RU2293175C1 - Method for cleaning face-adjacent zone of bed of force well with washing of transfer water duct - Google Patents

Abstract

FIELD: oil extractive industry, namely, methods for cleaning face zone of oil bed, making it possible to perform additional cleaning of water ducts and tubing pipes in force wells during operation of low penetrability beds or beds with worsened operation characteristics due to pollution of well-adjacent zone.

SUBSTANCE: in accordance to method, groups of low pickup and high pickup force wells are selected as single hydrodynamic system. Valves of water ducts are manipulated and liquid is discharged from low pickup force wells into high pickup force wells. In accordance to invention before beginning of forcing into low pickup force wells, in low pickup force wells with pickup below acceptable determined is the value of face pressure at mouth, which is supposed to provide for self-discharge of water from this well onto surface. Water is forced into current well via transfer water duct, after which rotation is induced onto flow. Water forcing is stopped and pause is sustained for separation of water pollutions in internal volume of tubing pipes. Liquid is discharged from current well into vessel in volume, providing for removal of separated particles. Forcing and discharge of liquid with sustenance of pause is performed cyclically until total volume of forced water exceeds volume of transfer water duct of this low pickup force well, and after pollution from lower part of tubing pipes appears in discharge, during discharge into groups of high pickup force wells, discharge from low pickup force wells with pickup below acceptable is transferred to utilization vessel.

EFFECT: decreased pickup loss for low penetrability beds, removal of hard particles from high pressure transfer water ducts, increased time between cleaning of face zone of force wells and savings in material costs of maintenance of bed pressure.

1 ex

Description

The proposal relates to the oil industry, and in particular to methods for cleaning the bottom-hole zone of an oil reservoir, allowing for additional cleaning of water conduits and tubing in injection wells when operating low-permeability reservoirs or worsening their performance due to contamination of the borehole zone.

Known methods for cleaning the bottom-hole zone of injection wells using physico-chemical treatment, in which, in addition to special chemicals, various additional downhole tools and equipment are used (R. Yaremiichuk, Yu.D. Kochmar "Opening of productive horizons and development of wells." - Lviv : Higher School, 1982, 152 pp. And RF patent No. 2140531, E 21 B 43/22. Publ. BI No. 30 of 10.27.99).

The disadvantage of these methods is that they require large additional costs associated with attracting teams of underground and overhaul wells with the installation of additional downhole equipment or surface equipment, while the contaminants in the distribution pipe remain and are further washed gradually with the fluid pumped through the pipeline, which worsens its properties.

The closest in technical essence and the achieved results to the proposed one is the "Method for cleaning the bottom-hole zone of injection wells" (RF patent No. 2165012 E 21 B 43/25. Publ. BI No. 10 of 04/10/2000), including the injection of water into injection wells that have opened formations of various permeability, cleaning the bottom-hole zone of low-receiving wells by pouring water into a water conduit and wells with higher permeability.

This method allows for the recovery of injectivity of the formations without underground and major overhaul of the wells due to the outflow of liquid with contaminating particles from low-receiving wells into high-receiving ones when the pump is operating at the cluster pump station.

The disadvantage of this method is that when the injection is stopped, water is redistributed between low and highly sensitive wells, that is, there is a spill from low-reception wells into a water conduit (and from a water conduit to highly sensitive wells), while the contaminants carried out with the flow of pouring water pollute the water conduit, part of the contaminants (asphalt-resinous substances, paraffins, solid particles) accumulate on the walls of the water pipes, increasing hydraulic losses. In addition, with the resumption of water injection into the reservoir, some of the contaminants not removed from the water conduit again fall into the bottomhole zone of the formation and clogs the pore space, reducing the efficiency of treatment.

The technical task of the invention is to reduce the loss of injectivity of low-permeability formations, remove solid particles from high-pressure distributing water conduits, increase the time between cleaning the bottom-hole zone of injection wells and, as a result, save material costs to maintain reservoir pressure.

The technical problem is solved by the proposed method for cleaning the bottom-hole zone of the injection well reservoir with flushing of the supply conduit, including the allocation of groups of low-pressure and high-pressure injection wells in a single hydrodynamic system, manipulation of the valves of water pipes and the discharge of liquid from low-pressure injection wells into high-pressure injection wells.

What is new is that before starting injection into low-pressure injection wells, the bottomhole pressure at the wellhead, which should ensure self-discharge of water from this well to the surface, is determined in the low-pressure injection well, which reduces the injectivity, then water is pumped into this well through a distribution conduit, after which the flow is rotated in a volume not exceeding the volume of the tubing placed in this low-pressure injection well, stop water is pumped and pause for separation of water pollution in the internal volume of the tubing, the fluid is poured from this well into a container in a volume that removes the separated particles of contamination with a density lower than the density of the injected water, and the fluid is pumped and poured with holding the pause cyclically until the total volume of injected water exceeds the volume of the distribution conduit of this low-pressure injection well, after the appearance of pollution from bo ttom of the tubing, with the spout in the group vysokopriemistyh injection wells nizkopriemistoy spout of the injection well, bottom below the permissible acceleration is converted into a container for disposal.

A method of cleaning the bottom-hole zone of a reservoir of an injection well with flushing a feed conduit is as follows.

Allocate a group of low-receiving and highly-receiving injection wells in a single hydrodynamic system. A low-injectivity injection well is determined that reduces the injectivity below the permissible field development design. The water prepared at the head treatment facilities is pumped through the metering and distribution unit of the cluster pump station to the water conduits with shutoff valves and fluid flow controllers and is pumped into injection wells of various injections in a single hydrodynamic system to maintain reservoir pressure in the reservoir. The injected water has a low concentration of oil particles and solid suspended particles (of the order of 10 ... 20 mg / l) with small sizes of about 2 ... 20 microns.

When the pumps are stopped or the gate valve is closed at the metering and distribution unit of the cluster pumping station, the pressure in the network of the high-pressure water supply pipelines gradually decreases as the volume of water from the water pipe into the reservoir is forced to a value determined by the reservoir properties and the pressure value. It is determined in a low-pressure injection well, which reduced the injectivity below the permissible level; therefore, measures must be taken to clean the bottom-hole zone of the formation in this well. After that, the bottomhole pressure at the wellhead is determined at this well, which should ensure self-discharge of water from this well to the surface and allow operations to clean its bottom-hole formation zone.

During the stop of the injection, additional water settling takes place in the discharge water conduits, a part of suspended solid particles and oil particles settles on the inner surface of the water conduits. Before starting the pump or opening the gate valve at the metering and distribution unit of the cluster pump station and resuming water injection into the injection wells, close the gate valves at the high-intake injection wells and pump water through the distribution pipelines into the low-intake injection wells.

When the pumps are started or the gate valve is opened at the metering and distribution unit of the cluster pump station and the pumping resumes at the initial moment of time, a high pressure front propagates through the pipelines in the direction from the pumps to the injection wells. The high pressure front extends 98% longitudinally along the column of water in the pipe, while 2% of the kinetic energy acts on the side walls of the pipe. As a result of the passage of the pressure wave, the settled particles of oil and solid sediment are separated and their movement with the injected water into the injection wells is displaced. At this time, the concentration of contaminants in the water reaches 1,600 mg / l for oil particles and 200 mg / l for suspended solids, that is, the bulk of the contaminants are oil particles and asphalt-resin-paraffin deposits deposited from the walls of water pipes, whose density is 860 ... 940 kg / m ³ .

In order to prevent formation seams in a low-pressure injection well, which reduced the injectivity below the permissible level, it is necessary: by pumping clean water into the water pipe with the pumps of the cluster pumping station through the metering and distribution unit, the contaminated water is moved through the water pipe and an additional device located in the mouth zone of this well (for example, screw insert, hydrocyclone), which imparts rotation to the fluid flow, in which, under the influence of centrifugal forces, the enlargement of oil particles and Leniye of water large mechanical dirt particles, detached from the walls of conduits. When resuming the injection of water, its supply to the low-pressure injection well is carried out cyclically. In one cycle, a volume of water is supplied that does not exceed one volume of tubing placed in a low-pressure injection well, and does not allow oil contaminants pumped with water from the water conduit to move from the tubing into the perforated formation, after which the water supply is stopped by manipulating the valves into a low-pressure injection well and pause for a period of time necessary for the separation of water pollution under the influence of gravitational forces in our inner cavity clearly tubing, the oil particles and dirt particles having a density lower than the density of the injected water, float to the top, and mechanical particles accumulated predominantly in the lower part of the tubing. Upon completion of the separation, a spout is produced from the low-pressure injection well into the tank in a volume that ensures removal of the separated particles of contaminants with a density lower than the density of the injected water, then injection is resumed into the low-pressure injection well. Injection into a low-injectivity injection well and pause-out of the fluid is carried out cyclically until the total volume of injected water exceeds the volume of the distributing conduit of the low-accepting injection well, as a result of which the volume of the distributing conduit will be completely filled with clean water pumped by the pumps of the cluster pump station. Then, with the shut-off conduit stopped, the valves are opened on highly-responsive injection wells and the fluid is poured into the highly-responsive injection wells until contamination appears from the lower part of the tubing in the spout, after which the spout is again transferred to a container for disposal of contaminants introduced from the supply conduit and settled in the lower part of the tubing and removed from the bottomhole formation zone of a low-pressure injection well. Upon completion of the spill of contaminants from the bottomhole formation zone of the low-pressure injection well into the tank, by manipulating the valves on the metering and distribution unit of the cluster pumping station, the injection into the group of low-pressure and high-pressure injection wells in a single hydrodynamic system is restored.

Thus, the method provides for cleaning the bottom-hole zone of the injection well reservoir, washing the inner surface of the supply conduit from precipitation and contaminants, preventing oil contaminants and asphalt-resinous substances from entering the bottom-hole zone of the injection well, which reduce the injectivity of the well to the greatest extent.

An example of a specific implementation.

A group of injection wells of different injectivity is distinguished in a single hydrodynamic system: low-injection wells with injectivity from 50 to 200 m ³ / day at wellhead pressure of 10 MPa and highly-responsive wells with injectivity of 800 m ³ / day at wellhead pressure of 5 MPa. A low-injectivity injection well is determined that reduces the injectivity below the permissible field development design.

Water is pumped through the metering and distribution unit of the cluster pump station and water conduits to low-pressure injection wells and highly-sensitive injection wells with a flow rate of 1050 m ³ / day and a pump discharge pressure of 11 MPa. The volume of tubing pipes lowered into the low-pressure injection well is 6 m ³ ; the volume of the water pipe leading to this well is 8 m ³ .

When the pumps are stopped, for example, in accordance with the schedule of periodic (cyclic) injection or closing the valve, a depression of up to 5 MPa is created in the hydraulic system at the metering and distribution unit of the cluster pump station. Wellhead pressure in injection wells drops to 5 MPa. In the presence of a hydrodynamic connection between highly-responsive and low-responsive wells, spillage is observed from wells with low-permeability reservoirs to water conduits and from water conduits to wells with highly permeable reservoirs through highly-permeable wells in the amount of about 10 ... 20 m ³ , then the movement of water in water conduits ceases, while the wellhead the pressure of a low-pressure injection well decreases to a value of 1 ... 3 MPa, at which self-discharge of the injection well is possible. There is additional water sedimentation in the water conduits, during which time a mixture of solid suspended particles and oil particles is deposited on the water conduit walls. Before starting the pump or opening the gate valve at the metering and distribution unit of the cluster pumping station and resuming pumping water, the gate valves are closed on high-pressure injection wells and water is pumped through distribution pipelines into low-pressure injection wells. When the pumps are started and the pumping resumes at the initial time, the high pressure front propagates in the direction from the pumps to the injection wells, causing the separation of settled particles of oil and solid sediment and their movement together with the pumped water into the injection wells. The concentration of contaminants in the water reaches 1600 mg / l for oil particles and 200 mg / l for solid suspended particles. By pumping clean water into the water conduit with a concentration of oil particles of 60 mg / L, suspended solids of 50 mg / L and a particle size of 12 μm by pumps of the cluster pumping station, the contaminated water is moved through the water conduit, displaced and passed through the discharge zone located in the mouth area wells, an additional cleaning device that imparts rotation to a fluid stream, in which, under the influence of centrifugal forces, oil particles coarsen and large mechanical particles of contaminants separated from water are separated culverts walls. When pumping resumes, water is supplied to the injection well cyclically. In one cycle, a volume of water of the order of 4 m ³ is supplied, with a volume of 6 m ^{3 of} tubing placed in the low-pressure injection well, which does not allow oil contaminants pumped with water from the water conduit to move from the tubing into the perforated formation, after which by manipulation the valves stop the water supply to the injection well for 0.3 ... 0.5 hours for the separation of water pollution under the action of gravitational forces in the inner cavity of the tubing. At the end of the separation process, during which oil particles float to the upper part, and mechanical particles settle to the lower part of the tubing, water is poured into the tank from a low-pressure injection well in a volume of 1 m ³ for removal to the surface and disposal to the separated tank oil pollution, then again resume pumping into a low-pressure injection well. Injection into a low-pressure injection well and pouring out the liquid with pause soaking is repeated, as a result of which the volume of the distribution conduit will be completely filled with clean water pumped by the pumps of the cluster pump station. Then, with the stopped water conduit stopped, the valves are opened in highly-responsive injection wells and the liquid is poured into highly-sensitive injection wells in a volume of 3 m ³ until contamination appears from the lower part of the tubing, after which the outflow is again transferred to a tank for disposal of contaminants introduced from a distributing water conduit and a low-pressure injection well carried out from the bottomhole zone, and another 3 m ^{3 is} poured. Upon completion of the removal of contaminants from the bottom-hole zone of the low-pressure injection well to the tank, by manipulating the valves on the metering and distribution unit of the cluster pumping station, the injection into the group of low-pressure and high-pressure injection wells in a single hydrodynamic system is restored.

The use of this proposal allows for small additional capital costs using the existing reservoir pressure maintenance system to restore the injectivity of low-permeability formations without underground and overhaul of wells due to controlled fluid flow and additional water purification in the estuarine zone of injection wells at the time of starting the distribution pipelines for injection, to reduce the volume of water poured into the tank, to reduce the pollution of distribution pipelines by pollution from willow and hold their washing, increase time between cleanings capital bottom zone of injection wells and as a result, saving material costs for maintenance of reservoir pressure.

Claims (1)

A method of cleaning the bottom-hole zone of an injection well reservoir with flushing a distribution conduit, comprising isolating groups of low-intake and highly-responsive injection wells in a single hydrodynamic system, manipulating the valves of the water conduits and pouring liquid from the low-intake injection wells into the high-intake injection wells, characterized in that wells are determined in a low-pressure injection well, which reduced injectivity below tolerance stimulus, the bottomhole pressure at the mouth, which should ensure self-discharge of water from this well to the surface, then water is pumped into this well through a distribution conduit, after which the flow is rotated in an amount not exceeding the volume of tubing placed in this low-acceptivity injection well, stop the injection of water and pause for separation of water pollution in the internal volume of the tubing, spill liquid from this well into the tank in volume providing removal of the separated particles of contaminants with a density lower than the density of the injected water, moreover, the fluid is pumped and poured with a pause so that the total volume of injected water does not exceed the volume of the discharge conduit of this low-pressure injection well, after the contamination appears from the lower parts of tubing, when spilling into a group of highly responsive injection wells, spilling from a low-pressure injection well, which reduced injectivity ilk admissible transferred to a container for disposal.