RU2373386C1 - Method for action at well bottom zone and oil-saturated beds (versions) and device for its realisation - Google Patents

Abstract

FIELD: oil and gas production.

SUBSTANCE: group of inventions is related to generation of seismic energy in oil bearing beds. Method consists in the fact that pressure pulses are created in well cavity hydraulic medium. Facility used to create mentioned pressure pulses is a source of electric hydraulic pulse discharge, comprising accumulating capacitor, electrodes closed with metal wire with area of cross section from 0.1 mm² to 0.9 mm². Voltage pulses with value from 2.6 kV to 4.3 kV are sent to electrodes with time intervals from 20 sec to 70 sec, thus providing wire explosion and formation of pressure pulses in hydraulic medium, at the same time distance between electrodes makes from 11 mm to 60 mm. Source displacement is provided at the distance from 300 mm to 1000 mm.

EFFECT: improved efficiency of production at minimum effect at ecology due to provision of resonant events in elements of system "well - well bottom zone - beds", and also simplification and improved safety.

4 cl, 3 ex, 8 dwg

Description

FIELD OF THE INVENTION

The invention relates to means for generating seismic energy, for example, elastic vibrations in oil-bearing formations, in particular, to means for influencing the bottom-hole zone of wells and oil-saturated formations in the production of hydrocarbons, for example oil.

State of the art

The prior art there are a large number of ways to increase the flow in the well.

The prior art method for influencing the bottom hole of a well by creating depressive-repressive pressure pulses of the hydraulic fluid (RU 2276722 C1, published 05/20/2006). The disadvantage is complexity and limited capabilities.

As the closest analogue, the well-known method of influencing the bottom-hole zone of the well is selected by creating depressive-repressive pressure pulses of the hydraulic medium (RU 2310059 C1, published November 10, 2007). The disadvantage is the complexity and limited ability to create the necessary dynamic mode.

As the closest analogue of the downhole source, a well-known borehole seismic energy source was selected, comprising a housing, a high-voltage electrode assembly, a low-voltage electrode assembly, a spark gap assembly including an electric discharge source (SU 247530 A, G01V 1/02, published 04.11.1969). This spark gap is not suitable for creating an impact with the necessary parameters.

Disclosure of the invention

The present invention solves the problem of inducing inflow (increasing production rate) into the well at the production stage, which ensures quick and low-cost output of the well to maximum production rates.

In the course of solving this problem, the following set of technical results is achieved: the occurrence of resonance phenomena in the elements of the well – bottomhole zone – formations system, which ensure the release of pore channels of the bottom-hole zone and perforations from clogging substances and guidance of the wave pattern in the layers, which ensures an increase in production rate the entire thickness of the reservoir; improvement of the filtration properties of the bottomhole zone; simplification, improving the safety and efficiency of production with minimal impact on the environment.

These technical results are achieved by the fact that the method of influencing the bottom-hole zone of the well consists in creating pressure pulses in the hydraulic medium in the well cavity, using a source of electrohydropulse discharge containing a storage capacitor, electrodes closed by a metal wire with an area cross-section from 0.1 mm ² to 0.9 mm ² , voltage pulses of magnitude from 2.6 kV to 4.3 kV are fed to the electrodes at time intervals from 20 sec to 70 sec, about This ensures the explosion of the wire and the formation of pressure pulses in the hydraulic medium, while the distance between the electrodes is from 11 mm to 60 mm.

The indicated technical results are also achieved by the fact that the method of influencing the bottom-hole zone of the well consists in creating pressure pulses in the hydraulic medium in the well cavity, using an electrohydropulse discharge source containing a storage capacitor, electrodes closed with a metal wire with cross-sectional area from 0.1 mm ² to 0.9 mm ^2, the pulses supplied to the electrodes a voltage value of 2.6 kV to 4.3 kV at intervals of 20 seconds to 70 nuts, thereby providing an explosion wire and formation of pressure pulses in gidrosrede, wherein the distance between electrodes is from 11 mm to 60 mm, and the formation of pressure pulses in gidrosrede provide a source of movement for a distance of from 300 mm to 1000 mm.

The indicated technical results are also achieved by the fact that the method of influencing the bottom-hole zone of the well consists in creating pressure pulses in the hydraulic medium in the well cavity, using an electrohydropulse discharge source containing a storage capacitor, electrodes closed with a metal wire with cross-sectional area from 0.1 mm ² to 0.9 mm ^2, the pulses supplied to the electrodes a voltage value of 2.6 kV to 4.3 kV at intervals of 20 seconds to 70 nuts, thereby ensuring the explosion of the wire and the formation of pressure pulses in the hydraulic medium, while the distance between the electrodes is from 11 mm to 60 mm, and the formation of pressure pulses in the hydraulic medium is provided during the movement of the source of electrohydropulse discharge in the cavity of the well at a speed of 270 mm / s up to 600 mm / s.

The indicated technical results are also achieved by the fact that the borehole source of seismic energy for influencing the bottomhole zone of the well comprises a housing, a high voltage electrode, a low voltage electrode, an electric discharge source, a metal wire feed mechanism, a metal wire has a cross-sectional area from 0.1 mm ² to 0 , 9 mm ² , the source of the electric discharge provides the supply of voltage pulses to the electrodes from 2.6 kV to 4.3 kV, while the distance between the high-voltage and low-voltage electric electrodes ranges from 11 mm to 60 mm.

A distinctive feature of the proposed variants of the method and device is the provision of the formation of directional pressure pulses with an excess pressure at the leading edge significantly exceeding the reservoir pressure, while the pulses have the optimal dynamic and energy parameters necessary to implement the above set of technical results.

List of drawings

Figure 1 schematically shows the emitter of the source of the electrohydropulse discharge at the stage of closing the electrodes with a metal wire located opposite the sealed perforation channel.

Figure 2 schematically shows the emitter of the source of the electrohydropulse discharge at the stage of initiation of the explosion, leading to the formation of plasma.

FIG. 3 schematically shows the emitter of an electrohydropulse discharge source at the stage of formation of a shock wave with excess pressure at the leading edge due to the expanding plasma, which penetrates through the perforation channel into the bottomhole zone and further into the formation.

Figure 4 schematically shows the emitter of the source of the electrohydropulse discharge at the stage of compression and cooling of the plasma, which leads to the removal of the mud into the wellbore and cleaning of the perforation channels and increase the permeability of the reservoir.

Figure 5 schematically shows the design of the borehole source of seismic energy.

FIG.6 presents a diagram for determining the duty cycle.

FIG.7 and FIG.8 presents graphs showing the dynamics of changes in the parameters of the well at the stage of operation after applying the method and device.

Information confirming the possibility of carrying out the invention

In terms of kinetic properties, the oil reservoir in the layered reservoir is a modulus of bulk elasticity, and in terms of its acoustic properties it is a set of vibrational systems where both longitudinal and transverse (shear) waves propagate under pulsed action.

The field of elastic vibrations is determined by the guiding properties of the collector, and its attenuation is determined by the resonant properties of the collector.

When pulsed, a whole set of eigenfrequencies arises in a multilayer medium.

Since the reservoir of the oil reservoir is an anisotropic body, the modulus of longitudinal elasticity and shear modulus take different values in different directions, and their values can vary widely.

Along the resonator layers, it is not the original signal (impulse) that propagates, but the intrinsic oscillation process caused by it, and each resonator layer has its own frequency.

The most important result of the kinetic effect is to take into account the interaction of the shock wave with a group of so-called resonant particles, the speed of which coincides with the wave propagation velocity.

The effect of resonant turbulence and cavitation appears, the wave vibrational motions of the liquid are transformed into monotonic one-sided directed motions, as well as the wave effects of the spatial shift in highly viscous media. Upon excitation of wave fields in the treated volume, both circulation and the elimination of stagnant zones occur.

According to the totality of geological, geophysical, hydrodynamic, hydromechanical and other factors, the bottom hole zone of the well with various technologies of primary and secondary drilling of the reservoirs has common characteristics in terms of the structure of clogging substances.

The task of increasing the production rate of the well at the production stage has significant differences from, for example, measures to increase the production rate of the well at the development stage. According to the totality of hydrological, geophysical, and other factors, the stage of operation of the well has significant features due to the laws of formation of the bottom-hole zone of the well, for example, compared with the state of the well that occurs during its formation. The geophysical conditions of the bottom-hole zone (filtration properties, etc.), deformation processes, well permeability, structure and rheological properties of the mud, and so on, are significantly different.

The present invention solves the problem of decolmatization of perforation channels of the bottomhole zone of the well with various geological features of the reservoir of oil deposits without adding chemicals to the well and causing fluid to flow into the well over the entire power of the working interval. At the same time, an effective resonant energy pumping of productive formations is performed, which leads to an increase in their permeability.

The present invention solves the problem by creating directed repression and depression of elastic waves in the well cavity due to plasma-pulse discharge.

The aim and result of the present invention is the creation in the well cavity of a sequence of elastic wave processes that ensure the occurrence of resonance phenomena both in the bottomhole zone and in more remote sections of the formations. The physical nature of the hydrocarbon production process is so complex that it is not possible to carry out adequate mathematical modeling of the elastic-deformation system "bottom-hole zone - well - geological formations" to determine the dynamic properties and perform calculations of oscillatory processes in this system.

As is known from the theory of oscillations and wave processes, the elastic wave pattern that arises in a system is determined by the following indicators:

- vibrational, i.e. dynamic properties of the system itself (inertial, elastic, dissipative properties, rheological characteristics of the medium, etc.);

- parameters of stimulating influences (intensity, frequency, source location, etc.).

The dynamic properties of the system “bottom-hole zone - well-geological formations” at the operational stage have significant differences from the dynamic properties of this system, but which is at the development stage. So, for example, deformations and stresses differ significantly. Wellbore contamination at the development stage is primarily due to the presence of mechanical particles contained in the opening and development fluids with their subsequent swelling, rock fragments, cementitious particles or rock skeleton. All this significantly distinguishes, for example, the task of cleaning the bottom-hole zone at the development stage from cleaning at the operational stage, when the main contamination is alluvial colmatant.

The complexity of solving resonance problems for such a heterogeneous geophysical system, which consists of a well, a bottomhole zone, formations, etc., is also due to the presence of secondary wave and oscillatory processes (reflex waves, i.e. waves reflected from the interfaces between the layers and the bottomhole zone, induced waves and vibrations in individual elements of the system, partial resonances, etc.).

Any problem whose solution is associated with the creation of resonant wave or oscillatory processes in the system is extremely difficult. Far from any effects on the elastic inertia system can cause resonance phenomena. The exposure parameters can be selected so poorly that there will be no resonance, but antiresonance, i.e. a situation where the wave or oscillation process initiated by the subsequent exposure extinguishes the wave or oscillation process created by the previous exposure.

The proposed solution in accordance with the present invention is to provide optimal parameters of stimulating influences (intensity, frequency, source location, etc.) initiating elastic wave and oscillatory processes in the well cavity, the propagation of which into the bottomhole zone and geological formations will cause an increase in flow rate, cleaning bottom-hole zone and perforation holes and improving the filtration properties of the bottom-hole zone.

The initiating effect is characterized by the following parameters:

- the intensity of the pulse effect (pulse energy);

- pulse frequency;

- location of the epicenter of the pulsed effect.

The result can be achieved only by determining the optimal combination of all these parameters. The need for an interconnected determination of the intensity of the impact and the frequency of the exciting pulses is explained by the nonlinear dynamic properties of the system "bottom-hole zone - well - geological formations".

The energy parameters of the initiating effect are in correlation with the pulse repetition rate. It has been experimentally established that the pulse energy from 15 MW to 25 MW is optimal. With a lower value, a wave process with the necessary parameters does not occur. A pulse with a higher energy causes a wave that is too intense reflected from the walls of the well, which damps the subsequent initiated wave. The optimal range of pulse energy values is achieved by the indicated ranges of parameters characterizing the transverse size of the wire and the voltage supplied to the electrodes. If you use a wire with a cross-sectional area of less than 0.1 mm ² , the plasma channel between the electrodes that occurs after its explosion will not allow the electrodes to be closed for the necessary time so that the electric energy stored in the drive is released. The use of a wire with a cross-sectional area greater than 0.9 mm ² will require a greater voltage supply, which will lead to an increase in the size of the entire device.

Pulses are fed at intervals from 20 seconds to 70 seconds. This symptom characterizes the dynamic indicators of the initiating effect. Pulses can be emitted at regular intervals, for example three times per minute, or at different intervals. The latter option is most effective for adaptive systems, i.e. equipped with a means of measuring the parameters of the hydraulic medium in the well cavity (pressure, etc.) in order to control the moments of the pulse supply, depending on the situation. With a more frequent supply of pulses, the superimposed waves will not allow you to effectively cause the resonance of the elements of the system. With a rarer supply of exciting pulses, it is impossible to ensure overlap, i.e. amplification by the next wave of the previous wave due to rapid attenuation.

An important parameter is also the duty cycle of the supplied pulses. As you know, the duty cycle is understood as the ratio of the period T of the pulse supply to the duration t of the pulse itself (see FIG. 6). In accordance with the invention, the duty cycle characterizes the ratio of the time interval T between pulses to the duration t of the pulse. Reliability is a dimensionless parameter and its value should be from 10 ⁵ to 10 ⁶ . At a value of less than 10 ^{5 the} waves are too rare, and at a value above 10 ⁶ too often to ensure resonance of the system "bottom-hole zone - well - geological formations".

Thus, the supply of voltage pulses with the indicated parameters causes a wire explosion, the formation of an ion-plasma channel between the electrodes and the increased pressure zone in the hydraulic medium, which, propagating, forms an elastic wave process in the well cavity, bottomhole zone and formations. The number of pulses required to process the bottom-hole zone, i.e. the processing time is determined in each case separately, depending on the intermediate processing results.

Depending on the depth of the formation, in order to create a wavefront over its entire power, it is necessary to move the source of hydraulic pulses along the well. It is usually advisable to move from bottom to top. However, in a number of special cases, it is optimal to move the source from top to bottom. When generating pulses, the source is moved from 300 mm to 1000 mm. Moving can be carried out both with a constant step, and at various distances depending on the situation. Moving less than 300 mm is impractical due to a slight change in the position of the source. When moving the source of more than 1000 mm, the appearance of shadow zones in the bottomhole zone, which will reduce the effectiveness of the method. This variant of the method assumes that the pulses are formed by a fixed source, which then moves to a specified distance.

To reduce the exposure time, the formation of pressure pulses in the hydraulic medium can be ensured during the movement of the source of electrohydropulse discharge in the well cavity at a speed of 270 mm / s to 600 mm / s. In this case, the source continuously moves along the well, and pulses are generated during the movement of the source.

Thus, the optimal range of pulse energy values is achieved within the framework of these basic parameters characterizing the cross section of the wire, the distance between the electrodes, the voltage supplied to the electrodes, and the frequency of pulse formation.

The supply of voltage pulses with the indicated parameters causes a wire explosion, the formation of plasma between the electrodes and the overpressure zone in the hydraulic medium, which, propagating, forms an elastic-wave process in the bottomhole zone and formations. The number of triggered pulses, i.e. the processing time is determined in each case separately, depending on the geological features of the deposit and the depth of the beds, as well as the propagation velocity of the elastic waves in the rocks.

The propagation velocity of elastic waves in rocks is characterized by the following values (m / s):

- gypsum, anhydrite, crystalline rocks 4500-6500 - rock salt 4500-5500 - hydrocarbon gases 430-450 - oil 1400 - water, drilling mud 1500-1700

Clay, sand and carbonate rocks are characterized by intermediate propagation velocities of elastic waves. The porosity of the rocks helps to reduce, and their cementation - to increase the speed of propagation of elastic waves.

The modulus of elasticity of rocks (E) increases with increasing depth, with the greatest influence on the modulus of elasticity having the mineralogical composition, structure, temperature, bedding conditions, nature of the fluid filling the pore channels.

An increase in sandiness will lead to an increase in E of the rock. With an increase in the carbonate content of sedimentary rocks, the elastic modulus increases. Ceteris paribus, the elastic modulus of fine-grained rocks has higher elasticities than coarse-grained. The elastic moduli for rocks have the following meanings:

Breed Shale Limestone Dolomite Marble Sandstone Quartzite E _s.p · 10 ^-6 , MPa 1.5-2.5 1.3-6.0 2.1-16.5 3.9-9.2 3.3-7.8 7.5-10.0

The downhole seismic energy source for influencing the bottom hole of the well at the development stage, as schematically shown in FIG. 5, comprises a housing 1, a high voltage electrode 2, a low voltage electrode 3, an electric discharge source 4, and a metal wire feed mechanism 5. The metal wire 6 has a cross-sectional area of from 0.1 mm ² to 0.9 mm ² . The source 4 of the electric discharge provides the supply of 2 and 3 voltage pulses to the electrodes with a magnitude of 2.6 kV to 4.3 kV, while the distance L between the high voltage 2 and low voltage 3 electrodes is from 11 mm to 60 mm. The electrical components of the source are not the subject of this invention and can be performed in any known manner, for example, as described in the sources indicated in the prior art section of the present description.

The device operates as follows.

Depending on the distance between the electrodes, the diameter and shape of the cross-section of the wire, at calculated time intervals, voltages from 2.1 kV to 4.3 kV are supplied to the electrodes 2 and 3 closed by a metal wire 6 (FIG. 1). As a result, the explosion of wire 6 is initiated, leading to the formation of plasma (FIG. 2), the expanding plasma forms a shock wave with an excess pressure at the leading edge significantly exceeding the reservoir pressure (FIG. 3), passing in the bottomhole zone and into the reservoir as a whole in a series of successive elastic vibrations. The compression and cooling of the plasma leads to the removal of colmatant into the wellbore, which leads to the cleaning of perforation channels and a significant increase in the permeability of the reservoir (FIG. 4). The emitter of the source of an electrohydropulse discharge, creating pulses with overpressure in the hydraulic medium, moves along the working perforation interval with a given step or given speed depending on the power of the oil reservoir and the geological characteristics of the well.

Method implementation examples

Example 1. Use a source of electrohydropulse discharge with a wire of 0.7 mm ² . The voltage at the electrodes is 3.8 kV. The pulse sequence is supplied at regular intervals of 60 seconds. The pulse feed rate is 350,000. The change in well parameters after processing is shown in FIG. 7.

Example 2. Use a source of electrohydropulse discharge with a wire of 0.9 mm ² . The voltage at the electrodes is 4.3 kV. The pulse sequence is supplied at regular intervals of 25 seconds. The pulse feed rate was 410,000. The pulses were applied in series of 7 pulses. After each series, the source is moved 600 mm apart. Changing the parameters of the well after processing are shown in FIG. 8.

Example 3. Use a source of electrohydropulse discharge with a wire of 0.15 mm ² . The voltage at the electrodes is 2.8 kV. The pulse sequence is supplied at regular intervals of 30 seconds. The pulse feed rate was 510,000. The pulses were applied in series of 10 pulses. The source moves into the well cavity at a speed of 500 mm / s.

Claims (4)

1. A method of influencing the bottom-hole zone of a well and oil-saturated formations, consisting in the fact that pressure pulses are generated in the hydraulic medium in the well cavity, characterized in that an electrohydroimpulse discharge source containing a storage capacitor, electrodes closed by a metal wire cross-sectional area of 0.1 to 0.9 mm ^2, the pulses supplied to the electrodes by the voltage from 2.6 to 4.3 kV at intervals of 20 to 70 provide the amym explosion wire and formation of pressure pulses in gidrosrede, wherein the distance between electrodes is from 11 to 60 mm. 2. A method of influencing the bottom-hole zone of a well and oil-saturated formations, consisting in the fact that pressure pulses are generated in the hydraulic medium in the well cavity, characterized in that an electrohydroimpulse discharge source containing a storage capacitor, electrodes closed by a metal wire cross-sectional area of 0.1 to 0.9 mm ^2, the pulses supplied to the electrodes by the voltage from 2.6 to 4.3 kV at intervals of 20 to 70 provide the amym explosion wire and formation of pressure pulses in gidrosrede, wherein the distance between electrodes is from 11 to 60 mm, and the formation of pressure pulses in gidrosrede provide a source of movement for a distance of 300 to 1000 mm. 3. A method of influencing the bottom-hole zone of a well and oil-saturated formations, consisting in the fact that pressure pulses are generated in the hydraulic medium in the well cavity, characterized in that an electrohydroimpulse discharge source containing a storage capacitor, electrodes closed by a metal are used as a means of creating said pressure pulses wire cross-sectional area of 0.1 to 0.9 mm ^2, the pulses supplied to the electrodes by the voltage from 2.6 to 4.3 kV at intervals of 20 to 70 provide the amym explosion wire and formation of pressure pulses in gidrosrede, wherein the distance between electrodes is from 11 to 60 mm, and the formation of pressure pulses in gidrosrede provide electrohydropulse during the movement of the discharge source in the borehole cavity at a rate of 270 to 600 mm / s. 4. A downhole source of seismic energy for influencing the bottom hole of a well and oil-saturated formations comprising a body, a high voltage electrode, a low voltage electrode, an electric discharge source, a metal wire feed mechanism, characterized in that the metal wire has a cross-sectional area from 0.1 to 0 , 9 mm ² , the source of the electric discharge provides voltage pulses from 2.6 to 4.3 kV to the electrodes, while the distance between the high-voltage and low-voltage electrodes is It ranges from 11 to 60 mm.

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