CN116688821A - A kind of medium phase microemulsion and its preparation device - Google Patents

Abstract

The invention relates to the technical field of medium-phase microemulsion production equipment, specifically a medium-phase microemulsion and a preparation device thereof. The raw materials of the medium-phase microemulsion oil displacement agent include formation water, sodium carbonate, alcohol compounds and surfactants; preparation The device includes a first constant temperature treatment structure, a second constant temperature treatment structure and a magnetic mixing structure, the side end of the first constant temperature treatment structure is connected with the magnetic mixing structure, and the side end of the magnetic mixing structure is connected with the second constant temperature treatment structure; Medium-phase microemulsion is a thermodynamically stable system formed by mixing sodium carbonate, alcohol compounds and surfactant components with oil and water. After use, it can sharply reduce the interfacial tension of crude oil remaining in the rock pores in the oil, so that The oil droplets are easy to deform and flow, and then coalesced to form an oil wall to be recovered, especially the formation of the middle phase can greatly improve the oil displacement efficiency; at the same time, the process of the present invention is simple, safe and convenient to operate, and has good repeatability.

Description

A kind of medium phase microemulsion and its preparation device

technical field

The invention relates to the technical field of medium-phase microemulsion production equipment, in particular to a medium-phase microemulsion and a preparation device thereof.

Background technique

Microemulsion is a thermodynamically stable system formed by mixing surfactants, additives and oil and water. According to the coexistence of microemulsion and oil-water phase, it can be divided into lower phase, middle phase and upper phase. The formation of middle phase can greatly improve the oil displacement efficiency. A very promising tertiary oil recovery technology. The mesophase microemulsion can solubilize both oil and water. When the interfacial tension σmo=σmw between the mesophase microemulsion and oil-water, the interfacial tension σc of the system reaches the minimum, corresponding to the oil-water solubilization parameter SPo=SPw, the solubilization parameter of the system Sp is also the largest. The main purpose of carrying out research on the oil displacement effect of the best mesophase microemulsion is to determine the best mesophase microemulsion formula, conduct oil displacement experimental research, evaluate the oil displacement effect of the formula, and provide a basis for further enhancing oil recovery technology after water flooding .

However, there are still some deficiencies in the use of the existing medium-phase microemulsion preparation device. During the use, continuous communication-detection-guiding cannot be realized, thereby affecting the systematic detection work, so A preparation device for a mesophase microemulsion is needed to solve the problems mentioned above.

Contents of the invention

The object of the present invention is to provide a medium-phase microemulsion and its preparation device to solve the problems raised in the above-mentioned background technology.

To achieve the above object, the present invention provides the following technical solutions:

A preparation device for a medium-phase microemulsion, comprising a first constant temperature treatment structure, a second constant temperature treatment structure and a magnetic mixing structure, the side end of the first constant temperature treatment structure is connected with a magnetic mixing structure, and the side of the magnetic mixing structure is The end is connected with a second constant temperature treatment structure;

The first constant temperature treatment structure includes a heating component and a communication component;

The side end of the heating component is communicated with a communication component, the heating component is subjected to constant temperature heating treatment, and the communication component is used for communication and conduction of liquid;

The heating component includes a thermal insulation board, a frame plate frame, a floor frame, a carrying bucket, a constant temperature part, a sealing plate and a protective plate;

The front end of the protection plate is fixedly connected with a sealing plate, the left side of the sealing plate is fixedly connected with a heat preservation plate, the bottom of the sealing plate is fixedly connected with a floor frame, and the center of the floor frame is provided with a carrying bucket, and the The rear end of the carrying bucket is provided with a constant temperature part, and the constant temperature part is fixedly connected with the sealing plate, and the front end of the sealing plate is hinged with a frame plate frame;

The constant temperature part includes a positioning frame, a heat conduction arc frame, a mounting seat and a heating wire;

The central lower end of the positioning frame is fixedly connected with a heat conduction arc frame, and the heat conduction arc frame is provided with a mounting seat, and a heating wire is installed in the center of the mounting seat, and the heat conduction arc frame is used for heat conduction and heat reflection;

The communication components include communication pipes, material guide pumps, control valves, matching conduits, hydraulic seats, insertion conduits, elevating frames, and load-carrying assembly frames;

The upper end of the hydraulic seat is telescopically connected with a lifting frame, and the top limit of the lifting frame is connected with a load-bearing assembly frame. The front end of the load-bearing assembly frame is provided with a matching conduit. The left side of the control valve is connected with a connecting pipe, the lower end of the connecting pipe is connected with a guide pump, and the right side of the matching conduit is connected with an insertion catheter;

The magnetic mixing structure includes a temperature sensor, a positioning plate and a nested ring frame;

The upper end of the nested ring frame is fixedly connected with a positioning plate, and a temperature sensor is installed at the center of the positioning plate;

The magnetic mixing structure also includes a magnetic stirring block, a drum and a machine base. The upper end center of the drum is rotatably connected with a magnetic stirring block. The lower end of the drum is limited by the machine base. The limit is set by nesting the ring frame and the positioning plate, and the temperature sensor is set at the center of the positioning plate, and the bottom of the temperature sensor is set in the drum.

Preferably, the machine base includes a heat sink and a control box, and the upper end of the control box is fixedly connected with a heat sink.

Preferably, the center of the heat sink is connected to the drum in a limit position, and the magnet inside the control box drives the magnetic stirring block to rotate in the drum.

Preferably, the heat sink is arranged in a three-layer structure, and the heat sink is fixed to the control box.

Preferably, the insertion catheter communicates with the guide pump through a matching catheter, a control valve, and a communication tube.

Preferably, the bottom of the material guide pump communicates with the carrying barrel, and the material guide pump is arranged through the sealing plate.

Preferably, the heating wire is electrically connected to an external power source through the mounting base.

Preferably, the side ends of the nested ring frame and the drum are provided with a groove body, and the upper limit of the groove body is connected with a nested docking frame, and the nested docking frame is elastically adjusted at the center of the telescopic guide rod, and the telescopic guide rod The bottom end of the rod is equipped with an air cylinder.

A kind of preparation technology of medium phase microemulsion, comprises the following steps:

a. Prepare the following raw materials: formation water, sodium carbonate, alcohol compounds and surfactants;

b. According to the oil-water volume ratio of 1:1, adjust the concentration levels of the three factors of sodium carbonate, alcohol compounds and surfactants, and record the volume of the microemulsion phase and the remaining oil-water phase, and use the magnetic mixing structure to fully mix them, and then send them to Treat the interior of the structure at a constant temperature, and let it stand at 40-45°C for 10-12 hours until each phase reaches phase equilibrium, and record the volume of each phase; c. Then use an alkaline burette to add formation water drop by drop, and titrate until the solution is just If it is turbid, record the volume of water added respectively, and use Origin8.0 to draw a pseudo-ternary phase diagram;

d. Finally, according to drawing the pseudo-three-phase phase diagram, the best medium-phase microemulsion oil displacement agent can be selected and prepared.

Preferably, in the step a, the alcohol compound is any one of n-propanol, n-butanol, and n-pentanol, and the surfactant is sodium lauryl sulfate, sodium lauryl sulfate, Any one of betaine and Tween, the salinity of the formation water is 3400-3700 mg·L ^-1 .

Compared with the prior art, the beneficial effects of the present invention are as follows:

1. The present invention can carry out the constant temperature treatment work of the solution through the structural setting of the first constant temperature treatment structure and the second constant temperature treatment structure, which is convenient for the reaction to occur. , The guide pump is integrally connected, which can automatically extract the solution, so that the solution reaches the inside of the carrying tank through the guide pump, helping to carry out automatic detection and processing work. At the same time, the setting of the constant temperature part can ensure a constant temperature environment for the carrying tank. Installation The seat and the heating wire are connected through the power supply for continuous heating, and are arranged in a ring structure to make the heat conduction more uniform.

2. The present invention can carry out the mixed processing work of the solution through the structural arrangement of the magnetic mixing structure, the solution is stored in the inside of the drum, and the machine base can be heated for the drum, and the magnetic stirring block is driven magnetically in the inside of the drum. Adjust the rotation to realize the mixing process of the internal solution. The positioning plate and the nested ring frame at the upper position are used for the limit of the temperature sensor, and the temperature detection is performed through the temperature sensor.

3. The medium-phase microemulsion prepared by the present invention is a thermodynamically stable system formed by mixing sodium carbonate, alcohol compounds and surfactant components with oil and water. After use, it can remove the crude oil interface remaining in the rock pores The tension decreases sharply, so that the oil droplets are easy to deform and flow, and then they are jointly aggregated and formed into an oil wall to be recovered, especially the formation of the middle phase can greatly improve the oil displacement efficiency; at the same time, the process of the present invention is simple, safe and convenient to operate, and repeated Good sex.

Description of drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the following will briefly introduce the accompanying drawings that are required for the description of the embodiments. Obviously, the accompanying drawings in the following description are only some embodiments of the present invention. Those of ordinary skill in the art can also obtain other drawings based on these drawings without any creative effort.

Fig. 1 is the perspective view three-dimensional structure schematic diagram of the front of the main body of the present invention;

Figure 2 is an exploded view of the main body of the present invention;

Fig. 3 is a schematic diagram of a front perspective perspective structure of the first constant temperature treatment structure of the present invention;

Figure 4 is an exploded view of the heating element of the present invention;

Fig. 5 is a schematic diagram of the stereoscopic structure of the front view of the constant temperature part of the present invention;

Fig. 6 is a schematic diagram of the stereoscopic structure of the communication part of the present invention from a front perspective;

Fig. 7 is a schematic diagram of a three-dimensional structure from a front perspective of a magnetic hybrid structure of the present invention;

Figure 8 is an exploded view of the magnetic mixing structure of the present invention;

Fig. 9 is a schematic diagram of a three-dimensional structure from a front perspective of the machine base of the present invention;

Fig. 10 is a structural schematic diagram of the second embodiment of the magnetic mixing structure of the present invention.

In the figure: 1-first constant temperature treatment structure, 2-second constant temperature treatment structure, 3-magnetic mixing structure, 4-heating component, 5-communication component, 6-insulation board, 7-frame plate frame, 8-bottom plate frame , 9-loading barrel, 10-constant temperature part, 11-sealing plate, 12-protective plate, 13-positioning frame, 14-heat conduction arc frame, 15-mounting seat, 16-heating wire, 17-connecting pipe, 18-guide Material pump, 19-control valve, 20-cooperating conduit, 21-hydraulic seat, 22-inserting conduit, 23-lifting frame, 24-carrying combined frame, 25-temperature sensor, 26-positioning plate, 27-nesting ring Frame, 28-magnetic stirring block, 29-drum, 30-base, 31-radiating fin, 32-control box, 33-cylinder, 34-nested docking frame, 35-telescopic guide rod.

Detailed ways

In order to enable those skilled in the art to better understand the solution of the present application, the technical solution in the embodiment of the application will be clearly and completely described below in conjunction with the accompanying drawings in the embodiment of the application. Obviously, the described embodiment is only It is an embodiment of a part of the application, but not all of the embodiments. Based on the embodiments in this application, all other embodiments obtained by persons of ordinary skill in the art without creative efforts shall fall within the scope of protection of this application.

It should be noted that the terms "first" and "second" in the description and claims of the present application and the above drawings are used to distinguish similar objects, but not necessarily used to describe a specific sequence or sequence. It should be understood that the data so used may be interchanged under appropriate circumstances for the embodiments of the application described herein. Furthermore, the terms "comprising" and "having", as well as any variations thereof, are intended to cover a non-exclusive inclusion, for example, a process, method, system, product or device comprising a sequence of steps or elements is not necessarily limited to the expressly listed instead, may include other steps or elements not explicitly listed or inherent to the process, method, product or apparatus.

The present invention will be further described below in conjunction with the accompanying drawings.

A kind of preparation technology of medium phase microemulsion, comprises the following steps:

a. Prepare the following raw materials: formation water, sodium carbonate, alcohol compounds and surfactants;

b. According to the oil-water volume ratio of 1:1, adjust the concentration levels of the three factors of sodium carbonate, alcohol compounds and surfactants, and record the volume of the microemulsion phase and the remaining oil-water phase, and use the magnetic mixing structure to fully mix them, and then send them to Treat the interior of the structure at a constant temperature, and let it stand at 40°C for 10 hours until each phase reaches phase equilibrium, and record the volume of each phase; c. Add formation water drop by drop with an alkaline burette, titrate until the solution is just turbid, and record separately Add the volume of water respectively, and use Origin8.0 to draw the pseudo-ternary phase diagram;

d. Finally, according to drawing the pseudo-three-phase phase diagram, the best medium-phase microemulsion oil displacement agent can be selected and prepared.

Wherein, in step a, the alcohol compound is n-propanol, the surfactant is Tween, and the salinity of the formation water is 3400 mg·L ^-1 .

A kind of preparation technology of medium phase microemulsion, comprises the following steps:

a. Prepare the following raw materials: formation water, sodium carbonate, alcohol compounds and surfactants;

b. According to the oil-water volume ratio of 1:1, adjust the concentration levels of the three factors of sodium carbonate, alcohol compounds and surfactants, and record the volume of the microemulsion phase and the remaining oil-water phase, and use the magnetic mixing structure to fully mix them, and then send them to Treat the interior of the structure at a constant temperature, and let it stand at 43°C for 11 hours until each phase reaches phase equilibrium, and record the volume of each phase; c. Add formation water drop by drop using an alkaline burette, titrate until the solution is just turbid, and record separately Add the volume of water respectively, and use Origin8.0 to draw the pseudo-ternary phase diagram;

d. Finally, according to drawing the pseudo-three-phase phase diagram, the best medium-phase microemulsion oil displacement agent can be selected and prepared.

Wherein, in step a, the alcohol compound is n-butanol, the surfactant is sodium lauryl sulfate, and the salinity of the formation water is 3600 mg·L ^-1 .

A kind of preparation technology of medium phase microemulsion, comprises the following steps:

a. Prepare the following raw materials: formation water, sodium carbonate, alcohol compounds and surfactants;

b. According to the oil-water volume ratio of 1:1, adjust the concentration levels of the three factors of sodium carbonate, alcohol compounds and surfactants, and record the volume of the microemulsion phase and the remaining oil-water phase, and use the magnetic mixing structure to fully mix them, and then send them to Treat the interior of the structure at a constant temperature, and let it stand at 40-45°C for 10-12 hours until each phase reaches phase equilibrium, and record the volume of each phase; c. Then use an alkaline burette to add formation water drop by drop, and titrate until the solution is just If it is turbid, record the volume of water added respectively, and use Origin8.0 to draw a pseudo-ternary phase diagram;

d. Finally, according to drawing the pseudo-three-phase phase diagram, the best medium-phase microemulsion oil displacement agent can be selected and prepared.

Wherein, the alcohol compound in step a is n-pentanol, the surfactant is betaine, and the salinity of the formation water is 3700 mg·L ^-1 .

Comprehensive embodiment 1～3, can draw that the medium phase microemulsion prepared by the present invention is a kind of thermodynamically stable system formed by mixing sodium carbonate, alcoholic compound and surfactant composition agent and oil and water, can remove oil in oil after use The interfacial tension of the crude oil remaining in the rock pores is sharply reduced, so that the oil droplets are easily deformed and flowed, and then coalesced and coalesced to form an oil bank to be recovered, especially the formation of the mesophase can greatly improve the oil displacement efficiency; at the same time, the present invention The process is simple, the operation is safe and convenient, and the repeatability is good.

Please refer to Fig. 1, Fig. 2, a kind of embodiment provided by the present invention: a kind of medium-phase microemulsion preparation device, comprise the first constant temperature treatment structure 1, the second constant temperature treatment structure 2 and magnetic force mixing structure 3, the first constant temperature The side end of the processing structure 1 is connected with a magnetic mixing structure 3, and the side end of the magnetic mixing structure 3 is connected with a second constant temperature processing structure 2;

Please refer to FIG. 3, the first constant temperature treatment structure 1 includes a heating component 4 and a communication component 5;

The side end of the heating component 4 is connected with a communication component 5, the heating component 4 is subjected to constant temperature heating treatment, and the communication component 5 is used for communication and conduction of liquid;

Please refer to Fig. 4, heating element 4 comprises insulation board 6, frame plate frame 7, base plate frame 8, bearing barrel 9, constant temperature part 10, sealing plate 11 and protective plate 12, insulation plate 6, sealing plate 11, base plate frame 8, The protective plate 12 is fixed as a whole to realize the construction of the sealing structure, and the frame plate frame 7 is hinged on the front part of the sealing plate 11 at the same time, so that the sealing process of the sealing plate 11 can be performed;

The front end of the protective plate 12 is fixedly connected with a sealing plate 11, the left side of the sealing plate 11 is fixedly connected with an insulating plate 6, the bottom of the sealing plate 11 is fixedly connected with a floor frame 8, and the center of the floor frame 8 is provided with a carrying bucket 9, and the carrying bucket The rear end of 9 is provided with a constant temperature part 10, and the constant temperature part 10 is fixedly connected with the sealing plate 11, and the front end of the sealing plate 11 is hinged with a frame plate frame 7;

Referring to Fig. 5, the constant temperature part 10 includes a positioning frame 13, a heat conduction arc frame 14, a mounting seat 15 and a heating wire 16, and the positioning frame 13 and the heat conducting arc frame 14 are fixed, and the mounting seat 15 and the heating wire 16 can be connected by electricity. Heat treatment, heat conduction arc frame 14 reflects heat;

The center lower end of the positioning frame 13 is fixedly connected with a heat conduction arc frame 14, the heat conduction arc frame 14 is provided with a mounting seat 15, and the center of the mounting seat 15 is equipped with a heating wire 16, and the heat conduction arc frame 14 is used for heat conduction and heat reflection;

Please refer to Fig. 6, the connecting part 5 includes a connecting pipe 17, a material guide pump 18, a control valve 19, a matching guide pipe 20, a hydraulic seat 21, an insertion guide pipe 22, a lifting frame 23 and a load-bearing assembly frame 24, the connecting pipe 17, the guide material The pump 18, the control valve 19, the coordinating conduit 20, and the insertion conduit 22 are integrally connected to carry out the guide and discharge treatment of the solution. At the same time, the hydraulic seat 21 carries out the bottom load of the lifting frame 23, and the lifting frame 23 can control the height of the carrying combination frame 24, thereby Realize the height adjustment of the connecting pipe 17, the guide pump 18, the control valve 19, the matching conduit 20, and the insertion conduit 22;

The upper end of the hydraulic seat 21 is telescopically connected with a lifting frame 23, and the top limit of the lifting frame 23 is connected with a bearing assembly frame 24. The front end of the carrying assembly frame 24 is provided with a matching conduit 20, and the left side of the matching conduit 20 is connected to a control valve 19. The left side of the control valve 19 is communicated with a connecting pipe 17, the lower end of the communicating pipe 17 is connected with a guide pump 18, and the right side of the matching conduit 20 is connected with an insertion conduit 22;

Please refer to FIG. 7, the magnetic hybrid structure 3 includes a temperature sensor 25, a positioning plate 26 and a nested ring frame 27, the positioning plate 26 and the nested ring frame 27 are fixed, and the positioning and installation of the temperature sensor 25 can be carried out;

The upper end of the nested ring frame 27 is fixedly connected with a positioning disc 26, and the center of the positioning disc 26 is equipped with a temperature sensor 25;

Please refer to Fig. 8, the magnetic mixing structure 3 also includes a magnetic stirring block 28, a drum 29 and a machine base 30, the upper end center of the drum 29 is connected with a magnetic stirring block 28, and the lower end of the drum 29 and the machine base 30 limit settings , the upper end of the drum 29 is limited by the nested ring frame 27 and the positioning plate 26, and the temperature sensor 25 is set at the center of the positioning plate 26, the bottom of the temperature sensor 25 is located in the drum 29, and the drum 29 carries out the solution At the same time, the base 30 can drive the magnetic stirring block 28 to rotate inside the drum 29 to realize the mixing reaction.

Please refer to Fig. 9, machine base 30 comprises cooling fin 31 and control box 32, and the upper end of control box 32 is fixedly connected with cooling fin 31, and control box 32 upper end is provided with cooling fin 31, and cooling fin 31 is used for heat dissipation processing, and control box 32 simultaneously The movement of the upper magnetic stirring block 28 can be controlled to assist in the mixing process.

The center of the cooling fin 31 is connected with the drum 29 in a limited position, and the magnet inside the control box 32 drives the magnetic stirring block 28 to rotate in the drum 29. The cooling fin 31 adopts a three-layer structure, and the cooling fin 31 and the control box 32 maintain Fixed, the insertion conduit 22 communicates with the material guide pump 18 through the matching conduit 20, the control valve 19, and the communication pipe 17. The bottom of the material guide pump 18 communicates with the carrying bucket 9, and the material guide pump 18 is connected to the sealing plate 11. The heating wire 16 is electrically connected to an external power source through the mounting base 15 .

When implementing this embodiment, the user combines the first constant temperature treatment structure 1, the second constant temperature treatment structure 2, and the magnetic mixing structure 3 as a whole, firstly places the mixed liquid inside the drum 29, and then passes the temperature sensor 25 through The positioning plate 26 and the nested ring frame 27 are installed. At this time, the control box 32 inside the drive base 30 works to heat the drum 29. At the same time, it can be driven by an internal magnet to drive the magnetic stirring block 28 in the drum. The interior of 29 rotates, and the magnetic force technology is the existing structure setting, this article does not go into details, the heat sink 31 helps to carry out the heat dissipation treatment of the side position of the drum 29, the temperature sensor 25 carries out the real-time monitoring of the temperature, after the completion of mixing, start the communication The pipe 17 and the connecting pipe 17 extract the solution through the insertion conduit 22, and the solution reaches the position of the matching conduit 20 through the insertion conduit 22, and then reaches the control valve 19, and is conducted to the inside of the guide pump 18 through the communication pipe 17, and at the same time The connecting pipe 17, the material guide pump 18, the control valve 19, the matching conduit 20, and the insertion conduit 22 can be adjusted in height through the lifting frame 23 and the carrying combination frame 24, and the solution reaches the inside of the carrying bucket 9 through the guide. 15. The heating wire 16 works to carry out the constant temperature treatment of the solution, helps to carry out the follow-up detection work, and completes the work.

On the basis of Embodiment 4, as shown in Figure 10, the side ends of the nested ring frame 27 and the drum 29 are provided with a groove body, and the upper limit of the groove body is connected with a nested docking frame 34, and the nested docking frame 34 is in the The central elastic adjustment of telescopic guide rod 35 is arranged, and the bottom end of telescopic guide rod 35 is equipped with cylinder 33.

During the implementation of this embodiment, the cylinder 33 can drive the telescopic guide rod 35 to adjust the height, thereby realizing the adjustment process of the position of the drum 29, and the nested docking frame 34 can be elastically pulled, and can be quickly connected to the nested ring frame 27, The drum 29 is coordinated and positioned to facilitate efficient combination purposes.

Although the embodiments of the present invention have been shown and described, those skilled in the art can understand that various changes, modifications and substitutions can be made to these embodiments without departing from the principle and spirit of the present invention. and modifications, the scope of the invention is defined by the appended claims and their equivalents.

Claims (10)

1. The preparation device of the medium-phase microemulsion is characterized in that: the device comprises a first constant temperature processing structure (1), a second constant temperature processing structure (2) and a magnetic force mixing structure (3), wherein the side end of the first constant temperature processing structure (1) is communicated with the magnetic force mixing structure (3), and the side end of the magnetic force mixing structure (3) is communicated with the second constant temperature processing structure (2);

the first constant temperature treatment structure (1) comprises a heating component (4) and a communication component (5);

the side end of the heating component (4) is communicated with a communicating component (5), the heating component (4) is subjected to constant-temperature heating treatment, and the communicating component (5) is used for communicating and conducting liquid.

2. The apparatus for preparing a mesophase microemulsion according to claim 1, wherein:

the heating component (4) comprises a heat insulation plate (6), a frame plate frame (7), a bottom plate frame (8), a bearing barrel (9), a constant temperature part (10), a sealing plate (11) and a protection plate (12);

the front end of the protection plate (12) is fixedly connected with a sealing plate (11), the left side of the sealing plate (11) is fixedly connected with a heat insulation plate (6), the bottom of the sealing plate (11) is fixedly connected with a bottom plate frame (8), the center of the bottom plate frame (8) is provided with a bearing barrel (9), the rear end of the bearing barrel (9) is provided with a constant temperature part (10), the constant temperature part (10) is fixedly connected with the sealing plate (11), and the front end of the sealing plate (11) is hinged with a frame plate frame (7);

the constant temperature part (10) comprises a positioning frame (13), a heat conduction arc frame (14), a mounting seat (15) and a heating wire (16);

the heat conduction arc frame is characterized in that the lower end of the center of the positioning frame (13) is fixedly connected with a heat conduction arc frame (14), a mounting seat (15) is arranged on the heat conduction arc frame (14), a heating wire (16) is arranged at the center of the mounting seat (15), and the heat conduction arc frame (14) is used for conducting heat and reflecting heat.

3. The apparatus for preparing a mesophase microemulsion according to claim 2, wherein:

the communication component (5) comprises a communication pipe (17), a material guide pump (18), a control valve (19), a matching conduit (20), a hydraulic seat (21), an imbedding conduit (22), a lifting frame (23) and a bearing combination frame (24);

the upper end of the hydraulic seat (21) is connected with a lifting frame (23) in a telescopic manner, the top limit of the lifting frame (23) is connected with a bearing combined frame (24), the front end of the bearing combined frame (24) is provided with a matched guide pipe (20), the left side of the matched guide pipe (20) is communicated with a control valve (19), the left side of the control valve (19) is communicated with a communicating pipe (17), the lower end of the communicating pipe (17) is communicated with a guide pump (18), and the right side of the matched guide pipe (20) is communicated with an imbedding guide pipe (22);

the magnetic force mixing structure (3) comprises a temperature sensor (25), a positioning disc (26) and a nested ring frame (27); the upper end of the nested ring frame (27) is fixedly connected with a positioning disk (26), and a temperature sensor (25) is arranged in the center of the positioning disk (26);

the magnetic mixing structure (3) further comprises a magnetic stirring block (28), a drum (29) and a base (30), wherein the magnetic stirring block (28) is rotationally connected to the center of the upper end of the drum (29), the lower end of the drum (29) is in limit setting with the base (30), the upper end of the drum (29) is in limit setting with a positioning disc (26) through a nested ring frame (27), a temperature sensor (25) is arranged at the center of the positioning disc (26), and the bottom of the temperature sensor (25) is arranged in the drum (29); the machine seat (30) comprises radiating fins (31) and a control box (32), and the upper end of the control box (32) is fixedly connected with the radiating fins (31);

the center of the cooling fin (31) is in limit connection with the boiler barrel (29), and the magnet in the control box (32) drives the magnetic stirring block (28) to rotate in the boiler barrel (29).

4. A device for preparing a mesophase microemulsion according to claim 3, wherein: the radiating fins (31) are arranged in a three-layer structure, and the radiating fins (31) and the control box (32) are kept fixed.

5. The apparatus for preparing a mesophase microemulsion as set forth in claim 4, wherein: the imbedding conduit (22) is communicated with the material guiding pump (18) through the matching conduit (20), the control valve (19) and the communicating pipe (17).

6. The apparatus for preparing a mesophase microemulsion as set forth in claim 5, wherein: the bottom of the guide pump (18) is communicated with the bearing barrel (9), and the guide pump (18) is communicated with the sealing plate (11).

7. The apparatus for preparing a mesophase microemulsion according to claim 6, wherein: the heating wire (16) is electrically connected with an external power supply through the mounting seat (15).

8. The apparatus for preparing a mesophase microemulsion according to claim 7, wherein: the side ends of the nested ring frame (27) and the boiler barrel (29) are provided with groove bodies, the groove bodies are connected with nested butt joint frames (34) in a limiting mode, the nested butt joint frames (34) are arranged in the center of the telescopic guide rod (35) in an elastic adjusting mode, and the bottom end of the telescopic guide rod (35) is provided with an air cylinder (33).

9. A process for preparing a mesophase microemulsion, which adopts a device for preparing a mesophase microemulsion according to any one of claims 1 to 8, and is characterized by comprising the following steps:

a. the following raw materials were prepared: formation water, sodium carbonate, alcohol compounds and surfactants;

b. according to the volume ratio of oil to water of 1:1, regulating the concentration level of three factors of sodium carbonate, alcohol compounds and surfactant, recording the volumes of a microemulsion phase and the residual oil and water phase, fully mixing by using a magnetic mixing structure (3), then conveying the mixture into a constant temperature treatment structure, standing the mixture for 10 to 12 hours at the temperature of 40 to 45 ℃ until each phase reaches phase balance, and recording the volumes of each phase; c. dropwise adding stratum water by using a basic burette, titrating until the solution is just turbid, respectively recording the volume of each dropwise adding water, and drawing a quasi-ternary phase diagram by using an origin 8.0;

d. finally, according to the drawn pseudo-three-phase diagram, the optimal medium-phase microemulsion oil displacement agent can be selected and prepared.

10. The process for preparing a medium-phase microemulsion according to claim 9, wherein said alcohol compound in said step a is any one of n-propanol, n-butanol and n-pentanol, said surfactant is any one of sodium dodecyl sulfate, sodium dodecyl sulfonate, betaine and tween, and the mineralization degree of said formation water is 3400-3700 mg.L ^-1 。