RU2750978C2 - Method for hydraulic pulse implosion processing of wells - Google Patents

Abstract

FIELD: oil industry.SUBSTANCE: invention relates to the oil industry, it can be used to restore/increase the productivity of producing and injection wells. The method for hydraulic pulse implosion processing of wells by affecting the bottom-hole zone of a reservoir using the implosion effect includes the descent into the well of an implosion device on pumping and compressor pipes containing an implosion chamber with an expanded part, pressure concentrators, a plunger and a valve. At the same time, the length of the expanded upper part of the implosion chamber exceeds the total length of the plunger, the remote rod and the geophysical device, rigidly connected to each other. The geophysical device with its lower part is rigidly connected to the upper part of the remote rod, and the upper part is rigidly connected to the load-bearing geophysical cable, through which the necessary electricity is supplied to supply it. The length of the lower part of the implosion chamber does not exceed the total length of the plunger and the remote rod.EFFECT: reduced time of stopping the well, increased efficiency of evaluating the use of implosion processing of wells and increased efficiency of hydraulic pulse implosion processing of wells.1 cl, 1 dwg

Description

The invention relates to the oil industry, and can be used to restore / increase the productivity of production and injection wells.

A known method of treatment of the bottomhole formation zone of wells, including lowering a pressure pulse generator into the well and subsequent pulse treatment of the bottomhole zone of the productive formation in intervals with maximum oil saturation, characterized in that before the pulse treatment, the well fluid is replaced with anhydrous oil, a hydrocarbon solvent is pushed into the interval of the productive formation , produce additional perforation of the production string and the formation in this environment in the intervals with the maximum oil saturation, and the pulse treatment process is performed in the mode of 20-40 pulses per minute with an energy of not more than 6 kJ at the bottomhole pressure, which ensures the flow of fluid from the formation into the well, then into the zone of the productive formation perform implosive cleaning of the bottomhole zone [RF patent for invention No. 2268997. IPC Е21В 43/25. Publ. January 27, 2006. Bul. Number 3]. The disadvantages of this method are the impossibility of conducting geophysical research before processing and immediately after processing, which significantly complicates the interpretation of the data obtained and, moreover, requires additional tripping and lifting operations and, accordingly, an objective assessment of the effectiveness of the technology.

There is a known method of reagent-impulse action on a well and a productive formation, including supplying an active fluid medium through a pressure multiplier to the sub-packer zone of the well and then into the formation system, followed by impulsive action on the fluid medium, supplying an active fluid medium to the nozzle of the jet apparatus and pumping out the jet apparatus from a formation zone of a passive liquid medium, characterized in that a mixture of aliphatic and aromatic hydrocarbon solvents with the addition of a demulsifier solution pretreated in a constant magnetic field in one of these solvents is used as an active liquid medium, said mixture is trapped into the formation at a pressure of 10-20 MPa, holding is carried out for 12-24 hours, removal of the passive liquid medium from the bottomhole formation zone by wave unloading of the well with a pulse-wave depression effect in two modes - reverse water hammer and abrupt opening of the well pre-loaded with pressure, then using a pressure multiplier with a flat-jet head carries out hydraulic pulse interval treatment of the near-wellbore zone with a process fluid with flat fan jets with a pulse frequency of 50-300 per minute and a pressure of 1.5-2.5 times the static pressure in the well at the reservoir level, after which the final removal from formation zone of a passive fluid medium [RF patent No. 2275495. IPC E21B 37/06. Publ. 04/27/2006. Bul. No. 12]. The disadvantage of this method is also the impossibility of conducting geophysical surveys before and immediately after processing.

, где ν - скорость звука в среде, м/с; L - длина обсадной колонны ниже ротационного гидравлического вибратора, м [патент РФ №2542016. МПК Е21В 43/16. Опубл. 20.02.2015. Бюл. №5]. Недостатком известного способа невозможность проведения геофизических исследований до и сразу после обработки.There is a known method of treatment of the near-wellbore zone of the productive formation, which consists in the fact that a hydraulic impulse device, a jet pump installed in series from the bottom upwards, is lowered into the well on a pipe string, a liquid medium is fed into a hydraulic pulse device and this medium is applied to the near-wellbore zone of a productive formation with simultaneous pump of a liquid medium together with clogging particles to the surface, characterized in that, in addition, a depth pressure gauge is installed on the tubing string in front of the hydraulic impulse device, and a rotary hydraulic vibrator is used as a hydraulic impulse device to create a jet and impulse cavitation outflow along the perforation interval, when This impact on the structure of the formation with the fluid is carried out by exciting resonant oscillations of the liquid column in the well due to the coincidence of the pulsation frequency of the rotary hydraulic vibrator and its own the resonant frequency of the casing with a fluid, which is below the rotary hydraulic vibrator and is a resonator of the "organ pipe" type, while the required vibration frequency £ Hz is determined by the formula:

, where ν is the speed of sound in the medium, m / s; L is the length of the casing string below the rotary hydraulic vibrator, m [RF patent No. 2542016. IPC Е21В 43/16. Publ. 02/20/2015. Bul. No. 5]. The disadvantage of this method is the impossibility of conducting geophysical surveys before and immediately after processing.

A known method of treatment of the bottomhole zone of the productive formation and the bottom of the well, including lowering the pressure pulse generator into the well and subsequent pulse processing in the mode of 20-40 Hz with an energy of not more than 5 kJ at bottomhole pressure in intervals with maximum oil saturation, cleaning the bottomhole zone of the productive formation, which is different by the fact that the impulse action is carried out by cyclical depression pressure in a fluid-filled well, and the depression pressure is controlled by a throttling fluid flow by using a throttle sleeve with replaceable bushings of different diameters, the bottomhole zone is cleaned using a slotted and feather filter installed on the tubing, and the formation is treated in the well is carried out at least three times [RF patent No. 2546696. IPC Е21В 43/25. Publ. 10.04.2015. Bul. No. 10]. The disadvantage of this method is also the difficulty in objectively assessing the effectiveness of the applied technology of well treatment due to the impossibility of conducting geophysical studies before and immediately after treatment.

Known is a reusable implosion hydrogenerator of pressure according to RF patent No. 2303691, IPC E21B 37/00, containing an intake pipeline with holes for supplying reservoir pressure of the well fluid, an implosion chamber cylinder, a sub connecting the intake pipeline with the implosion chamber cylinder, a plunger connected to a rod, a clutch, a working chamber consisting of a working cylinder with windows and pressure concentrators, a shut-off valve, which is a valve seat with a ball inside, a cylindrical compression spring, while the working chamber is equipped with a hydraulic shock absorber.

The disadvantage of this device is the impossibility of performing geophysical surveys in the well immediately before and immediately after the implosion treatment of the bottomhole zone, and for conducting geophysical surveys, an additional round-trip operation is required separately.

Of the known technical solutions, the closest in purpose and technical essence to the claimed object is a method that provides multiple implosion hydraulic impulse effects on the bottomhole formation zone [A.A. Popov. "Implosion in oil production processes". - M .: Nedra, 1996, p. 113-115], including an implosion chamber, lowered into the well on tubing and a plunger down to the spring-loaded valve on a wireline into the implosion chamber. When the plunger rises, the valve closes and a vacuum is created in the chamber, and as soon as the lower end of the plunger reaches the expanded section of the chamber, the well fluid rushes into the implosion chamber, creating a depression impulse, and then a water hammer, while the spring-loaded valve opens, opening the implosion chamber.

However, this method also does not allow conducting geophysical surveys (for example, gamma-ray logging, thermometry, radiation or acoustic methods) in the well immediately before implosion processing and immediately after the work on this technology, which significantly reduces the efficiency of evaluating the results of this technology and, accordingly, the area and the possibility of its application, and increases the time for the study of the well due to the conduct of a separate additional round-trip operation for the geophysical study of the well. This is due to the fact that, for example, geophysical instruments such as "GEO-6", "GEO-7", "SOVA S5-38" and others, which often have an outer diameter greater than the inner diameter of the implosion chamber, cannot fit in the implosion chamber, in the case of fixing them, for example, at the upper end of the plunger.

General essential technical features of the prototype and the claimed invention are as follows. The device with pressure concentrators is lowered into the well filled with well fluid on the tubing to the formation, and the plunger is lowered up to the shut-off valve. To create a vacuum in the implosion chamber, and then a water hammer, the plunger is lifted from the implosion chamber by a lifting device located in the upper part of the well at its mouth to the expanded part of the implosion chamber.

The claimed invention differs from the prototype in that the device used in the method is equipped with a geophysical device, which is rigidly connected through a remote rod with a plunger, while the extended upper part of the implosion chamber is made with a length exceeding the total length of the geophysical device (the standard length of which is usually 1.8 m), a distance rod and a plunger, and the length of the plunger with a distance rod exceeds the length of the lower part of the implosion chamber. In this case, the geophysical device in its upper part is rigidly connected to the carrying geophysical cable, through which the necessary power supply is supplied to power it.

In the claimed invention, the disadvantages of the prototype are eliminated as follows. The plunger is rigidly connected to the geophysical device through the remote rod, while the total length of the plunger and the distance rod exceeds the length of the lower part of the implosion chamber, and the length of the extended upper part of the implosion chamber exceeds the total length of the plunger, the remote rod and the geophysical instrument, the upper part of which is connected to the load-carrying geophysical cable.

The essence of the claimed invention lies in the fact that the device used is equipped with a geophysical device, which, due to the presence of a distance rod having a total length with a plunger more than the length of the lower part of the implosion chamber, can be freely placed in the extended upper part of the implosion chamber, even in the lowest position of the plunger, when it rests on the bottom of the shut-off valve. In this case, the inner diameter of the expanded part is greater than the outer diameter of the device itself. When the plunger is lifted upwards to create a vacuum in the implosion chamber (and then the subsequent water hammer) until the lower end of the plunger reaches the expanded upper part of the implosion chamber, the geophysical device also has the ability to be freely positioned in the upper expanded part, because the length of the expanded section of the chamber exceeds the total length of the plunger, distance rod and device. The lifting of the plunger and the remote rod rigidly connected to it, as well as the geophysical device is carried out by a load-carrying geophysical cable with a breaking force of 9 tons or more (for example, the industrial brand KGSv1x0.75-90-150-4), which allows implosion processing according to the proposed method and simultaneously conduct geophysical surveys of the well, immediately before and immediately after the treatment of the well.

The implementation of the claimed invention is achieved as follows. The drawing schematically shows the implementation of the essence of the proposed method.

So in a well filled with liquid (conventionally not shown), a device is lowered on tubing 2, including an expanded upper section 3 and a lower section 5 of the implosion chamber. In this case, the device, equipped with pressure concentrators 6, is lowered to the formation. Using a winch or other lifting mechanism (conventionally not shown) on a geophysical load-carrying cable 1, for example, of the KTSv1x0.75-90-150-4 brand, the plunger 7 is lowered, with a remote rod 6 attached to it in its upper part, which in its upper part part is rigidly connected to the geophysical device 4, into the implosion chamber up to the shut-off valve 9. In this case, the total length of the distance rod 6 with the plunger 7 exceeds the length of the lower part 5 of the implosion chamber, and the expanded upper part 3 of the implosion chamber exceeds the total length of the plunger 7, the distance rod 6 and geophysical device 4. When lifting the load-carrying geophysical cable 1, with the attached geophysical device 4, there is a simultaneous ascent, using a remote rod 6, plunger 7. At the same time, a vacuum occurs in the implosion chamber, since the shut-off valve 9 is closed, and when the lower end of the plunger 7 reaches the expanded upper part 3 of the implosion chamber, the well fluid from the tubing and the annulus through the windows located in the expanded part 3 of the implosion chamber rushes to the lower part 5 of the implosion chamber at an instantaneous speed, creating in the bottomhole zone first a depression impulse, and then a water hammer, with a pressure exceeding the pressure in the formation. At the time of the water hammer, under the pressure of the fluid flow, the shut-off valve 9 opens, opening the implosion chamber and transmitting a pressure pulse into the well, into the formation.

Before the direct treatment of the well or immediately after that, a number of geophysical studies are carried out with the help of a geophysical tool, for example, by installing the tool in the required place in height using adjustable tubing. The electrical energy required to power the geophysical instrument is supplied through the current-carrying conductors of the load-carrying cable.

Technical results: the ability to conduct geophysical surveys immediately before and immediately after the treatment without additional tripping and lifting operations for research, which significantly reduces the well shut-in time, and allows obtaining more reliable results and, accordingly, more accurately assessing the possibility and effectiveness of using this technology on specific deposits.

Claims (1)

The method of hydraulic impulse implosion treatment of wells by influencing the bottomhole formation zone using the implosion effect, including running an implosion device on the tubing into the well, containing an implosion chamber with an expanded part, pressure concentrators, a plunger, a valve, characterized in that the length of the expanded upper part of the implosion chamber exceeds the total length of the plunger, the remote rod and the geophysical device, rigidly connected to each other, while the geophysical device is rigidly connected with its lower part to the upper part of the remote rod, and the upper part is rigidly connected to the load-carrying geophysical cable, through which the necessary electric power is supplied to its power supply, and the length of the lower part of the implosion chamber does not exceed the total length of the plunger and the distance rod.

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