC PATTERNS WITH CONTROLLED POROSITY FOR

PHYSICAL SIMULATION OF UNDERGROUND FLUID FLOW

Field of the invention [001] The present invention refers to a method of fabricating permoporous specimens for use as standards in physical simulation of fluid flow in underground rocks. This method is characterized by automated control of dimensions, geometries, interconnections and spatial distribution of pores. Pores and their interconnections define two important physical characteristics that are porosity and permeability. Porosity is defined as the percentage between the empty volume and the total volume of the rocks. Permeability is related to the flow of fluids through the interconnections between the pores. The term permoporosity has been used in Brazil to refer to permeability and is being used in the present invention.

Description of the state of the art [002] The concepts of porosity, permeability and permoporosity are decisive in the field of oil and gas exploration and production, and also in other areas of mineralogy such as the exploration and production of water from aquifers. This is because the fluids to be explored are conditioned inside the pores of the rocks. In the case of oil and gas exploration, these rocks are usually known as reservoir rocks.

[003] In the case of exploration and production of oil fields, to increase the recovery of oil and gas, it is necessary to move the oil from the pores towards the production well by means of pressurized injection of fluids in the reservoir rocks, using a set of technologies known as EOR, which stands for “Enhanced Oil Recovery”. This injection of fluids underground is done through wells located at the perimeter of the oil field. Steam, salt water, polymers, carbon dioxide are

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Ί / 10 examples of these so-called injection fluids.

[004] To determine which are the best EOR technologies, tests are conducted in the laboratory to identify which fluids are most easily drained through a given rock sample. A test called “rock core flooding” is commonly used in the oil industry to determine the porosity and permeability of samples of reservoir rocks to air, water, oil and also to various injection fluids. The porosity and permeability values are used in simulations that will indicate the EOR technology to be used. For these simulations to be the most realistic, in the sense of maximizing oil production, it is necessary a large number of permoporous specimens of standards that serve as a reference. The availability of these specimens is the condition that allows EOR tests, performed in different laboratories, to be compared.

[005] Natural specimens, that is, obtained from rocks originating from nature, have been used as standards for the tests of “rock core flooding” and, therefore, of the EOR, because they are considered homogeneous. This condition of homogeneity is based on a statistical evaluation that considers as a sample space a large number of permoporous specimens obtained from the outcrops of these rocks. The homogeneous characteristic is defined here as the existence of very close permeability values in any region of the outcrop.

[006] A concept of a standard based on statistics causes many inaccuracies and doubts about experiments that use this standard. In the specific case of natural rocks, these inaccuracies and doubts become even greater because, it is intuitively known, that the probability of finding two samples of rocks that are exactly the same is null. In addition, these natural rocks have limitations because those obtained from a single outcrop do not meet all permeability ranges that are of interest to the oil and gas exploration and production industry.

10/24 / 10 [007] The low reproducibility of the porosity and permeability values obtained by the “rock core flooding” test for different natural permoporous specimens, even from a single outcrop, has stimulated the development of permoporous specimens synthetics to be used as reference standards in EOR simulations, replacing natural permoporous specimens. The control of the synthesis or construction process allows obtaining permoporous specimens for the EOR simulations with homogeneity that becomes all the more reproductive as the control over the construction process of the porous matrix increases.

[008] An advantage of synthetic permoporous specimens over natural ones is the possibility of adding, in a controlled and reproductive way, heterogeneities and anisotropies. Heterogeneity is understood as any discontinuity in the structure of the material, such as multiple porosities, fractures, caves, faults and pore obstruction. Anisotropy is understood as a change in material property with a change in direction. These heterogeneities and anisotropies can increase or decrease the flow of fluids in relation to homogeneous and isotropic bodies.

[009] The most commonly used methods of construction of said synthetic permoporous specimens are handcrafted and involve the use of granular materials such as sand and glass spheres. Depending on the degree of adhesion between the grains, these specimens are classified as unconsolidated and consolidated. In the unconsolidated specimens, the grains are compacted inside a hollow cylinder without promoting adhesion between them, either by chemical means, using a binding agent, or by physical means such as sintering and / or compression. In the consolidated specimens, the grains are adhered by chemical or physical processes, becoming a single piece, with all the grains joined together.

11/24 / 10 [010] Synthetic permoporous specimens can, instead of grains, be constructed from raw material in the form of sheets that are stacked and pressed. For example, specimen formed by stacking cellophane to simulate the semi-permeability characteristic of a type of rock called shale (Muniz E.S., Fontoura, S. A. B., Duarte, R. G, Muniz, C.S, Research Gate). The semi-permeability property is characterized by the passage of water through the pores of a material but restricting the passage of ions. Another type of synthetic specimen used in EOR does not include pores but parallel microchannels constructed and subsequently sealed in transparent plastic material (Park, DS; King, S .; Thomson, KE; Wilson CS; Nikitopoulos D. E, Proceedings of the ASME , Flow Visualization in Artificial Porous Media from Microfluidic PMMA Devices, International Mechanical Engineering Congress and Exposition, 2011, vol. 6, 1159-1166).

[011] The methods of production of synthetic permoporous specimens, consolidated and unconsolidated mentioned above, have failed to establish themselves as standards due to the fact that they are built by hand, that is, without automation. The artisanal character determines two main limitations for these methods: (a) low reproducibility of their porosity and permeability values, and (b) low production volume to meet the worldwide demand for EOR simulations. Due to these limitations, the method based on the extraction of permoporous specimens from nature has been maintained as the state of the art for producing standards for the EOR, although they still do not present the desired conditions for standards. The extraction of natural permoporous specimens occurs in a few existing outcrops, mainly in the United States. The most important outcrops are those known as berea sandstone (berea sandstone), baker dolomite (dolomite baker) and Indian limestone (Indian limestone).

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Objectives of the invention [012] In view of the above, it is the first objective of the present invention to provide synthetic permoporous specimens to serve as standards for EOR simulations. Those “Permoporous Synthetic Standards Test Bodies” that define this first objective will be called hereafter by its acronym CP3S.

[013] It is the second objective of the present invention that said CP3S can also be used for any other application related to the exploration of underground fluids stored inside pores.

[014] It is the third objective of the present invention that said CP3S be produced in an automated way, by means of three-dimensional printing, hereinafter called 3D printing, to have controlled permoporosity, that is, with control of dimension, geometry, interconnections and spatial distribution of the pores.

[015] It is another objective of the present invention to ensure that said CP3S are homogeneous or heterogeneous, isotropic or anisotropic.

[016] It is yet another objective of the present invention to ensure that said CP3S allow the survey of reproductive curves of permeability X porosity.

[017] It is another objective of the present invention that CP3S can be constructed with different materials, such as, polymers, ceramics, metals, composites, etc.

[018] It is a further objective of the present invention that said CP3S can be built with 3D printing, using different physicochemical processes or devices for consolidating the printing material in the form of CP3S. These processes or devices will hereinafter be called 3D printing agents and are as follows: electron beams, light beams from lamps, laser beam beams, inkjet print head, extruder head, cutting blade, or any other physical phenomenon or device or combination of them used for layer construction

13/24 / 10 the layer or other construction based on the addition of material.

[019] It is a further objective of the present invention that said CP3S can be constructed with various forms of raw material, such as, powder, paste, filament, liquid, etc.

[020] It is yet another objective of the present invention to ensure that said provision of CP3S is done in a reproducible manner.

[021] It is yet another objective of the present invention that said CP3S can be produced in large quantities.

Brief description of the invention [022] The above objectives are achieved by the present invention through the generation of digital models of the CP3S followed by an automated method of construction.

[023] According to another characteristic of the invention, said digital models of CP3S may include or, alternatively, not include the modeling of the characteristics of permoporosity - pore size, pore geometry, interconnections between pores and spatial distribution.

[024] According to another characteristic of the invention, said automated method of construction is 3D printing.

[025] In accordance with another characteristic of the invention, said 3D printing method physically reproduces and in a controlled manner the permoporosity characteristics planned in the digital models of the CP3S.

[026] According to another characteristic of the invention, in the event that the referred 3D printing method does not use a digital model containing the desired physical characteristics of the permoporosity, the printing control is carried out by means of process parameters.

[027] In accordance with yet another characteristic of the invention, said CP3S, constructed by means of 3D printing, are versatile in terms of degree of homogeneity and isotropy.

[028] In accordance with yet another characteristic of the invention, said CP3S, built by means of 3D printing, allow the lifting of curves

14/24/10 reproductive permeability X porosity.

[029] According to another feature of the invention, CP3S can be built by different 3D printing agents individually or in combination.

[030] According to yet another feature of the invention, 3D printing agents are: electrons, light beams from lamps, laser beam beams, inkjet print head, extruder head, cutting blade, etc.

[031] In accordance with yet another characteristic of the invention, said CP3S can be constructed with different materials, such as, polymers, ceramics, metals, composites, etc.

[032] In accordance with yet another feature of the invention, said CP3S can be constructed with various forms of raw material, such as, powder, paste, sheet, filament, liquid, etc.

[033] According to yet another characteristic of the invention, the permoporosity characteristics of said CP3S are reproducible.

[034] According to yet another characteristic of the invention, said CP3S, can be produced in large quantities and in a reproductive way.

[035] Advantageously, the described method allows the precise and reproductive control of the desired permoporosity characteristics during the manufacturing process of the CP3S.

Brief description of the figures [036] The characteristics and advantages of the present invention will be better understood by describing a preferred embodiment, given by way of illustration and not limiting, and the figures that refer to it, in which:

[037] Figure 1 is a representation of the method described.

[038] Figure 2 illustrates a permoporous specimen produced according to the method described in this patent.

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Detailed description of the invention [039] The method for producing CP3S described in the present invention is 3D printing, also known as rapid prototyping, digital fabrication, digital fabrication, additive fabrication and additive fabrication, among others. Additive manufacturing is the expression adopted by the F 2792 standard of the American Society for Testing Materials - ASTM. This method is based on the construction of parts layer by layer, controlled by computer from a digital model, as shown in figure 1. There are two types of permoporosity control for the generation of CP3S: permoporosity controlled by process parameters and controlled permoporosity by modeling. In the permoporosity controlled by process parameters, the individual pores are not physical reproductions of digital pores designed in the CP3S digital model. In the model-controlled permoporosity, the individual pores are physical reproductions of pores designed in the CP3S digital model. Both in one control and in the other, the reproducibility of the permoporosity is guaranteed by the automation of that method. It is this automation that distinguishes the method of the present invention from other methods of production of existing synthetic permoporous specimens.

[040] With the resources coming from these two automated controls for the generation of permoporosity, individually or in combination, it is possible to construct reproductive curves of permeability versus porosity, from a set of CP3S of different porosities and permeabilities.

[041] The automated control over the properties of CP3S, obtained by 3D printing, makes it possible to replace the permoporous specimens of natural patterns, used in physical simulations of fluid flow in the oil and gas exploration and production industry, by synthetic analogs . The CP3S built with 3D printing, due to the precision and high degree of reproducibility, provide advantages in these simulations compared to the technologies for the production of permoporous, natural or

16/24 / 10 synthetic, already existing. Additionally, it enables other physical simulations besides the EOR involving aspects of permoporosity, within the core of oil and gas exploration, such as natural sealing membrane, well drilling, synthetic sealing by cementing well walls and propping material for filling fractures.

[042] In addition to the area of oil and gas exploration, the construction of CP3S using 3D printing can be applied in simulations of exploration and production of water in aquifers.

[043] Thus, in the present invention, 3D printing enables the construction of CP3S within the desired porosity and permeability ranges, from the control of the permoporosity by process parameters and control of the planned porosity by computational modeling. The high level of automated control allows not only homogeneous permoporous specimens to be printed, but also heterogeneous permoporous specimens, acting on the modulation of their properties according to the spatial orientation to present isotropic and anisotropic behavior.

[044] Patents for 3D printing applications in the oil and gas exploration field are recent - WO 2014/047003 A1, US 2013/0180327 A1 and CN103806905A. They are based on the physical reproduction, on a reduced scale, of a portion of the reservoir rock, based on 3D images obtained with equipment equipped with sensors. None of these patents addressed the construction of permoporous characteristics (size, geometry, connections and spatial distribution of the pores) as presented in the method that constitutes the present invention. The smallest printed structure presented in the aforementioned patents was that of rock fractures resulting from the hydraulic fracturing process.

[045] The method described in the present invention, illustrated in figure 1, consists of digital modeling, performed on a computer (1), of a unit of the

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CP3S (2). This modeling generates a data file recognizable by a 3D printer (3). Fed with said data, a 3D printer (3) produces the desired CP3S (4) by adding layers (4). As a final result, we have the CP3S (5), completely printed (3), ready to be used in the desired tests and simulations.

[046] Figure 2 illustrates a specimen (10), made by 3D printing, with pores (11) standardized according to the desired permoporosity characteristics, obtained by controlling process parameters or by pore modeling.

[047] 3D printing uses different 3D printing technologies distinguished by the 3D printing agents used such as: electron beams, light beams from lamps, laser beam beams, inkjet print head, extruder head, blade cutting, etc. Alternatively, these 3D printing technologies may be those contained in the “F2792 Standard Terminology for Additive Manufacturing Technologies ^{11” standard,} which classifies 3D printing technologies in the following categories: material extrusion, material jet, binder jet, sheet lamination, light curing in vat, powder bed melting and direct energy deposition.

[048] Likewise, CP3S (5) can be made of any material, polymers, ceramics, metals, composites, etc. The choice of material depends on the characteristics and conveniences that said specimen must have. These characteristics and conveniences also define the form of raw material to be used: powder, paste, filament, liquid, sheet, granules, etc.

[049] Although the invention has been described on the basis of some preferred exemplary embodiments, those skilled in the art may introduce modifications within the basic inventive concept. Accordingly, the invention is defined by the following set of claims.

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Claims (28)

1. METHOD OF PRODUCTION OF PERMOPOROUS PROOF BODIES SYNTHETIC PATTERNS WITH CONTROLLED POROSITY FOR PHYSICAL SIMULATION OF UNDERGROUND FLUID FLOW, characterized by using 3D printing. 2. METHOD, according to claim 1, characterized in that said specimens have a porous organization that can be reproduced as many times as necessary. 3. METHOD, according to claims 1 and 2, characterized by reproducible porous organization that has size, geometry, connections between pores and spatial distribution of pores controlled by computer. 4. METHOD, according to claims 1, 2 and 3, characterized in that said specimens, with the same porous organization, present the same absolute permeability for the same fluid. 5. METHOD, according to claims 1, 2 and 3, characterized in that said specimens, with the same porous organization, present the same relative permeability for the same mixture of fluids. 6. METHOD, according to claims 1, 2 and 3 characterized by allowing the survey of reproductive curves of permeability versus porosity. 7. METHOD, according to claim 1, characterized by allowing the construction of said specimens with different 3D printing technology. 8. METHOD, according to claims 1 and 7, characterized by producing specimens made of different materials, such as polymers, ceramics, metals, composites, etc. 9. METHOD, according to claims 1, 7 and 8, characterized by using one or more of the following 3D printing agents: ray source 19/24 2/4 laser, inkjet print head, extruder head, cutting blade or any other printing agent included within the “F2792 Standard Terminology for Additive Manufacturing Technologies ”. 10. METHOD, according to claims 1, 7, 8 and 9 characterized by allowing the construction of said specimens with various forms of raw materials, such as, powder, paste, filament, liquid etc. 11. METHOD, according to claim 1, characterized by producing, in an automated way, homogeneous and heterogeneous specimens. 12. METHOD, according to claims 1 and 11, characterized by producing said specimens with the same porosity in all its different regions. 13. METHOD, according to claims 1 and 11, characterized by producing said homogeneous specimens with the same chemical composition in all its different regions. 14. METHOD, according to claims 1 and 11, characterized by producing said specimens with the same absolute and relative permeability, in all its different regions. 15. METHOD, according to claims 1 and 11, characterized by producing said specimens with elements of heterogeneity cracks, blockages - within the porous matrix during the 3D printing process. 16. METHOD, according to claims 1, 11 and 15, characterized by producing specimens with porosity gradients. 17. METHOD, according to claim 1, characterized by producing, in a controlled manner, said anisotropic specimens in all directions. 18. METHOD, according to claims 1 and 2, characterized by producing, in a controlled manner, said specimens from modeling 20/24 3/4 of the porous organization or only from the variation of the process parameters. 19. METHOD, according to claim 1, characterized by producing, in a controlled manner, said specimens with modulated porosity. 20. METHOD, according to claim 1, characterized in that said specimens are applied to the physical simulation of oil and gas production. 21. METHOD, according to claims 1 and 20, characterized in that said specimens are applied to the evaluation of the storage potential of fluids in rock. 22. METHOD, according to claims 1 and 20, characterized in that said specimens are applied to studies of permeability of sealing rock. 23. METHOD, according to claims 1 and 20, characterized in that said specimens are applied to studies of the cementation process of wells. 24. METHOD, according to claims 1 and 20, characterized in that said specimens are applied to studies of propant material. 25. METHOD, according to claims 1 and 21, characterized in that said specimens are applied to water exploration in aquifers. 26. METHOD, according to claims 1 and 24, characterized in that said specimens are applied to the reproduction of fractures obtained by the method of stimulation by hydraulic fracturing. 27. METHOD, according to claims 1, 16 and 17, characterized in that said specimens are applied to the reproduction of fractures obtained by the method of stimulation by acid fracturing. 28. METHOD, according to claims 1, 16 and 17, 21/24 4/4 characterized by said specimens being applied to the reproduction of natural fractures, caves, faults and other geological anomalies, represented by heterogeneities and anisotropies, found in underground rocks. 22/24 1/1