RU2605571C1 - Garipov method for intensification of oil extraction and apparatus therefor - Google Patents

Abstract

FIELD: oil industry.

SUBSTANCE: group of inventions relates to oil industry and can be used for simultaneous separate development of multiple production facilities with electric submersible pump using acoustic effect on formation fluid in oil well. Method involves lowering in a given well interval tubing string, submersible pump and a source of acoustic vibrations, connected to generator of acoustic vibrations. Method includes degassing of reservoir fluid by exposing reservoir fluid to acoustic vibrations, generated by a source of acoustic vibrations. Degassed fluid is extracted from well. Source of acoustic vibrations is a high-frequency acoustic radiator, one or more. Said source of acoustic vibrations is installed above submersible pump. Degassing of reservoir fluid, coming out output of submersible pump, is performed.

EFFECT: technical result is higher efficiency of oil production, increase oil inflow and continuous process of extracting degassed oil due to acoustic degassing of fluid in well above submersible pump.

18 cl, 5 dwg

Description

The invention relates to the oil industry and can be used, including for simultaneous and separate development of several production facilities of the well with an electric submersible pump using acoustic effects on the reservoir fluid in an oil well.

Known installation for stimulating oil production, containing a generator, lowered into the well at a predetermined interval of depth of tubing, a source of acoustic vibrations connected to the generator, and a submersible pump, and a method of intensifying oil production, including descent into the well at a predetermined depth interval of a submersible pump, acoustic device, acoustic fluid degassing by exposing the fluid to an acoustic field and extracting the degassed fluid (RF Patent No. 2133332, E21B 43/00, 25, op. 20.07.1999).

The disadvantage of the above technical solutions is that the source of acoustic vibrations for degassing the fluid is lowered under a submersible pump, which cannot operate with a high content of the gas phase in the fluid and raise gas condensate, since it is known that oil formations contain oil with a gas factor of 20 to 1000 m ³ / m ³ and, accordingly, when this gas is released into the free phase in the acoustic field below the reception of the submersible pump, conditions are unacceptable for the submersible pump to work, and it will turn off according to “not partial load ”or will go out of service due to overheating.

The closest technical solution is an installation for stimulating oil production, comprising an acoustic oscillator lowered into the well at a predetermined tubing interval, an acoustic oscillation source connected to the generator, and a submersible pump, and an oil production intensification method that includes lowering a tubing at a predetermined interval, a source of acoustic vibrations and a submersible pump, acoustic degassing of a fluid by exposing the fluid to an acoustic field generated by a source of acoustic vibrations, and from treatment of the degassed fluid (RF patent №2264532, E21B 43/16, op. 20.11.2005, at the prototype).

The disadvantage of the above method and installation is that the source of acoustic vibrations for degassing fluid is lowered under a submersible pump, which cannot operate with a high content of the gas phase in the fluid and raise gas condensate, since it is known that oil formations contain oil with a gas factor of 20 up to 1000 m ³ / m ³ and accordingly, the allocation of the gas phase in a free acoustic field below the pump intake conditions are unacceptable for a submersible pump, and it will be disconnected at "weeks load "or out of operation due to overheating.

The proposed technical solutions eliminate the above disadvantages, increase the efficiency of oil production, increasing oil flow and providing a continuous process for the extraction of degassed oil by creating conditions for acoustic degassing of the fluid in the well above the submersible pump, and reduce the cost of oil production, while the method of intensifying oil production involves lowering in a given interval of the tubing well, submersible pump and the source of acoustic vibrations connected to the generator, acoustic degassing of the reservoir yuida by exposing the formation fluid to an acoustic field generated by the source of acoustic vibrations and extracting the formation fluid, wherein the source of acoustic vibrations, which is a high-frequency acoustic emitter, is installed one or more above the intake of the submersible pump, and acoustic degassing of the formation fluid is performed on the formation fluid leaving the submersible pump, additionally install one or more packers above the reception of the submersible, high-frequency akus the acoustic emitter is additionally driven into reciprocating motion, the high-frequency acoustic emitter is lowered into the depth range above the gas pressure level of the well fluid, the high-frequency acoustic emitter is lowered into the unstable zone of the well fluid, the beginning of the release of dissolved gas from oil and the high-frequency acoustic emitter are brought into ultrasonic mode cavitation.

An oil production intensification installation comprises an acoustic oscillation generator, a submersible pump, a tubing, a source of acoustic vibrations, at least one cable entry lowered into the well at a predetermined interval, and the acoustic oscillator is a deep or wellhead generator of high-frequency acoustic signals, an acoustic source oscillation is a high-frequency acoustic emitter, one or more connected to the generator of acoustic vibrations by cable, high a frequency acoustic emitter or emitters are placed in the well above the intake of the submersible pump with the possibility of flowing through them of formation fluid exiting the submersible pump, it is further provided with at least one packer located above the submersible pump and above the high-frequency acoustic emitter or emitters, it is additionally equipped with at least one packer located above the submersible pump and under the high-frequency acoustic emitter or emitters, it is further provided with, at least one packer located under the submersible pump and under the high-frequency acoustic emitter or emitters, high-frequency acoustic emitters are placed in series or in parallel, while the upper high-frequency acoustic emitter is installed in a given depth range, and subsequent high-frequency acoustic emitters are lower than the upper high-frequency acoustic emitter at a given distance from it, a high-frequency acoustic emitter is placed inside the tubing, high-frequency aku a static emitter is placed inside the borehole chamber fixed on the tubing, a high-frequency acoustic emitter is placed on a saddle fixed inside the tubing, a high-frequency emitter is placed on a stop fixed inside the tubing, a high-frequency acoustic emitter is placed and fixed on the submersible pump, the specified depth interval is the depth interval above the gas saturation pressure level of the well fluid, the specified depth interval is the zone of the unstable state of the well’s fluid Highlighted dissolved gas from the oil.

In FIG. 1 shows an installation comprising a submersible pump, a measuring device, two high-frequency acoustic emitters arranged in series above the submersible pump in a bypass system with a mechanical or hydraulic valve, a packer mounted above the submersible pump and under the high-frequency acoustic emitters, while the high-frequency acoustic emitters are connected by cable with a wellhead generator and with a ground current source, and a control station, in FIG. 2 shows an installation containing a submersible pump, a measuring device and a high-frequency acoustic emitter located in the saddle in the form of a mandrel inside the tubing above the submersible pump and connected via a cable to the wellhead generator and a ground source of current, and a control station, Fig. 3 shows the installation comprising a submersible pump, a measuring device, a high-frequency acoustic emitter located in the saddle inside the tubing above the submersible pump and connected via cable to a wellhead generator and to a ground source current nickname, and the control station, in FIG. 4 shows an installation comprising a submersible pump, a measuring device, two high-frequency acoustic emitters arranged in series above the submersible pump and connected via a cable to a wellhead generator and to a ground current source, with one high-frequency acoustic emitter located in the borehole chamber and the other high-frequency acoustic the emitter is located in the saddle, and the control station, in FIG. 5 shows an installation comprising a submersible pump and a high-frequency acoustic emitter located inside the tubing above the submersible pump and connected to the wellhead generator and to the ground source of current through a cable, and a control station.

Installation for intensification of oil production contains a submersible pump 1, tubing 2, at least one source of acoustic vibrations 3, at least one cable entry, ground source 4 and deep or wellhead generator of high-frequency acoustic signals 5 (hereinafter - “ Generator").

The submersible pump 1 is a deep well pump, for example, ESP, EVN.

The tubing 2 is a pipe, for example a pipe with or without couplings, pipe sections of one or different diameters, interconnected, for example, by sub.

The source of acoustic vibrations 3 is connected via cable 6 to a generator 5 and to a ground current source 4 and is a high-frequency acoustic emitter 3 (hereinafter referred to as “high-frequency emitter”), for example, magnetostrictive emitter, piezoceramic emitter. The high-frequency emitter or emitters 3 are placed in the well in a predetermined depth interval and above the intake of the submersible pump 1 with the possibility of the flow of the well fluid exiting the submersible pump 1, while the high-frequency emitter 3 is placed, for example, in a stationary device fixed to the tubing 2. High-frequency emitter 3 may include removable or permanently mounted, for example, on magnetostrictive emitters waveguides, concentrators.

The predetermined interval of the descent depths of the high-frequency emitter or emitters 3 represents the interval of depths above the gas saturation pressure level of the well fluid, the zone of unstable state of the well fluid at the beginning of the release of dissolved gas from oil, which is determined as follows:

- according to physico-chemical studies;

- according to deep and wellhead samples, which determine the composition of hydrocarbons, saturation pressure, gases present in the dissolved state;

- according to the data of geophysical studies of the well, for example pressure, temperature, density and other parameters inside the well, a change in the well parameters and a fracture in the line for changing the well parameters, for example pressure, temperature, density with a change in the functional dependence, indicates the zone of unstable state of the well fluid the release of dissolved gas from oil.

High-frequency emitter 3 is made in a mobile version or a stationary version.

High-frequency emitters 3 are placed in the well in series or in parallel, while the upper high-frequency emitter 3 is installed in a predetermined depth interval, for example, in the depth interval above the gas saturation pressure level of the well fluid, and subsequent high-frequency emitters 3 are installed below the upper high-frequency emitter 3 and at a predetermined distance between them and a submersible pump 1.

The stationary device is configured to accommodate a high-frequency emitter 3 in it and with the possibility of flowing through it of a well fluid leaving the submersible pump 1, and is, for example, a saddle 7, a borehole chamber 8, a pocket.

For example, the high-frequency emitter 3 is located in the saddle 7, mounted inside the tubing 2; high-frequency emitter 3 is placed inside the borehole chamber 8, mounted on the tubing 2; high-frequency emitter 3 is placed inside the tubing 2; high-frequency emitter 3 is placed on a stop fixed inside the tubing 2.

The cable entry is a device made with the possibility of sealing the cable 6 emerging from the well, for example, a faceplate, a tube-shaped chamber with sealing cuffs, a lubricator.

The generator 5 is placed at the wellhead or in the well and is a device for creating powerful acoustic vibrations. The generator 5 is made in one housing with a high-frequency emitter 3 or separately in different buildings.

The high-frequency emitter 3 is additionally equipped with a protective flow housing.

The installation is additionally equipped with at least one packer 9, a depth measuring device or devices 10, a bypass system 11 with a mechanical or hydraulic valve, a control station 12.

The packer 9 is designed to separate the layers from each other and from the submersible pump 1 and is a disconnecting device, for example mechanical, hydraulic, with a different installation method in the well.

The depth measuring device 10 is located in the well at a predetermined depth and is designed to monitor the operation of the high-frequency emitter or emitters 3, the operating parameters of the submersible pump 1 and the well fluid. Using the data of the depth measuring device 10, it is possible to clarify the data of physical and chemical studies of deep and wellhead samples and, accordingly, to clarify the depth of placement of a high-frequency emitter or emitters 3, to specify the intervals of the metastable state of the well fluid, the zone of the beginning of gas degassing, and also to clearly record the change in the density of the fluid , the beginning of the release of dissolved gas from the fluid into the free and bubble phase.

The depth measuring device 10 is stationary in the well or lowered on the cable 6 for a given time and depth.

The bypass system 11 with a mechanical or hydraulic valve is a system that provides for the separation of flows within the well while simultaneously and separately producing oil for wells with multiple reservoirs.

The control station 12 is a device that provides automated control of the downhole equipment from the surface, the control station 12 is additionally equipped with a modem.

The method of intensification of oil production is as follows.

If necessary, in a pumping oil well, a predetermined interval of descent depths of a high-frequency emitter or emitters 3 is determined, for example, after a well has been put into continuous operation of a submersible pump 1, or it is determined from previously conducted well studies, which indicate data on a given depth interval, namely, the interval depths above the gas saturation pressure level of the well fluid (degassing of the well fluid), the zone of unstable state of the well fluid of the beginning of the release of dissolved gas from oil .

To determine the specified interval of depths, well-known research tools and methods for studying well fluid are used, for example, data on changes in density with depth, where a more rapid decrease in the density of carbonated fluid occurs in the degassing zone due to an increase in the proportion of bubble gas in the volume of well fluid.

The submersible pump 1 is lowered into the well, one or several high-frequency emitters 3 are installed above the submersible pump 1 intake after determining the specified depth interval by known methods and means, tubing 2. At least one high-frequency emitter 3 is lowered into the well, after connecting it to the generator 5 and with a ground current source 4 using cable 6, one or more cable entries are used to lower one or more high-frequency emitters 3. One or more high-frequency emitters 3 are placed in the well in a predetermined depth interval with the possibility of flowing through them of the well fluid leaving the submersible pump 1.

High-frequency emitters 3 are placed sequentially or in parallel in a predetermined depth interval, after tuning the high-frequency emitter 3 in resonance to the cavitation mode, for example, the 15-100 kHz mode.

High-frequency acoustic emitter 3 is placed above the reception of the submersible pump 1, for example:

place it directly on the exit of the submersible pump 1, securing it from above, if gas already begins to be released in the submersible pump 1 and the saturation pressure and unstable state of the fluid will be directly at the outlet of the submersible pump 1, more precisely, directly in the submersible pump 1 (for shallow wells) ;

place it above the outlet of the submersible pump 1, but close to it, for example, if gas already begins to be released near the submersible pump 1 (for not very deep low-pressure wells);

place it above the outboard of the submersible pump 1 and above a predetermined depth interval, for example, the level of gas saturation pressure of the fluid of the well (for deep wells, when the pumps are at great depths), placing it, for example, in a stationary device mounted on tubing 2.

After the installation is launched into the well, the generator 5 is launched, while the high-frequency emitter or emitters 3 produce high-frequency acoustic vibrations, creating an acoustic field. The formation fluid leaving the submersible pump 1 passes through the acoustic field, the acoustic stimulation of the formation fluid accelerates the process of gas evolution from it, providing additional intensive gas evolution in the well elevator at a given depth into the bubble phase from the carbonated fluid with dissolved gas, thereby performing acoustic formation fluid degassing.

High-frequency acoustic vibrations, affecting the parameters of oil, in particular, a decrease in density by acoustic degassing, accelerate the process of gas evolution from a metastable carbonated fluid with a large volume of gas dissolved in it, form a bubble-bubble emulsion, while reducing the density of the fluid and backpressure on the submersible pump 1, thereby increasing its productivity and, accordingly, lowering the bottomhole pressure and increasing the flow of fluid in the bottomhole zone.

If necessary, the high-frequency acoustic emitter 3 is brought into ultrasonic cavitation mode.

In the case when several high-frequency emitters 3 are placed in the well, the upper high-frequency emitter 3 is necessarily installed above a predetermined depth interval and higher than the reception of the submersible pump 1, and subsequent high-frequency emitters 3 are lower than the upper high-frequency emitter 3 at a predetermined distance between themselves and the submersible pump 1, but above intake submersible pump 1.

In the process of acoustic degassing of the formation fluid, dissolved hydrocarbon gas is released from it into the free and bubble phase, gas bubbles stick together, foam together and rise through the well as a bubble phase, while the gas in the foam-bubble emulsion, rising, pushes oil to surface.

Gas bubbles are released as a result of cavitation and in the form of foam sharply reduce the density in the elevator of the well fluid.

At the same time, if the well fluid is degassed below the saturation pressure, then the gas bubbles generated by high-frequency irradiation and mechanical action immediately dissolve in the same fluid.

During the operation of the well, the metastable state of the fluid is taken into account, not allowing the upper high-frequency emitter 3 to be below the level of saturation pressure, because the gas released during the acoustic treatment will dissolve in the unsaturated state of the fluid, i.e. the fluid will be saturated with gas, dissolving in itself free hydrocarbon gas.

These technical solutions work provided that the fluid is above the saturation pressure level (in a saturated and supersaturated gas state) - in a metastable state, when hydrocarbon gas is released from the supersaturated fluid into the free phase and is present in the well in the form of bubbles, some of which will be unite in the form of foam, stick together and be present in the well in the free bubble phase.

The acoustic field degassed is extracted from the well to the surface.

For simultaneous and separate operation of several productive objects with simultaneous exposure to the formation fluid of these productive objects by an acoustic field on the formation fluid, the installation is additionally equipped with one or more packers 9.

In this case, the packer or packers 9 are installed above the intake of the submersible pump 1, for example above or below the high-frequency emitter or emitters 3, performing simultaneous and separate operation of several productive objects with the simultaneous impact of the acoustic field on the reservoir fluid of these productive objects.

In this case, the reservoir fluid is received by the submersible pump 1 from the upper and lower reservoirs or only from the lower reservoir and acoustic degassing of the reservoir fluid is carried out by flowing the reservoir fluid leaving the submersible pump 1 through an acoustic field created by a high-frequency emitter or emitters 3.

Also, for the simultaneous and separate operation of several productive objects with the simultaneous impact of the acoustic field on the reservoir fluid of these productive objects, the installation is additionally equipped with one or more packers 9 and a bypass system 11 with a mechanical or hydraulic valve, while they are installed above the intake of the submersible pump 1 inside the tubing 2 , for example above or below a high-frequency emitter or emitters 3, carrying out simultaneous and separate operation of several productive objects with one the temporary exposure of the acoustic field to the reservoir fluid of these productive objects.

In this case, the reservoir fluid is received by the submersible pump 1 from the upper and lower reservoirs or only from the lower reservoir and acoustic degassing of the reservoir fluid is carried out by flowing the reservoir fluid leaving the submersible pump 1 through an acoustic field created by a high-frequency emitter or emitters 3.

To monitor the operation of the high-frequency emitter or emitters 3, as well as for the borehole parameters, including the operating parameters of the submersible pump 1 and the parameters of the borehole fluid, the installation is additionally equipped with one or more depth measuring instruments 10, which allows you to specify the depth of placement of the high-frequency emitter or emitters 3, specify the specified depth intervals of the metastable state of the well fluid - the zone of the beginning of gas degassing, and also clearly record the decrease in density the fluid and, accordingly, the start of discharge from the fluid dissolved gas and bubble-free in phase.

Data from the depth measuring device 10 is sent to the control station 12, analyzed and taken into account during the operation of the oil well.

The proposed technical solutions increase the efficiency of oil wells using high-frequency acoustic emitters, providing a continuous process for the extraction of degassed oil, increasing the flow of oil by creating conditions for acoustic degassing of the fluid in the well above the submersible pump and reducing production costs, including lowering the cost of submersible electricity pumps operating in a gentle mode due to a decrease in the weight of the fluid column above the pump.

Claims (18)

1. A method of intensifying oil production, including the descent into a predetermined interval of the well of tubing — tubing, a submersible pump and an acoustic source connected to a generator, degassing the formation fluid by exposing the formation fluid to acoustic vibrations generated by the source of acoustic vibrations and extracting the degassed fluid, characterized in that the source of acoustic vibrations, which is a high-frequency acoustic emitter, one or more, is installed in Above the intake of the submersible pump, the degassing of formation fluid exiting the submersible pump is carried out. 2. The method according to p. 1, characterized in that they additionally install one or more packers above the reception of the submersible pump. 3. The method according to p. 1, characterized in that the high-frequency acoustic emitter is additionally driven into reciprocating motion. 4. The method according to p. 1, characterized in that the high-frequency acoustic emitter is lowered into the interval of depths above the level of the gas saturation pressure of the well fluid. 5. The method according to p. 1, characterized in that the high-frequency acoustic emitter is lowered into the unstable zone of the well fluid, the beginning of the release of dissolved gas from oil. 6. The method according to p. 1, characterized in that the high-frequency acoustic emitter is brought into ultrasonic cavitation mode. 7. Installation for intensifying oil production, containing a generator of acoustic vibrations, lowered into the well at a predetermined interval by a submersible pump, tubing - tubing, a source of acoustic vibrations, characterized in that it is additionally equipped with at least one cable entry, a generator acoustic vibrations is a deep or wellhead generator of high-frequency acoustic signals, the source of acoustic vibrations is a high-frequency acoustic emitter, one or several Only, the high-frequency acoustic emitter is connected to the acoustic oscillation generator using a cable, the high-frequency acoustic emitter or emitters are placed in the well above the intake of the submersible pump with the possibility of flowing through them of formation fluid leaving the submersible pump. 8. Installation according to claim 7, characterized in that it is additionally equipped with at least one packer located above the submersible pump and above the high-frequency acoustic emitter or emitters. 9. Installation according to claim 7, characterized in that it is further provided with at least one packer located above the submersible pump and under a high-frequency acoustic emitter or emitters. 10. Installation according to claim 7, characterized in that it is additionally equipped with at least one packer located under a submersible pump and under a high-frequency acoustic emitter or emitters. 11. Installation according to claim 7, characterized in that the high-frequency acoustic emitters are placed in series or in parallel, while the upper high-frequency acoustic emitter is installed in a predetermined depth interval, and subsequent high-frequency acoustic emitters are lower than the upper high-frequency acoustic emitter at a predetermined distance from it. 12. Installation according to claim 7, characterized in that the high-frequency acoustic emitter is located inside the tubing. 13. Installation according to claim 7, characterized in that the high-frequency acoustic emitter is placed inside the borehole chamber mounted on the tubing. 14. Installation according to claim 7, characterized in that the high-frequency acoustic emitter is located in a saddle mounted inside the tubing. 15. Installation according to claim 7, characterized in that the high-frequency emitter is placed on a stop fixed inside the tubing. 16. Installation according to claim 7, characterized in that the high-frequency acoustic emitter is placed and fixed on the exit of the submersible pump. 17. Installation according to claim 7, characterized in that the predetermined depth interval is an interval of depths above the level of the gas saturation pressure of the well fluid. 18. Installation according to claim 7, characterized in that the predetermined depth interval is a zone of an unstable state of the well fluid of the beginning of the release of dissolved gas from oil.

Images