RU2163665C1 - Method rising oil recovery from oil pool of repaired well - Google Patents

Abstract

FIELD: oil and gas production. SUBSTANCE: thermal wave radiation with frequency 400-2000 Hz and specific power of radiated thermal and wave energy not less than 10.0 kW per 1.0 m of thickness of pool is generated across face of well for action on pool. Low-frequency wave energy for relaxation of tension in pool is input by way of simultaneous formation in face zone of low-frequency periodic waves of decreased pressure with amplitude satisfying dependence P= Pf-0.8Psat, where Pf is pressure across face of well; Psat is saturation pressure of gas dissolved in oil. Frequency of low-frequency waves lies in range of 5-20 Hz. EFFECT: increased efficiency of wave action on oil pool to raise productivity of wells. 1 cl, 1 dwg

Description

 The invention relates to the oil and gas industry and is intended to increase well productivity.

 There are many known methods of wave and thermowave (vibrational, shock, pulsed, thermoacoustic) effects on the oil and gas formation or its bottom-hole zone (1 - 6). A generalization of the experience of using wave methods of influencing productive formations shows that with a good choice of impact and treatment regimes, one can achieve a significant intensification of the filtration processes in the reservoirs and increase their oil recovery over a wide range of amplitude-frequency characteristics of the impact regimes. At the same time, the positive effect of the wave action is detected both in the directly processed well and in some cases, with the appropriate treatment modes, it manifests itself in wells that are hundreds or more meters away from the source of pressure pulses, that is, when the formation is wave-processed, it is possible to implement mechanisms of both local and long-range areal effects.

 A known method of exposure to the formation of high-frequency and elastic waves (15 - 20 kHz) from the emitter, installed opposite the reservoir, to be processed or moved across the thickness of the treated formations (5).

 In the known method, when the waves of ultrasonic frequency act on viscous oils immediately after exposure, the viscosity of the oil significantly decreases and this effect persists for several hours, then the opposite phenomenon occurs - the viscosity of the oil increases against the original initial value before processing.

 The bottom-hole zones of wells drilled and operated in oil fields of the Russian Federation are clogged both during drilling and operation. In some cases, the clogging zone is from a well wall in the depth of the plates from a few centimeters to several tens of centimeters, in others - from several meters to tens of meters.

 The radiated power of known ultrasonic sources does not exceed several kilowatts. The wavelength emitted into the porous medium is 20 - 25 cm. High-frequency elastic waves decay intensively in the reservoir, therefore, the depth of effective processing at low vibrational energy densities does not exceed several tens of centimeters (3). Nevertheless, with the correct selection of the processing object, it is possible to increase the flow rates of wells by 2 - 2.5 times.

 The disadvantage of this method is the small depth of processing, low density of acoustic energy.

The known method of exposure to low-frequency seismic waves with a frequency of 520 Hz, the so-called vibrating microwave effect, carried out in two ways:
1. Through the bottomhole zone of the wells from a surface source of waves transmitted along the waveguide (pipe);
2. Vibration sources transmitting seismic (wave) energy to the oil reservoir from the earth's surface through the thickness of overlying rocks.

 The test results of this method showed at various fields (5) its high efficiency mainly due to a sharp decrease in the water cut of well products after treatment and a small increase in flow rate. When vibroseismic exposure occurs in the formation, seismic waves cause relaxation of directions in the "supports" and some sediment of the roof of the formation, due to this, the channels of the through flow of injected water are blocked, but there is no noticeable increase in production rates and injectivity of injection wells, since bottom-hole zones wells (especially in Siberia) are colmated both during the opening and operation, therefore, the hydraulic resistance of the bottom-hole formation zone is large, and some the increase in reservoir pressure caused by the treatment is not able to effectively filter the additionally displaced fluid through the clogged bottomhole zone. Vibroseismic exposure should be preceded by treatment of bottom-hole zones of wells. In this case, the effect should be higher. This, in turn, complicates and increases the cost of the process and makes it difficult to separate the effects from various methods of exposure - vibroseismic treatment - cleaning the bottom-hole zone.

 Another major drawback of this method is energy and environmental imperfection.

 In order to carry out vibroseismic treatment of formations with a thickness of 3 - 20 m, it is necessary to expose the seismic waves with a purity of 5 - 20 Hz to the hemisphere of the earth's surface with a radius of more than 3 km, including various horizons, ranging from construction structures and communications to aquifers. These objects also cannot be in a difficult state and the action of seismic waves can cause destruction.

 The range of low emitted frequencies is biologically dangerous for living organisms.

 As the closest analogue, a method is adopted to increase oil recovery from the oil well of a well being repaired, including flushing the well, cleaning the bottomhole zone by exposing the formation to thermal wave radiation when a thermal wave emitter is immersed in the well (5).

 Thus, the known methods have significant drawbacks and do not allow the full use of the physical phenomena occurring in the reservoir during the wave action to increase oil recovery and intensify oil production.

 The technical problem posed and the present invention is to increase the efficiency of wave action on the oil reservoir.

The problem is solved in that in a method of increasing oil recovery from an oil well of a well being repaired, including flushing the well, cleaning the bottomhole zone by exposing the formation to thermowave radiation when a thermowave emitter is immersed in the well, exposure to the reservoir is carried out by generating thermal wave radiation at the bottom of the well with a frequency of 400 - 2000 Hz with a specific power of radiated thermal and wave energy of at least 10 kW per 1 m of the thickness of the formation, while the low-frequency wave energy d For stress relaxation in the formation by creating periodic low-frequency waves of reduced pressure in the bottomhole zone with an amplitude satisfying the dependence
P = P _s - 0.8 P _us ,
where P is the amplitude of the periodic low-frequency waves of reduced pressure;
P _s - pressure at the bottom of the well;
P _us - saturation pressure of gas dissolved in oil.

 In addition, a powerful flow of wave energy of the introduced sound frequency into the formation causes the generation of two types of secondary dominant waves: one low frequency in the range of 5 - 20 Hz, the other ultrasonic, whose frequency is 10 - 20 Hz and is determined by the particle size distribution of the porous oil-saturated formation (3 ), which also helps to increase the efficiency of the process.

 The drawing shows a diagram of the integrated impact on the formation using a logging elevator, which allows to implement the described method.

 On the logging cable 1, a thermal wave emitter 2 is lowered into the well, in the upper part of which a packer-piston 3 is mounted, the cylinder for which is a casing 4. A centralizer 5 is attached to the thermal wave-emitter 2 in the lower part, and a packer-piston 3 is the top centrator. power thermowave emitter is fed through the cable, lowered from the logging elevator 6.

 The treatment of the bottomhole formation zone is as follows. Before the launch of the device, the well is washed, the place of movement of the packer-piston 3 is dibbed, then the emitter 2 with the piston 3 is lowered and installed against the reservoir to be processed.

 Thermal wave treatment of the formation is carried out in a stationary mode with the aim of heating and softening solid deposits in the well and formation. Then, with the help of the winch of the logging elevator 6, the packer-piston 3 is driven back and forth. During the upward stroke, the pressure of the liquid column in the borehole is transmitted to the piston 3, and under the piston 3 a reduced pressure region is formed, which is transmitted to the bottomhole formation zone, and over time, as it is cleaned, low-frequency infrasonic pressure fluctuations with an amplitude lower than the reservoir pressure are transmitted to more remote areas of the reservoir, causing overvoltage of the bearing platforms of the arches and their settlement. At the same time, a thorough cleaning of the bottom-hole zone is performed, which increases not only the inflow to the well, but also reduces the wave resistance of the bottom-hole zone for the passage of sound and infrasound and infrasound waves of reduced pressure. During the downward stroke, the liquid from under the piston 3 flows unhindered through the valve 8 into the space above the piston 3. During the upward stroke, the liquid decreases along the casing and enters the tank 7.

 The use of the present invention improves the efficiency of wave action on the reservoir.

Sources of information:
1. Abasov M.T., Sadovsky M.A., Nikolaev A.V. Vibration effect on oil reservoir. Vestnik AN SSSR, 1986, N 9, p. 95 to 99.

 2. Kuznetsov O. L., Simkin E. M. Transformation and interaction of geophysical fields in the lithosphere. Moscow, Nedra, 1990, p. 269.

 3. Nikolaevsky V.N. Geomechanics and fluid dynamics. M., Nedra, 1996, p. 447.

 4. Svalov A.M. About one mechanism of wave action on oil reservoirs. Oil industry, 1996, N 7.

 5. Simonov B.F. and others. The results of experimental field work to increase oil recovery by the vibroseismic method. Journal of Petroleum Economics, 1996, N 5.

 6. Reference Guide for the Design of the Development and Operation of Oil Fields, ed. Sh.K. Gimatudinova, Moscow, Nedra, 1983, p. 455.

Claims (2)

1. A method of increasing oil recovery from an oil well of a well being repaired, including flushing the well, cleaning the bottom-hole zone by exposing the formation to thermal wave radiation when a thermal wave emitter is immersed in the well, characterized in that the formation is produced by generating thermal wave radiation at the bottom of the well with a frequency of 400 - 2000 Hz with a specific power of radiated heat and wave energy of at least 10 kW per 1 m of the formation thickness, while low-frequency wave energy is input for rel stress accumulation in the formation by creating periodic low-frequency waves of reduced pressure in the bottomhole zone with an amplitude satisfying the dependence
P = Pz. - 0.8 Rnas.,
where P is the amplitude of the periodic low-frequency waves of reduced pressure;
Rz. - pressure at the bottom of the well;
Rnas. - saturation pressure of gas dissolved in oil.  2. The method according to claim 1, characterized in that the frequency of the periodic low-frequency waves is in the range of 5 to 20 Hz.