RU2618248C1 - Self-cleaning well filter - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: device comprises a filtering element, a drive shaft and a driven shaft interconnected by means of a reducer, a blade and cleaning elements mounted on the driven shaft. The driven shaft is surrounded by the filtering element, the bottom butt of which is open and the upper butt is closed by a lid through which the driven shaft passes. On the drive shaft there is the blade enclosed in a housing with inlet openings at the bottom and outlet openings at the top. O-rings are installed on the housing above the inlet openings and at the lower end of the filtering element.

EFFECT: improving the self-cleaning efficiency.

5 cl, 2 dwg

Description

The invention relates to oilfield equipment, and in particular to devices for long-term protection of electric centrifugal pumps from mechanical impurities.

Known self-cleaning downhole filter, comprising a housing, a filter element with conical perforations and elastic brackets inserted in the perforations with a gap (AS USSR No. 685810, E21B 43/08, 1979).

A disadvantage of the known filter is that it can be used exclusively with a rod pump, since the filter element is cleaned of contaminants by elastic brackets that swing when the rod moves back and forth.

Known self-cleaning well filter containing a perforated pipe with nipple threaded sections and a coupling on one of the sections, a filter element and an insulated winding connected to an energy source (Pat. No. 2338871 RF, E21B 43/08, 2008).

A disadvantage of the known filter is that the thermal cleaning of the filter element used in it allows to remove mainly asphalt-resinous and paraffin hydrate deposits, but not solid solids.

A well-known filter is cleaned in the well, which is attached by a hollow liner to a cylindrical casing covering a submersible pump and mounted on a pipe string above the check valve, which passes from the bottom up, and a spring-loaded valve communicating the pipe string with a gap between the casing and the pump (Pat. No. 2415253 of the Russian Federation, E21B 43/00, 2011).

The disadvantage of the considered well filter is that the submersible pump is interrupted during its cleaning and, as a result, the amount of produced fluid is reduced.

A well-known self-cleaning well filter containing a cylindrical frame with through grooves, a filter element from a spring, a piston with a ring and adjusting screws for setting the gap between the spring turns, a shaft with radial blades and a beam equipped with profiled protrusions on the end surface (A.S. USSR No. 1036343, B01D 25/20, 1983).

The disadvantage of the filter is that it can be used to clean the liquid only with soft mechanical impurities, since solid impurities, when they reach the protrusions, slow down the rotation of the rocker arm and reduce the amplitude of the spring vibrations, in which particles are removed from the gaps.

The closest in technical essence to the claimed and adopted as a prototype is a self-cleaning well filter, including a filter element made of a coiled coil spring, the lower end of which is blocked by a plug with an adjusting screw, a shaft with blades and cleaning elements in the form of brushes along their ends, mounted in supports inside filter element (A.S. USSR No. 1165427, B01D 25/20, 1985).

The disadvantage of the self-cleaning well filter used as a prototype is the low torque on the shaft, since not all of the fluid flowing through the filter element rotates the blades, which can lead to jamming of the bristles between the spring turns with a significant length of the filter element and, as a result, the self-cleaning of the latter.

The present invention solves the problem of creating a downhole self-cleaning filter with increased ability to self-cleaning.

The specified technical result is achieved by the fact that in the borehole self-cleaning filter containing a filter element with an open and closed end, a shaft, a blade on the shaft and cleaning elements associated with the shaft, according to the invention, the shaft is made integral and consists of drive and driven shafts connected between by means of a reducer, the driven shaft with the cleaning elements installed on it is surrounded by a filter element, the lower end of which is open, and the upper end is closed by a cover through which the driven shaft passes, on the drive shaft blade is encased in a casing with inlets at the bottom and an outlet at the top, with the housing above the inlet openings and at the lower end of the filter element mounted sealing ring.

The filter element can be equipped with a safety valve.

The cleaning elements can be made in the form of rack brushes or spring-loaded strikers interacting with the filter element during rotation of the driven shaft.

A sludge collector with inlet openings at the top can be attached to the lower end of the filter element.

The filter element can be made in the form of an all-welded structure of wound and axial prismatic profiles.

In FIG. 1 schematically depicts the inventive downhole self-cleaning filter, a longitudinal section; in FIG. 2 - filter element with cleaning elements in the form of spring-loaded strikers, cross section.

The self-cleaning downhole filter contains driving and driven shafts 1 and 2, from different sides connected by means of splined couplings 3 to the reducer 4. The filtering element 5 with covers 6, 7 at the ends in which bearing bearings (not shown) are placed, is mounted on the driven shaft 2, passing through the top cover 7. In the bottom cover 6 there are made liquid inlets 8. On the driven shaft 2, cleaning elements are installed in the form of rack brushes 9, the bristles of which are in contact with the surface of the filter element 5 facing the fluid flow. In some embodiments, the cleaning elements may be spring-loaded strikers 23 colliding with the filter element 5 (Fig. 2). The drive shaft 1 is surrounded by a blade 10 and enclosed in a housing 11, in the lower and upper covers 12 and 13 of which there are inlet and outlet holes 14 and 15 and bearing bearings (not shown). The lower end of the filter element 5 and the housing 11 above the inlet openings 14 cover the sealing rings 16, dividing the space between them and the borehole wall into three areas for organizing the movement of fluid in the borehole self-cleaning filter along the desired path. A safety valve 17 is installed in the upper part of the filter element 5. A sludge collector 18 with inlet openings 19 at the top is connected to the lower end of the filter element 5, which serves to collect mechanical impurities removed from the surface of the filter element 5. The filter element 5 is an all-welded structure consisting of an internal wound profile 20 and external supporting axial profiles 21 (Fig. 2). Between the turns of the profile 20 there is a slot 22 expanding from the inside out, the width of which determines the fineness of cleaning the formation fluid. The filter element may be made of internal axial profiles, spaced apart from each other by the width of the slit, and supporting turns of the profile from the outside (not shown). In both versions of the filter element, the inner profile or profiles form a smooth surface facing the fluid flow. To protect against damage during tripping operations, a perforated casing (not shown) is mounted on the filter element 5.

Well self-cleaning filter operates as follows.

As part of a submersible pump installation, a self-cleaning well filter is lowered into the well to the perforation interval in the production casing (Fig. 1). Under the action of the vacuum created by the submersible pump, the formation fluid rushes into the filter element 5 through the openings 8 in the lower cover 6, since the annular gap between the filter element 5 and the borehole wall is closed by a sealing ring 16. Then the liquid is filtered through a gap 22 between the turns of the inner profile 20, and in it, rock particles remain above the gap (Fig. 2). In the presence of a sludge collector 18, liquid enters the filter element 5 through the inlet holes 19. From the filter element 5, the purified liquid enters the annular gap and flows along it along the reducer 4 to the sealing ring 16, which overlaps the annular gap between the casing 11 and the well wall. The fluid passes through the openings 14 into the housing 11, goes up and leaves it through the outlet openings 15.

During the upward movement in the housing 11, the fluid flows around the blade 10, which converts the potential energy of the fluid flow into the kinetic energy of the drive shaft 1, causing it to rotate in the bearing supports available in the covers 12, 13. The rotation from the drive shaft 1 is transmitted through the gearbox 4 to the driven shaft 2, while the gearbox 4 lowers the speed and increases the torque on the driven shaft 2 in comparison with the drive shaft 1. The driven shaft 2 with the rack brush 9 located on it rotates inside the filter element 5, while the rack bristles only 9 minutes brushes in contact with the smooth surface of the inner profile of wound 20, and to overcome the frictional force therebetween consumes a small amount of fluid flow energy. As particles accumulate over the slit 22, the bristles of the rotating rack brushes 9 begin to cling to them and pull them out of the slit 22. Due to the increased power on the driven shaft 2, the friction force of the bristles against the inner wound profile 20 with particles in the slit 22 is overcome.

The bristles do not compact the stuck particles in the expanding slit 22, they only push particles smaller than the width of the slit beyond the filter element 5. The particles removed from the inner surface of the filter element 5 are lowered by gravity into the sump 18.

When the cleaning elements are executed in the form of spring-loaded strikers attached to the driven shaft 2, the latter strikes with the wound profile 20. As a result, oscillatory processes arise in the form of elastic waves that impart acceleration to the particles stuck above the slot 22, causing them to detach from the filter element 5.

When volley particles are ejected from the formation and the slit is irreversibly contaminated with 22 particles of rock, the safety valve 17 opens, and the formation fluid, bypassing the filter element 5, enters the casing 11 and then goes to receive a submersible pump.

In a borehole self-cleaning filter, the cleaning elements constantly remove trapped particles from the surface of the filter element and, thus, maintain its throughput almost at the initial level for a long time, which increases the service life of the submersible pump installation.

Claims (5)

1. Well self-cleaning filter containing a filter element with an open and closed end, a shaft, a blade on the shaft and cleaning elements associated with the shaft, characterized in that the shaft is made integral and consists of drive and driven shafts connected by a gearbox, driven the shaft with the cleaning elements installed on it is surrounded by a filter element, the lower end of which is open, and the upper end is closed by a cover through which the driven shaft passes, on the drive shaft there is a blade enclosed in a housing with input with openings at the bottom and outlet openings at the top, with O-rings mounted on the housing above the inlet openings and at the lower end of the filter element. 2. Well self-cleaning filter according to claim 1, characterized in that the filter element is equipped with a safety valve. 3. A self-cleaning downhole filter according to claim 1, characterized in that the cleaning elements are made in the form of a rack brush or spring-loaded strikers interacting with the filter element during rotation of the driven shaft. 4. A self-cleaning downhole filter according to claim 1, characterized in that a sludge collector with inlet openings at the top is connected to the lower end of the filter element. 5. Well self-cleaning filter according to claim 1, characterized in that the filter element is made in the form of an all-welded structure of wound and axial prismatic profiles.

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