RU2459943C2 - Method of complex wave action on well and bottom-hole zone - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: method involves formation of depression pressure drop between bottom-hole zone and cavity of tubing string by pumping of fluid, pressure relief with arrangement of fluid flow from bottom-hole zone to day surface at opening of quick-acting valve of tubing string cavity, creation of periodic wave processes in bottom-hole zone of formation, repetition of stages of pressure relief and creation of negative pressure pulses. Maximum increase in pressure drop is arranged between bottom-hole zone and well zone due to packer installed at design depth in annular space; monitoring of wave processes is performed using calculation system based on readings of pressure gauges and pulse pressure sensors calibrated on the installation of impact tube type.

EFFECT: higher efficiency of wave action on well.

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Description

The present invention relates to the field of oil and gas industry and can be used to develop and increase the flow rate of injection and production wells.

The known method (Popov A.A. Impact effects on the bottom-hole zone of wells. M., Nedra, 1990, p. 46-47) of cleaning bottom-hole zones of wells by pulsed drainage, including the formation of a pressure drop between the bottom-hole zone of the formation and the tubing cavity by the descent into the well of a tight tubing string filled with air at atmospheric pressure, with a breaker and packer at the lower end, installing the packer in the well above, and a breaker opposite the perforation, bleeding pressure during intensive movement of the fluid from the bottomhole ones formation of tubing to the surface at the opening of the breaker, the creation of periodic pressure pulses in the bottomhole formation zone by switching the fluid flow interrupter.

There is also known a method (Popov A.A. Impact effects on the bottom-hole zone of wells. M., Nedra, 1990, pp. 108-109) of cleaning bottom-hole zones of wells by pulsed drainage, including the formation of a pressure drop between the bottom-hole zone of the formation and the tubing cavity by lowering the tubing into the casing of the well with a breaker and packer at the lower end, installing the packer in the well above and the breaker opposite the perforation interval, lowering the plunger with a valve on the rope into the tubing and creating a vacuum in the tubing when lifting the plunger by ground traction construction inside the interrupter cavity, pressure release during intensive movement of the fluid from the bottomhole formation zone along the tubing to the surface at the moment the plunger opens the holes in the breaker, the creation of periodic pressure pulses in the bottomhole formation zone by switching the fluid flow during the reciprocating movement of the plunger.

The disadvantages of the above methods are the inability to control and regulate the process of development or cleaning of the bottomhole zone of the well.

A known method of cleaning a well from deposits during its operation (Veliev F.G., Kurbanov R.A.-I., Aliev E.N.A.S. No. 1700207, class E21B 37/00, published 12/23/91, bull. No. 47), in which negative pressure waves are periodically created at the wellhead, for which the valves on the flow line are closed and kept in the closed state, then opened. It is argued that in the well from the mouth to the bottomhole zone a negative pressure wave propagates with the speed of sound, reaching an amplitude of 1.5 MPa and leading to the formation of an effective shock depression that cleans the tubing and bottomhole zone.

However, at the installation used for the experiments, an imperfect pulse pressure measurement system based on a tensoelectric sensor was installed. Therefore, the authors were not able to trace the actual dynamics of the pressure waves, and the insufficient installation length did not allow to accurately determine the effectiveness of the method.

There is a method of developing and cleaning the bottom-hole zone of wells by pulsed drainage (Nosov P.I., Senochkin P.D., Nurislamov N.B. et al. Patent No. 2159326, class E21B 43/25), in which the formation of a pressure drop between the borehole zone of the formation and the cavity of the well is carried out by pre-pumping fluid into the well, creating periodic pressure pulses in the borehole zone of the formation in the form of a damped standing wave moving along the cavity of the well, and bleeding off the pressure when moving the fluid through the well from the well hydrochloric formation zone to the surface at a sharp opening borehole cavity.

However, control of fast wave processes is carried out using pressure gauges installed at the wellhead. They give conflicting readings (Fig. 2 and Fig. 3 of the patent description), although the wave process begins with “preliminary injection of fluid into the well” and subsequent “pressure relief”. Then, a unloading wave propagates into the well in the first phase of the working cycle, which is reflected in Fig. 2 of the description. And from Fig. 3, there may be an erroneous opinion that a pressure wave propagates into the bottomhole zone, which in subsequent patents, without taking measurements, is erroneously called a shock wave.

A known method of processing the borehole zone of the formation (Shipulin A.V. Patent No. 2266404, class E21B 43/25), including the creation of periodic pressure pulses in the borehole zone of the formation in the form of a shock wave moving along the cavity of the well, which is formed when the well cavity is periodically opened at the wellhead using valves, one of which connects the well cavity with a drain tank, the second - with a source of liquid under pressure.

However, with “periodic opening of the well cavity at the wellhead for the well to pressurize fluid under pressure”, “shock waves” do not form in the tubing, but a rarefaction wave forms, propagating from the wellhead to the bottomhole zone.

The known method, taken as a prototype, and a device for the development and cleaning of the bottomhole zone of wells by pulse drainage (Guryanov A.I., Fassakhov R.Kh., Fayzullin I.K. et al. Patent No. 2272902, class E21B 43/25), in which the pressure is vented when the fluid moves from the bottomhole zone to the surface to create periodic pressure pulses in the bottomhole formation zone. Depression differential pressure between the bottomhole formation zone and the tubing cavity and the formation of periodic pulses are created by pumping fluid into the borehole space when a predetermined pressure is injected. Bleeding to a predetermined pressure is carried out when the control valve is opened through the annulus, the steps of bleeding and creating pressure pulses are repeated.

However, periodic pressure pulses are created by pumping fluid into the borehole space when a predetermined pressure is created for a time T ₁ , and bleeding to a predetermined pressure is performed when the control valve is opened for a time T ₂ . The times T ₁ and T _{2 are} pre-set and controlled by a reading electronic device, although it is more reliable to monitor the effectiveness of the method by measuring pulse pressures, which have a wave effect.

In the known method, a pressure sensor in the bottomhole zone was used, which measured the magnitude of the rarefaction wave propagating from the wellhead to the bottom of the well, recording the possibility of reaching the discharge waves of the bottom of the well. But the time resolution of the used sensor does not allow one to judge either the speed of the wave or the steepness of the pressure front, thereby depriving them of the opportunity to fully control the process and successfully influence the results of the work.

In addition, since the depression in the near-wellbore zone of the well depends on the pressure drop in the rarefaction wave created at the wellhead as the difference between the initial pressure in the well during injection of a given pressure over time T ₁ and the pressure at the wellhead, set a predetermined pressure and process the collector for several days is extremely inefficient. The fact is that the permeability of the collector upon successful exposure to the applied method will vary in time. Namely, the flow rate of the well depends on this parameter, which determines the duration of the wave action on the bottomhole zone of the well.

It is more efficient to bleed the pressure from the well through the tubing than through the cavity of the annulus for the reasons that the tubing has a smaller diameter and the rate of fluid flow will be much larger, and hence the process of transferring the muds to the drainage tank will be more efficient. In addition, the flow rate affects the magnitude of the rarefaction wave that forms when the quick-acting valve is suddenly opened and propagates from the wellhead to the bottom of the well.

The present invention is aimed at achieving a technical result, which consists in increasing the efficiency of the wave action on the well and the bottomhole zone and thereby reducing the resistance to movement of the fluid in the bottomhole zone.

To obtain the specified technical result in the proposed method for the development and cleaning of the bottom-hole zone of the wells, including the formation of a depression of the pressure differential between the bottom-hole zone of the formation and the cavity of the tubing by pumping fluid, bleeding pressure when the fluid moves from the bottom-hole zone to the day surface with a sharp opening of the high-speed valve tubing cavities, the creation of periodic pressure pulses in the bottomhole formation zone, the repetition of the etching and pressure generation steps I, monitoring these stages at each cycle at the same fluid injection rate, injecting a predetermined pressure and bleeding fluid when the valve is opened, will organize the maximum increase in pressure drop between the bottom-hole zone and the well due to a decrease in pressure in the perforation zone when the rarefaction waves interact in this zone due to the installation at the calculated depth in the annular space of the packer and control the wave processes using a computer complex based on pressure gauges and pulse pressure sensors calibrated on a “shock tube” installation and in detail monitor the dynamics of the wave action in real time and effectively control it.

This method allows you to create a depressive pressure drop between the perforation zone and the cavity of the well in the form of a rarefaction wave by abruptly opening a high-speed valve. In this case, the rarefaction wave, moving in the direction from the wellhead, reaches the borehole sump, is reflected, doubling in amplitude at the maximum, and creates a powerful rarefaction wave in the perforation zone, providing buildup, weakening of adhesion and implosive extraction of colmatants from perforation holes and formation pores, and the wave Unloading, moving up the annulus, reaches the packer, is reflected, doubles in amplitude and returns to the perforation zone, shakes off adsorption deposits from the borehole walls and destroys ac falt-resinoparaffin deposits (AFS) in the perforation zone and adjacent pores of the formation. At this time, the rarefaction wave reflected from the sump of the well, propagating along the tubing upwards, reaches the already closed high-speed valve, reaches the sump, doubles in amplitude and is reflected in the perforation zone, and the cycle repeats. The rarefaction waves move through the fluid at the speed of sound, so they reach the bottom of the well, 2 km deep in 1.3 seconds. The full cycle of oscillation - from the mouth to the sump and vice versa, takes about 3 seconds. It is proposed to monitor wave processes in a multicomponent medium using pulsed pressure sensors pre-calibrated on a shock tube installation and output to a computer, which allows detailed tracking of wave dynamics in real time and the wave action can be quickly controlled. For example, to organize the movement of backward rarefaction waves down the annulus and along the tubing so that they meet and interact, for example, in the perforation interval. Such regulation can be carried out in various ways, for example, by controlling the depth of installation of the packer in the annulus. The occurrence of unloading waves makes it possible to obtain a liquid rupture in the perforation zone, which is characterized by shock boiling and intensive growth of cavitation bubbles in the region of a significant decrease in liquid pressure. The latter will allow you to ideally clean, for example, the perforation zone and remove the mud from the pores of the formation rock adjacent to the perforation holes due to the powerful cleaning injection of fluid under reservoir conditions under pressure above 20.0 MPa into the perforation zone of the well through pore capillaries and perforations . It is necessary to take into account that the rarefaction wave moves into the formation in the cleaned perforation zone also with the speed of sound and manages to achieve a significant penetration depth into the formation, which contributes to pulse injection. At the same time, the control of wave processes in the well will allow you to adjust the amplitude of the rarefaction waves, their frequency and an extremely important parameter when the wave action - the steepness of the waves, which determines the dynamic efficiency of the wave action.

Fig. 1 shows a schematic diagram for implementing the proposed integrated method of wave action on the well and the bottomhole zone. At the wellhead 1, a packer 16 and a quick-acting valve 15 are installed, which connects the tubing cavity 2 to the drain tank 9 through the shut-off valve 7 and the nozzle 8. The pump unit 4 or from the injection line through the nozzles equipped with valves 5 and 12, the fluid is pumped into the well and nadpakerny zone. A pressure gauge 6 is installed on the pipe in front of the shut-off valve to control the pressure. A manometer 10 and valves 3 and 12 are installed to control the pressure in the annulus and drain the liquid. The pressure gauges are read by the computer complex 13. The high-speed valve and valves are equipped with actuators 11, which are controlled by the computer complex 13. The wave processes are also monitored and controlled by the computer complex using calibrated pulse pressure sensors 14 installed on the tubing. The signals from the sensors are sent to the computer complex via electric cables. Before carrying out the wave action, the condition of the well, the tightness of the valves, assemblies and connections, are carefully examined.

The method is implemented as follows. The tubing pipes are lowered into the well and the packer is installed at the calculated depth. The installation is brought into working condition. To do this, close the valves 3 and 7, turn on the pumping unit 4, open the valve 15 and open the valves 5 and, if necessary, 12. According to the readings of pressure gauges 6 and 10, the pressure in the system is controlled. If necessary, excess fluid is drained through valve 3. Fluid is pumped into the well through the tubing to a technologically acceptable value. Then stop the pump 4 and close the valve 5. Hold the well under pressure, fixing its change in time, close the valve 15 and open the valve 7. Then, the wave treatment of the well is carried out - the high-speed valve 15 is sharply opened. When the high-speed valve is opened, the borehole fluid begins to pour out drain tank 9, the fluid pressure at the mouth drops sharply to atmospheric pressure, and a rarefaction wave propagates down the tubing down to the bottom. Then the valve 15 is closed. The amplitude of the rarefaction wave depends on the initial conditions and can reach negative values (Veliev F.G., Kurbanov R.A.-I., Aliev E.N. A.S. No. 1700207, class E21B 37/00). The dynamics of rarefaction waves is shown in Fig. 2. The rarefaction wave, moving from the mouth, reaches the sump of the well, is reflected, doubles in amplitude at the maximum and creates a rarefaction wave in the perforation zone, providing buildup and partial implosive extraction of colmatants from the perforation pores of the formation. In this case, the reflected rarefaction wave is divided into two waves. The unloading wave, propagating up the annulus, reaches the packer, doubles during reflection and returns to the perforation zone and is reflected from the bottom. A rarefaction wave moving up the tubing reaches the already closed valve 15 and is reflected from it down, also doubling in amplitude. At the calculated level, counter-propagation of rarefaction waves occurs. At this level, a significant decrease in pressure occurs. The fluid filling the well is brought into a metastable state, in which there is a fluid rupture, spontaneous gas formation with the formation of cavitation bubbles. A spectacular shock depression and cavitational destruction of paraffin deposits and other deposits occur at a pre-calculated depth, for example, in the perforation zone. Subsequently, rarefaction waves propagate along the tubing and annulus and the cycle repeats. The dynamics of the waves is recorded using pulsed pressure sensors pre-calibrated on the shock tube and installed on the wellhead, the signals from which are fed to the computer. The latter captures and analyzes the dynamics of rarefaction waves. The work program is designed in such a way as to give the operator specific proposals for the effective use of the local impact of wave processes. The parameters of wave pulses are determined taking into account the structural features of the reservoir, permissible pressure, pipe string condition, etc. Work to develop and increase the flow rate of injection and production wells can be carried out in conjunction with other types of bottom-hole treatment: thermal, chemical, vibrational, acoustic, etc. .d.

The colmatants, sand, and paraffin deposits removed using the described method are removed by washing.

The advantages of the proposed technical solution are that:

- it allows you to achieve the maximum increase in the pressure drop between the bottomhole zone and the well;

- monitor the wave processes using a computer complex based on the readings of pressure gauges and pulse pressure sensors;

- monitor in detail the dynamics of the wave action in real time and effectively manage it;

- to carry out a wave action in conjunction with other types of bottom-hole treatment: thermal, chemical, vibrational, acoustic, etc.

Claims (1)

The method of complex wave action on the well and the bottom-hole zone, including the formation of a depressive pressure drop between the bottom-hole zone of the formation and the cavity of the tubing by pumping fluid, relieving pressure with the organization of the movement of fluid from the bottom-hole zone to the day surface with a sharp opening of the high-speed valve of the cavity Tubing, the creation of periodic wave processes in the bottom-hole zone of the reservoir, the repetition of the stages of bleeding and the creation of rarefaction pulses, the control of these ups on each cycle at the same fluid injection rate, injection of a given pressure and bleeding it when the valve is opened, time control according to the pressure sensor, characterized in that they organize the maximum increase in pressure drop between the bottomhole zone and the well due to a decrease in pressure in the perforation zone in the case of counter-interaction of rarefaction waves in this zone due to the installation of a packer at the calculated depth in the annulus and control the wave processes with power computing system based on the pressure gauge and pressure pulse sensors Tare on the installation of the "shock tube" and monitor in detail the dynamics of wave action in real time and effectively control it.

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