EA030820B1 - Method for production of nano-fluid with gas nano-bubbles - Google Patents

Abstract

The invention is related to a method for production of nano-fluid with gas nano-bubbles and can find application in the petroleum industry, in particular, to be used as a fluid medium for oil displacement and extraction, especially in development of low-permeability oil fields. The objective of the invention is development of a method for production of stable nano-fluid and provision of efficient formation of stable bubbles of sizes in the nanometric range. Said objective is attained by provision of a method for production of nano-fluid with gas nano-bubbles comprising mixing of gas and liquid, wherein, after mixing gas and fluid, a pressure higher than the pressure of saturation of liquid with gas (Ps) is maintained. Pressure in the gas-liquid mixture is maintained at a level of 1.1-2.0 Ps. The ratio of gas volume and liquid volume is determined from Henry's law at the pressure of liquid saturation with gas. The ratio of gas volume and liquid volume is determined from the curve of gas solubility in liquid at the pressure of liquid saturation with gas.

Description

The invention relates to a method for producing nanofluid with gas nanobubbles and may find application in the oil industry, specifically for use as a fluid in displacement and oil production, especially in the development of low-permeability oil fields. The objective of the invention is to develop a method of obtaining sustainable nanofluid and ensuring the effective formation of stable bubbles with a size of nanometric range. The task is achieved by the fact that in the method of producing nanofluid with nanobubbles of gas, including mixing gas and liquid, after mixing gas and liquid in a gas-liquid mixture, the pressure is maintained above the saturation pressure of the liquid with gas (PH). The pressure in the gas-liquid mixture is maintained at 1.1-2.0 pH. The ratio of the volumes of gas and liquid is determined from Henry's law at the pressure of saturation of the liquid with gas. The ratio of the volumes of gas and liquid is determined by the solubility curve of the gas in the liquid at the pressure of saturation of the liquid with gas.

030820 Bl

030820 B1

The invention relates to a method for producing nanofluid with gas nanobubbles and can be used in the oil industry, specifically for use as a fluid for displacing and extracting oil, especially in the development of low-permeability oil fields.

The known composition of the nanofluid for processing the bottomhole zone of oil reservoirs, prepared on the basis of an aqueous solution of anionic surfactants and their compositions with the addition of nanoparticles of light non-ferrous metal 50-200 nm in size [1].

The disadvantage of the invention is that the use of prepared by the proposed method nanofluid is complicated by the fact that when it is injected into the reservoir, it has a relatively high residual resistance to flow.

Known methods for producing nanosized metal powders using an induction plasma torch [2].

The disadvantages of the methods is the impossibility of preventing the formation of cakes and agglomerates of condensed powders and the difficulty of removing nanopowder deposits from the surfaces of the reactor.

A method of producing nanofluid for enhanced oil recovery is known, including adding deionized water to the nanopowder and conducting ultrasonic dispersion at room temperature, dissolving the silane coupling agent in absolute ethanol; mixing the nano alkaline solution with a solution of ethanol silane, filtering, washing with an anhydrous solvent many times and drying at 60-70 ° C for 12 hours to obtain modified nanoparticles; heating to a range of 60-75 ° C using a water bath, adding a mixed solution of surfactant and polyethylene glycol, mechanical stirring for 6-8 hours, washing the stirred dispersion 2-3 times, adjusting the pH to a range of 8-9 and adding deionized water [3].

The disadvantage of this method is the difficulty of obtaining water-based nanofluid and the use of expensive reagents.

The closest to the proposed invention is a method for producing nanofluid with nanobubbles of gas, including mixing gas and liquid [4].

The disadvantage of this method is that the nanobubbles are not stable and quickly collapse.

The application of the proposed method is also complicated by the need to use a special device for the generation of nanofluid with gas nanobubbles.

The objective of the invention is to develop a method of obtaining sustainable nanofluid and ensuring the effective formation of stable bubbles with a size of nanometric range.

The task is achieved by the fact that in the method of producing nanofluid with nanobubbles of gas, including mixing gas and liquid, after mixing gas and liquid in a gas-liquid mixture, the pressure is maintained above the saturation pressure of the liquid with gas (PH).

The pressure in the gas-liquid mixture is maintained at 1.1-2.0 pH.

The ratio of the volumes of gas and liquid is determined from Henry's law at the pressure of saturation of the liquid with gas.

The ratio of the volumes of gas and liquid is determined by the solubility curve of the gas in the liquid at the pressure of saturation of the liquid with gas.

Anionic, cationic or non-ionic surfactants are additionally introduced into the gas-liquid mixture.

The technical result consists in developing a method for producing nanofluid with stable nanobubbles of gas with a size of the nanometric range (up to 100 nm).

In the known method, the size of the bubbles decreases, however, at the same time a significant amount of energy is expended on their formation and the formation of stable bubbles with the size of the nanometric range is not ensured.

In the proposed method, nanobubbles are formed in a gas-liquid mixture, if the pressure in the gas-liquid mixture is maintained above the liquid's saturation pressure with gas (1.1-2.0 Rn).

By maintaining the pressure of the gas-liquid mixture above the liquid’s saturation pressure with gas, it is possible to obtain subcritical gas nuclei (bubbles) of the nanometric range. The stability of subcritical bubbles is ensured by the presence of electric charges on their surface [5]. Due to the presence of an electric charge, the nanobubble, resulting from the application of the proposed method, becomes resistant to collapse. The surface electric charge makes the main contribution to the formation and stabilization of nanobubbles in a liquid at a pressure P above the saturation pressure Рн (1.1-2.0 Рн) of a gas in a liquid.

From the law of Henry determine the ratio of the volumes of gas and liquid at the pressure of saturation of the liquid gas. The required ratio of the volumes of gas and liquid is also established according to the solubility curve of the gas in the liquid at the pressure of liquid saturation with gas. With this ratio of volumes of gas and liquid and while maintaining the pressure above the saturation pressure of the liquid with gas (1.1-2.0 Rn), the resulting gas-liquid mixture acquires the properties of a stable nanofluid.

- 1 030820

The stability of nanobubbles can be enhanced by introducing a surfactant into the gas-liquid mixture. Therefore, in order to regulate the properties of the nanofluid, an anionic, cationic or non-ionic surfactant is additionally introduced into the gas-liquid mixture.

Any gas, in particular air, natural gas, methane, nitrogen, carbon dioxide and others can be used as a gas for the production of a nanofluid.

Polar and non-polar solvents, in particular water, oil, etc. can be used as a liquid for the production of a nanofluid.

The method of producing nanofluid with gas nanobubbles is as follows:

The liquid is placed in a special container, including an internal paddle stirrer. The container also includes a gas injection valve, a pressure control valve, a temperature sensor, and a pressure gauge. The gas stream is injected through the pipeline. Gas-liquid mixture is stirred in continuous mode. The gas stream is combined with a liquid under pressure equal to a pressure higher than the saturation pressure of the liquid with gas (PH). In this case, a dispersion of gas bubbles in the liquid phase is formed in the vessel. Monitoring the pressure of the gas-liquid mixture in the tank is carried out using pressure gauges. The temperature of the gas-liquid mixture is maintained at the required level using a device for heating and / or cooling and temperature measuring means. By maintaining the pressure in the gas-liquid mixture above the liquid’s saturation pressure with gas (PH), a stable nanofluid is created, including stable gas bubbles with nanometer-size range. The volume of gas-liquid mixture is regulated by the pumped gas volume. Keeping the pressure in the gas-liquid mixture at the level of 1.1-2.0 Rn, determine the ratio of the volumes of gas and liquid from Henry's Law or from the solubility curve of gas in a liquid at a pressure of saturation of the liquid with gas. If it is necessary to adjust the properties of the nanofluid, the gas-liquid mixture is additionally treated with anionic, cationic or non-ionic surfactant.

To study the filtration of nanofluids obtained by the proposed method and the prototype, experiments were conducted on a laboratory setup. The formation model was simulated in a high-pressure filtration column with a porous medium composed of quartz sand fractions up to 0.1 x10 ^-3 m. Porosity and air permeability were determined using a known technique, which were 0.256 and 0.3 microns, respectively. The reservoir model was saturated with transformer oil at constant evacuation and temperature control (T = 308K). A gas-liquid mixture consisting of natural gas and water was prepared in a 2.4 m ^-3 PVT bomb. The gas factor gas-liquid mixture G = 1 m ³ / m ³ . The saturation pressure of the gas-liquid mixture was determined by the volumetric method and was equal to Рн = 3.0 MPa. Transformer oil was displaced by a gas-liquid mixture at a pressure P much higher than the saturation pressure Pn (P = 3 Pn), while displacement continued until the output of the pure gas-liquid mixture at the outlet of the column. The gas-liquid mixture was filtered under a constant pressure drop to establish a constant flow rate. The pressure of the reservoir model again rose to P = 3 PH, the inlet and outlet of the column were blocked, and it was maintained in this state for 24 hours. The fluid flow rate was again determined at various pressure drops (at a pressure above the saturation pressure).

The results of the experiments are shown in the table, which shows the change in the flow rate of the nanofluid Q depending on P / PH. To compare the obtained results, all experiments were carried out in the same reservoir model in the following sequence: nanofluid without surfactant additives, with surfactant additives, and the prototype nanofluid.

R / PH Nanofluid consumption without surfactant additive, Q-10 ' ⁸ m7c Consumption of nanofluid with surfactant additive, Q-lO’V / c 0.01% 0.02% 0.035% 1.1 1.0 1.1 1,3 1.2 1,3 1.2 1.0 1.2 1.1 1.5 1.0 0.95 0.9 0.95 1.7 0.8 0.65 0.75 0.94 2.0 0.6 0.55 0.7 0.92 2.5 0.5 0.5 0.65 0.91 Prototype 0.5-0.8 -

From the table it can be seen that at P / PH = 1.1-2.0, an increase in the consumption of the nanofluid without the addition of surfactants is achieved by almost 2 times. Improving the filtration characteristics of a porous medium while maintaining a pressure of 1.1-2.0 Rn occurs due to the formation of nanobubbles of gas to 100 nm, which leads to a decrease in hydraulic resistance and an increase in filtration flow rate of the nanofluid. Small surfactant additives (C = 0.01; 0.02;) have little effect on the change in the value of the flow rate Q. The nanofluid in the prototype was also investigated in a similar way. The known device (prototype) generates a nanodispersion containing gas nanobubbles with a diameter of 200 nm. The compressed gas-liquid mixture passes through the nanofuse valve. The particle size obtained by nanodispersions containing

- 2 030820 nanoscale nanopubes, is the same as the width of the nanofuse valve (200 nm). In the well-known nanofluid (prototype), as the pressure level P <1.1 Rn decreases, a significant decrease in flow occurs and amounts to 40-50% of the flow rate achieved while maintaining the pressure of the nanofluid at 1.1-2.0 Rn according to the proposed method. When moving a known nanofluid (according to the prototype) through a porous medium, additional hydraulic resistances arise, which leads to a decrease in the flow rate.

LITERATURE

1. Patent RU No. 2434042, C09K 8/584, В82В 1/00, 2011.

2. US Patent No. 7967891, B22F 9/28, B22F 9/24, 2011; US Patent No. 7,501,599, C01B 13/14, C01B 13/30, 2009; US Patent No. 7208028, B22F 9/28, B22F 9/30, 2007; US Patent No. 7118724, В82В 3/00, СВВ 31/34, 2006.

3. CN Patent No. 103937478, Е21В 43/22, f09K 8/58, 2014.

4. US Patent No. 8726918, B01D 47/00, BB08B3 / 10, 2014.

5. Suleymanov B.A. Features filtering heterogeneous systems. M., IKI, 2006, pp.67-68.

Claims (4)

CLAIM 1. A method of producing a nanofluid with nanobubbles of gas to displace oil from the reservoir, including mixing gas and liquid, characterized in that after mixing gas and liquid in a gas-liquid mixture, the pressure is maintained above the saturation pressure of the liquid with gas (PH). 2. The method according to claim 1, characterized in that the pressure in the gas-liquid mixture is maintained at the level of 1.1-2.0 Ph. 3. The method according to claim 1, characterized in that the ratio of the volumes of gas and liquid is determined from Henry's law at the pressure of saturation of the liquid with gas. 4. The method according to claim 1, characterized in that the ratio of the volumes of gas and liquid is determined by the solubility curve of a gas in a liquid at a saturation pressure of liquid gas.