Oil-water emulsion breakup (OWEB) process and system

Abstract

An oil-water emulsion breakup system. In one embodiment, the system includes an oil-water mixture inlet line configured to receive an oil and water liquid mixture, which may be stabilized by hydrophobic nanoparticles, surfactants of low HLB value, or both. A water injection inlet in communication with the oil-water mixture inlet is configured to direct water into the oil-water mixture inlet. A water sensor is in communication with the oil-water mixture inlet to sense percentage of water in the mixture. A water injection valve in the water injection inlet is in communication with the water sensor. A liquid-liquid separator has an inlet configured to receive a combination of the oil and water mixture and the water, with the separator separating liquid into an oil phase and a water phase. An upper leg in communication with the liquid-liquid separator receives oil separated from the separator. A lower leg in communication with the liquid-liquid separator receives water separated in the liquid-liquid separator.

Claims

1. An oil-water emulsion breakup system, which system comprises: an oil-water mixture inlet line configured to receive an oil and water liquid mixture, stabilized by hydrophobic nanoparticles, surfactants of low hydrophilic-lipophilic (HLB) value, or both; a water injection inlet line in communication with said oil-water mixture inlet line at a junction configured to direct water into said oil-water mixture inlet line; a water sensor in communication with and located at said oil-water mixture inlet line configured to sense a percentage of water in said mixture, said water sensor upstream of said junction; a water injection valve in said water injection inlet line in communication with said water sensor; a controller in communication with said water sensor and said water injection valve, wherein said water injection valve is configured to adjust an amount of said water in response to said water sensor in order to promote separation; a liquid-liquid separator having an inlet configured to receive said-oil and water liquid mixture and said water, said liquid-liquid separator configured to separate liquid into an oil phase and a water phase; an upper leg in communication with said liquid-liquid separator configured to receive oil separated from said liquid-liquid separator; a lower leg in communication with said liquid-liquid separator configured to receive water separated in said liquid-liquid separator; a water recirculation line extending from said lower leg to said water injection inlet line; and a variable frequency drive pump on said water recirculation line positioned downstream of said lower leg and upstream of said junction, said variable frequency drive pump in communication with said water sensor.

2. The oil-water emulsion breakup system as set forth in claim 1 wherein said liquid-liquid separator is a cylindrical cyclone separator having a cylindrical body, a horizontal inlet and a tangential nozzle with an opening between 25 and 30 percent of the horizontal inlet cross-section.

3. The oil-water emulsion breakup system as set forth in claim 1 wherein said upper leg includes an oil control valve, an oil mass flow meter and an oil flow controller configured to control flow of oil.

4. The oil-water emulsion breakup system as set forth in claim 1 wherein said lower leg includes a water control valve, a water mass flow meter and a water flow controller configured to control flow of water.

5. The oil-water emulsion breakup system as set forth in claim 1 including a water recirculation controller in communication with said water sensor and said variable frequency drive pump.

6. The oil-water emulsion breakup system as forth in claim 1 wherein said oil and water mixture includes hydrophobic nanoparticles which are separated in said liquid-liquid separator.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 illustrates a simplified schematic diagram of a first preferred embodiment of an oil-water emulsion breakup system constructed in accordance with the present invention;

(2) FIG. 2 illustrates a schematic diagram of a second preferred embodiment of an oil-water emulsion breakup system constructed in accordance with the present invention;

(3) FIG. 3 illustrates a schematic diagram of a third preferred embodiment of an oil-water emulsion breakup system of the present invention; and

(4) FIG. 4 illustrates a bar-graph that describes the performance of the invented oil-water emulsion break-up process and system.

DETAILED DESCRIPTION OF THE INVENTION

(5) The embodiments discussed herein are merely illustrative of specific manners in which to make and use the invention and are not to be interpreted as limiting the scope.

(6) While the invention has been described with a certain degree of particularity, it is to be noted that many modifications may be made in the details of the invention's construction and the arrangement of its components without departing from the scope of this disclosure. It is understood that the invention is not limited to the embodiments set forth herein for purposes of exemplification.

(7) Referring to the drawings in detail, FIG. 1 illustrates a schematic diagram of a first preferred embodiment of an oil-water emulsion breakup system 10 constructed in accordance with the present invention.

(8) An oil-water mixture inlet line 12 is configured to receive an incoming oil and water liquid mixture, as shown by arrow 14, such as a mixture extracted from a subterranean reservoir. The mixture may be stabilized by hydrophobic nanoparticles, by surfactants of low hydrophilic-lipophilic balance or both.

(9) A water injection inlet line 16 in communication with said oil-water mixture inlet line 12 is configured to direct water into said oil-water mixture inlet line, as shown by arrow 18.

(10) A water sensor 20 in communication with said oil-water mixture inlet line 12 is configured to sense percentage of water by mass in the oil-water mixture. The water sensor 20 is upstream of the water injection inlet line 16.

(11) A water injection valve 22 is juxtaposed in the water injection inlet line 16. A controller 26 is in communication with the water injection valve 22 and in communication with the water sensor 20. Accordingly, the amount of water injected through the water injection inlet line 16 may be controlled.

(12) External water shown by arrow 18 is injected into the water injection inlet line 16 through the control valve 22 when the watercut sensor 20 at the oil-water inlet records watercut less than a setpoint watercut, in order to increase the water percentage and reduce emulsifier or stabilizing agent concentration in the system and thereby promote separation.

(13) A liquid-liquid separator 30 having an inlet is configured to receive the combination oil and water mixture and the injected water. The liquid-liquid separator 30 (shown in exploded view in FIG. 1) is configured to separate liquid into an oil phase and a water phase.

(14) In one configuration, the liquid-liquid separator 30 is a cylindrical cyclone separator having a horizontal inlet and a tangential nozzle with an opening between 25 and 30 percent of the horizontal inlet cross-section.

(15) The liquid-liquid separator 30 includes a vertical section that is equipped with a horizontal or near horizontal (with a downward incline of approximately 1%) inlet through which an oil-water mixture entrained with nanoparticles, surfactants, or both enters. A tangential nozzle with an opening of 25-30% of the inlet section cross-sectional area is placed at the end of the inlet line. The nozzle generates swirling flow in the separator body, generating centrifugal force that separates the oil and water phases radially. After separation, water flows through a lower leg outlet 34 as shown by arrow 44 while the oil exits through an upper leg outlet 32 as shown by arrow 46.

(16) The upper leg 32 in communication with the liquid-liquid separator 30 is configured to receive oil separated in the liquid-liquid separator. The lower leg 34 is in communication with the liquid-liquid separator 30 and is configured to receive water.

(17) The upper leg 32 includes an oil mass flow meter 36 and an oil control valve 38 configured to control flow of oil.

(18) A controller 37 is in communication with the oil mass flow meter 36 and oil control valve 38. The oil mass flow meter 36 also measures the density of the oil phase and communicates to the controller 37. If the density of oil is more than a setpoint density (corresponding to pure oil), the oil control valve will close sufficiently to obtain maximum flow rate of pure oil with density as close as possible to the setpoint density.

(19) The lower leg 34 includes a mass flow meter 40 and a water control valve 42 configured to control flow of water.

(20) A controller 41 is in communication with the water mass flow meter 40 and water control valve 42. The water mass flow meter 40 also measures the density of the water phase and communicates to the controller 44. If the density of water is less than a setpoint density (corresponding to pure water), the water control valve 42 will close sufficiently to obtain maximum flow rate of pure water with density as close as possible to the setpoint density.

(21) FIG. 2 illustrates a schematic diagram of a second preferred embodiment of an oil-water emulsion breakup system 50 constructed in accordance with the present invention.

(22) An oil-water mixture inlet line 52 is configured to receive an incoming oil and water liquid mixture, as shown by arrow 54, such as a mixture extracted from a subterranean reservoir.

(23) A water injection inlet line 56 in communication with said oil-water mixture inlet line 52 is configured to direct water into said oil-water mixture inlet line, as shown by arrow 58.

(24) A water sensor 60 in communication with said oil-water mixture inlet line 52 is configured to sense percentage of water by mass in the incoming oil-water mixture. The water sensor 60 is upstream of the water injection inlet line 56.

(25) A liquid-liquid separator 70 has an inlet configured to receive the combination oil and water mixture and the injected water. The liquid-liquid separator 70 is configured to separate liquid into an oil phase and a water phase.

(26) In one configuration, the liquid-liquid separator 70 is a cylindrical cyclone separator having a horizontal or near horizontal (with a downward incline of approximately 1%) inlet and a tangential nozzle with an opening between 25 and 30 percent of the horizontal inlet cross-section.

(27) The liquid-liquid separator 70 includes a vertical section equipped with a horizontal inlet through which an oil-water mixture entrained with nanoparticles, surfactants, or both enters. A tangential nozzle with an opening of 25-30% of the inlet section cross-sectional area is placed at the end of the inlet line. The nozzle generates swirling flow in the separator body, generating centrifugal force that separates the oil and water phases radially. After separation, water flows through a lower leg outlet 74 as shown by arrow 86 while the oil exits through an upper leg outlet 72 as shown by arrow 88.

(28) The upper leg 72 in communication with the liquid-liquid separator 70 is configured to receive oil separated in the liquid-liquid separator 70. The lower leg 74 is in communication with the liquid-liquid separator 70 and is configured to receive water.

(29) The upper leg 72 includes an oil mass flow meter 76 and an oil control valve 78 configured to control flow of oil.

(30) A controller 77 is in communication with the oil mass flow meter 76 and oil control valve 78. The oil mass flow meter also measures the density of the oil phase and communicates to the controller. If the density of oil is more than a setpoint density (corresponding to pure oil), the oil control valve will close sufficiently to obtain maximum flow rate of pure oil with density as close as possible to the setpoint density.

(31) The lower leg 74 includes a water mass flow meter 80 and a water control valve 82 configured to control flow of water.

(32) A controller 81 is in communication with the water mass flow meter 80 and water control valve 82. The water mass flow meter also measures the density of the water phase and communicates to the controller 81. If the density of water is less than a setpoint density (corresponding to pure water), the water control valve 82 will close sufficiently to obtain maximum flow rate of pure water with density as close as possible to the setpoint density.

(33) The water injection inlet line 56 is in communication with the lower leg 74. Water is recirculated from lower leg 74 back into the inlet line 52 utilizing a pump 84. The pump is equipped with a variable frequency drive (VFD).

(34) A controller 85 is in communication with the variable frequency drive pump 84 and with the water sensor 60. Accordingly, when the watercut sensor 60 records watercut less than a set point percentage of watercut, the pump speed is increased by the VFD pump 84.

(35) FIG. 3 illustrates a schematic diagram of a third preferred embodiment of an emulsion breakup system 90 of the present invention.

(36) An oil-water mixture inlet line 92 is configured to receive an incoming oil and water liquid mixture as shown by arrow 94, such as a mixture extracted from a subterranean reservoir.

(37) A horizontal pipe separator 96 is in communication with the oil-water mixture inlet line 92 to separate oil from the oil and water mixture by gravity, the horizontal pipe separator having an oil outlet line 98 and an oil-water mixture outlet line 100. In one arrangement, the horizontal pipe separator 96 has a diameter at least twice the inlet pipe line 92 diameter and the horizontal pipe separator has a length at least five times the inlet pipe line 92 diameter.

(38) A water sensor 102 in communication with said oil-water mixture inlet line 92 is configured to sense percentage of water by mass in the oil-water mixture. The water sensor 102 is upstream of said horizontal pipe separator 96.

(39) An oil valve 104 in the oil extraction line 98 is in communication with the water sensor 102. In one embodiment, a controller 106 is in communication with both the water sensor 102 and the oil valve 104. Accordingly, the amount of oil extracted is controlled based on the incoming water percentage.

(40) A liquid-liquid separator 108 includes an inlet configured to receive the combination oil and water mixture from the horizontal separator outlet 100 and is configured to separate liquid into an oil phase and a water phase.

(41) The liquid-liquid separator 108 is a cylindrical cyclone separator having a horizontal inlet and a tangential nozzle with an opening between 25 and 30 percent of the inlet cross-section. The nozzle generates swirling flow in the separator body, generating centrifugal force that separates the oil and water phases radially.

(42) An upper leg 110 in communication with the liquid-liquid separator 108 is configured to receive oil flow from the liquid-liquid separator 108.

(43) A lower leg 112 in communication with the liquid-liquid separator 108 is configured to receive water separated in the liquid-liquid separator 108.

(44) The horizontal pipe separator 96 is, thus, installed upstream of the liquid-liquid separator 108. The horizontal pipe separator 96 promotes the pre-separation of the oil and water phases by gravity. Oil is extracted from the top of the horizontal pipe separator 96 to ensure clean oil at the top, which is injected into an upper leg 110, which is the oil outlet from the liquid-liquid separator.

(45) The upper leg 110 includes an oil mass flow meter 114 and an oil control valve 116 configured to control flow of oil, as shown by arrow 122.

(46) A controller 115 is in communication with the oil mass flow meter 114 and oil control valve 116. The oil mass flow meter also measures the density of the oil phase and communicates to the controller. If the density of oil is more than a setpoint density (corresponding to pure oil), the oil control valve will close sufficiently to obtain maximum flow rate of pure oil with density as close as possible to the setpoint density.

(47) The lower leg 112 includes a water mass flow meter 118 and a water control valve 120 configured to control flow of water, as shown by arrow 124.

(48) A controller 119 is in communication with the water mass flow meter 118 and water control valve 120. The water mass flow meter also measures the density of the water phase and communicates to the controller. If the density of water is less than a setpoint density (corresponding to pure water), the water control valve will close sufficiently to obtain maximum flow rate of pure water with density as close as possible to the setpoint density.

(49) FIG. 4 illustrates a bar-graph with experimental data from a batch separator highlighting the performance of the invented OWEB process and system. Three different types of stabilizing agents, i.e., nanoparticles, surfactants, or both, may be entrained or dissolved in the incoming oil-water liquid mixture, as shown on the X-axis. The W/O emulsion normalized volume is shown on the Y-axis. As an example, the third case on the X-axis, which refers to an incoming W/O mixture containing both hydrophobic nanoparticles and a surfactant of low HLB value (each stabilizing agent with a concentration of 0.01% by wt.) shows how the volume of the incoming emulsion is dramatically reduced after applying the invented OWEB process. The mechanism driving the performance of the OWEB process is a catastrophic inversion process by increasing the WC from 25% to 67%. This significantly enhances the separation kinetics of oil and water, while at the same time dramatically reducing the volume of the W/O dispersion.

(50) Whereas, the invention has been described in relation to the drawings attached hereto, it should be understood that other and further modifications, apart from those shown or suggested herein, may be made within the scope of this invention.