RU2351755C1 - Method of effecting pay-out bed - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: invention refers to oil and gas industry and can be implemented for wave effecting production reservoir to increase oil withdrawal from it. The method of effecting production reservoir of a perforated well consists in creating hydro-acoustic waves in a flow with a specified frequency by means of a generator. The distance from the interval of perforation to the upper boundary of fluid in a well is measured. Then the period of basic harmonica of resonance frequency of the system "well-reservoir" is determined. Frequency of hydro-acoustic waves created by the generator is set equal to the frequency of the basic harmonica of resonance frequency "well-reservoir".

EFFECT: increased efficiency of effecting bottomhole zone of well and, correspondingly, reservoir.

4 cl, 1 dwg

Description

The invention relates to the oil industry and can be used for wave action on the reservoir in order to increase its oil recovery.

A known analogue of the invention is a method of influencing the bottom-hole zone of a well by exciting hydroacoustic waves in a liquid by a wave generator (RF patent 1595070, 1999).

Closest to the claimed invention is a method of influencing the bottom-hole zone of a well in which damped oscillations of a liquid column in a well are periodically generated using a generator (depression chamber) (RF patent 2176403, 2001).

The disadvantages of the prototype and analogue are the low impact efficiency associated with insufficient consideration of the properties of the treated object and the need to use special devices and fluids to generate a wave effect on the bottomhole zone of the well.

The objective of the invention is to increase the effectiveness of the impact on the bottom-hole zone of the well and, accordingly, on the reservoir.

This object is achieved in that in a method of exposing a perforated well to a producing formation, including generating a hydroacoustic wave with a certain frequency by a generator in a stream, according to the invention, the distance from the perforation interval to the upper boundary of the liquid in the well is measured, the period of the fundamental harmonic of the resonance frequency of the "well- formation ”, and the frequency of hydroacoustic waves generated by the generator is set equal to the fundamental frequency of the resonant frequency“ well-formation ”, while the period of the main harmonic of the resonant frequency "well-reservoir" is determined by the time diagram of the parameter associated with free oscillations of the upper boundary of the fluid after the disturbance of the "well-reservoir" system or by the time diagram of the manometer installed below the upper boundary of the fluid, the disturbance of the "well-reservoir" system create a certain volume of fluid by adding to the well, and the frequency of the hydroacoustic waves generated by the generator is set automatically by putting the generator in self-oscillation mode by introducing positive feedback.

The essence of the proposed method is as follows.

An oil well with a perforated casing operates in oil production mode.

As a wave generator, industrial well equipment is used, which includes an electric submersible pump with a control station. To implement the proposed method in the well by periodically changing the flow rate of the produced fluid, acting wave vibrations are created, which leads to a change in the pressure at the bottom in the perforation zone.

A change in the fluid flow rate is provided by a change in the rotation speed of the submersible electric pump under the influence of changes in the characteristics of the supply voltage generated by the control station.

Changes in the characteristics of the supply voltage generated by the control station are carried out under the action of an independently generated control signal having a frequency equal to or close to the resonant frequency of the processed object - the system "well-reservoir".

In this case, the control signal is generated by the controller of the control station. This signal is harmonic with a period T calculated by the formula

where H is the distance from the perforation interval to the upper boundary of the fluid in the well, m;

g is the gravitational constant, g = 9.8 m / s ² .

To more accurately determine the value of the period T, an empirical method can be used, which consists in the fact that in a well-reservoir system in equilibrium, using any disturbance, for example, by adding a certain volume of fluid to the well, free oscillations are created. In this case, the upper boundary of the fluid in the well will have damped oscillations with the frequency of the fundamental harmonic of the "well-formation" system. By registering these oscillations, for example, with a manometer installed below the liquid level, the value of the period T _{p of the} resonance waves is determined (see drawing). In this case, the controller of the control station will generate a signal with a period T equal to the period of the resonant waves T _p .

The same problem can be solved by connecting a feedback sensor signal to the control input of the control station and transferring the closed electro-hydraulic control system "control station - pump - fluid flow - feedback sensor - control station" to self-oscillation with a frequency equal to the resonant frequency the processed object is the well-reservoir system.

At the same time, a flow rate sensor is installed in the fluid flow to create a closed-loop control system.

To create self-oscillations of the flow, the output signal of the flow velocity sensor is connected to the controller of the control station, which extracts the signal of the flow velocity change, for example, by subtracting the measured current velocity value from the average velocity value for the current defined period. The value of the averaging period is chosen 50-100 times the period of the created self-oscillations.

The period of self-oscillations is determined by the above formula or empirically.

The calculated signal of the flow rate change is summed up with the set value of the pump rotation speed and fed to the control input of the control device in such a way that positive feedback appears in the obtained closed-loop control system.

Since the obtained closed-loop control system is connected with a well-reservoir hydraulic resonance system, due to positive communication, the system goes into self-oscillation mode with a resonant frequency of the well-reservoir system.

In order for the amplitude of the generated oscillations not to exceed the value that is dangerous for mining equipment, the controller of the control station limits the maximum and minimum allowable values of the pump speed rotation, for example, to ± 5% of the set value of the pump rotation speed, and the amplitude of the self-oscillations will be limited to the set allowable level.

In a real well, the value of the period of natural vibrations of the "well-formation" system is additionally associated with the value of the filtration resistance of the bottomhole zone. The greater the resistance, the shorter the period.

It follows that, by analyzing the time behavior of the values of the period of natural oscillations of the well-reservoir system in the first case or the period of self-oscillations in the second case, it is possible to continuously monitor the results of cleaning the bottom-hole zone when the well is exposed.

In fact, the period of natural vibrations for wells with a depth of 1000 to 4000 m is tens to hundreds of seconds, which allows using industrial equipment of the well as a wave generator.

The same principles of creating a wave action can be used for an injection well.

Using the proposed method, it is possible due to the penetration of the generated wave oscillations into the reservoir to provide continuous intensification of oil flow to the well.

Claims (4)

1. A method of impacting a perforated well on a producing formation, including generating a hydroacoustic wave with a generator in a flow at a certain frequency, characterized in that the distance from the perforation interval to the upper fluid boundary in the well is measured, the period of the fundamental harmonic of the resonant frequency of the well-formation system is determined, and the frequency of the hydroacoustic waves generated by the generator is set equal to the frequency of the fundamental harmonic of the resonant frequency “well-reservoir”. 2. The method according to claim 1, characterized in that the period of the fundamental harmonic of the resonant frequency "well-formation" is determined by the time diagram of a parameter associated with free oscillations of the upper boundary of the fluid after a disturbance of the "well-formation" system. 3. The method according to claims 1 and 2, characterized in that the period of the main harmonic of the resonant frequency "well-reservoir" is determined by the time diagram of the manometer installed below the upper boundary of the fluid, and the disturbance of the system "well-reservoir" is created by adding some volume to the well liquids. 4. The method according to claim 1, characterized in that the frequency of the hydroacoustic waves generated by the generator is set automatically by putting the generator in self-oscillation mode by introducing positive feedback.

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