RU204611U1 - SLOT FILTER - Google Patents

Abstract

The utility model relates to the oil and gas industry and can be used in the operation of oil and oil and gas condensate fields, complicated by increased removal from the developed productive horizons together with the produced hydrocarbons and formation water of sand and other mechanical impurities. In a slotted filter containing a perforated pipe with through holes, covered by a filter block, the filter block consists of filter elements mounted concentrically to a perforated pipe, made in the form of a cylindrical spiral made of a high-precision V-shaped profile, creating a rigid screen with annular slots 50 μm in size and more, with a gap width tolerance of up to 15 μm, fixed with by welding on supporting elements, with the outer filtering surface with varying degrees of filtration, and each subsequent filtering element from the outer to the inner has a decreasing gap between the turns of the cylindrical spiral, which allows retention place larger particles in the outer layers, and smaller ones in the inner layers. 7 p.p. f-ly.

Description

The utility model relates to the oil and gas production industry and can be used in the operation of oil and oil and gas condensate fields, complicated by an increased removal from the developed productive horizons together with the produced hydrocarbons and formation water of sand and other mechanical impurities.

In the art, there are many types of filter devices configured to prevent sand and other solid particles from entering fluids from oil, gas, water wells.

Known slotted filter containing a pipe, the filter section of which has perforations in the form of holes, the filter element is installed concentrically to the pipe between the fixed lower support element in the form of a glass and a movable double-sided stop in the annular gaps between the outer diameter of the pipe and the inner diameters of the lower support element and the movable double-sided stop, supported on the annular platform of each, and between the movable double-sided stop and the upper movable stop in the annular gaps between the outer diameter of the pipe and the inner diameters of the stops, supported on the annular platform of each, a spring is installed, the initial force of which exceeds the elastic deformation of the spring of the filter element, which provides tight fit of the wire turns of the filter element.

RF patent No. 2445146, IPC B01D 29/48, published 03/20/2012.

Known is a slotted filter with a wire filter element containing a perforated pipe with nipple and coupling parts, concentrically of which the filter element is made of spiral wound wire connected to longitudinal wire stringers, the wire in the spiral is laid turn to turn, and at least on one of of the contacting sides of the wire, a notch is made, which provides a filtering gap, while the notch on the wire is tangential or intersecting. The notch profile can be rectangular, triangular or semicircular. The wire of the filter element is made of stainless steel (RF Patent No. 2378494, IPC E21B 43/08, published on 10.01.2010).

Known filter containing concentrically located outer, intermediate and inner pipes. The last two are provided with holes and are connected to each other by a pipe in the upper part. The outer pipe at both ends is connected to the intermediate pipe with annular plugs. The inner pipe is equipped with a filter element located in the interval of holes made on this pipe, equipped with a bell and connected to it by longitudinal ribs. The bell is located with a gap relative to the intermediate pipe and is equipped with a centralizer and a nozzle in the lower part. In the annular gap between the inner and intermediate pipes, a filter element is placed coaxially with them, made in the form of an inverse truncated cone and attached to these pipes above the upper holes made in them. The middle holes of the intermediate pipe are made opposite the bell and are equipped with a filter element [RF Patent No. 2305756, IPC E21B 43/08, publ. 2007.09.10].

Known is a downhole filter containing a tubular frame, external and internal slotted filter elements, concentrically mounted on the tubular frame with the formation of vertical channels, a sump connected to vertical channels, a pipe connected to the pump intake, according to the invention, slotted filter elements are formed from longitudinal prismatic rods and of the wound prismatic profile connected to them, placed outside and inside the tubular frame supported on longitudinal rods, forming external and internal vertical channels between the longitudinal rods and the tubular frame and a central cylindrical cavity in the internal slotted filter element, and the external vertical channels are hermetically closed from above and connected with a sump in the lower part, and the internal vertical channels are hermetically closed at the bottom and connected at the top with the branch pipe, the central cylindrical cavity is separated from the branch pipe by a valve and connected to the sump.

RF patent No. 2446274, IPC E 21 B 43/08 published on 27.03.2012

The disadvantage of these designs is the low permeability of the slotted holes, as a result of which there is a rapid clogging of the passage holes with particles of sand and gravel, which leads to a rapid failure of pumping equipment and the formation of a large amount of solid oily waste and reduces the productivity of the well.

The task of the utility model is to increase the efficiency of cleaning the extracted products from mechanical impurities.

This problem is solved due to the fact that in a slotted filter containing a perforated pipe with through holes, covered by a filter block, the filter block consists of filter elements installed concentrically to the perforated pipe, made in the form of a cylindrical spiral from a high-precision V-shaped profile, creating a rigid screen with annular slots of 50 microns and more, with a slit width tolerance of up to 15 microns, fixed by welding on supporting elements, with an outer filtering surface with varying degrees of filtration, and each subsequent filtering element from outer to inner has a decreasing gap between the turns cylindrical spiral, which allows you to retain larger particles in the outer layers, and smaller ones in the inner ones.

In addition, the through holes can be located along the perforated pipe.

In addition, the through holes can be located across the perforated pipe.

In addition, on the perforated pipe, the through holes can be staggered.

In addition, on the perforated pipe, the through holes can be arranged in a spiral.

In addition, the diameter of the through holes of a perforated pipe can be selected the same for all pipe sections.

In addition, the diameter of the through holes in different sections of the perforated pipe may not be the same.

In addition, the inner surface of the filter elements can be pre-treated with paraffin.

The utility model is illustrated by figures.

FIG. 1 is a general view of a slotted filter.

FIG. 2 - section А-А - arrangement of filter elements

FIG. 3-view B, the location of the slotted holes of the filter elements.

FIG. 4 - accumulation of sediments on the filter element

FIG. 5 - the inner surface of the filter element pretreated with paraffin

The slotted filter consists of a perforated pipe 1 with through holes 2, the diameter and distribution of which along the pipe is carried out according to the developed mathematical program, covered by the filter block 3, consisting of two or more filter elements installed concentrically to the pipe, for example, outer 4 and inner 5, having cylindrical shape, made in the form of a cylindrical spiral from a high-precision V-shaped profile, creating a rigid screen with annular slots of 50 microns or more, with a gap width tolerance of up to 15 microns, fixed by welding on supporting elements of a certain section, with an outer surface filtration with varying degrees of filtration, and each subsequent filter element from the outer to the inner has a decreasing gap between the turns of the cylindrical spiral, which makes it possible to retain larger particles in the outer layers, and smaller ones in the inner ones.

Using the example of two filter elements included in the filter design, we will consider its feature.

The size of the gap A between the turns of the cylindrical spiral of the outer filtering element is greater than the size of the gap B between the turns of the cylindrical spiral of the inner filtering element

Through holes 2 can be located along and across the perforated pipe, staggered or spiral.

Through holes 2 can be calibrated with increased accuracy and high surface finish.

The diameter of the through holes 2 of the pipe can be chosen the same for all sections of the perforated pipe, while the total area of the holes must correspond to the calculated data obtained for each section of the perforated pipe 1.

In different sections of pipe 1, the diameter of the perforated through holes may be different, while the total area of the holes must correspond to the calculated data obtained for each section.

The inner surface of the filter elements can be pretreated with paraffin 6, which reduces the risk of "smearing" the working (outer) surfaces of the filter elements with the residues of drilling fluids when installing a slotted filter.

The principle of operation of a slotted filter is as follows.

Let's consider an example of using two filter elements.

The slotted screen is installed in the well inside the casing.

The inner surface of the filter elements can be pretreated with paraffin 6, which reduces the risk of "smearing" the working (outer) surfaces of the filter elements with the residues of drilling fluids when installing a slotted filter.

The liquid in the well is sucked through the slotted grid of the filtering element 4, is cleaned of mechanical impurities, the dimensions of which are larger than or comparable to the size of the slot of the filtering element 4, and falls into the annular gap between the filtering element 4 and the filtering element 5. Since this gap is much smaller than the previous one , the fluid flow rate increases here. Then, the process of additional purification of the liquid is carried out due to the reduced gap between the turns of the cylindrical spiral of the internal filter element, which makes it possible to retain smaller particles.

Then the purified liquid enters the inner cavity of the perforated pipe and then rises to the surface.

For a particular field, depending on the characteristic fractional composition of the formation sand, as well as the requirements for cleaning the formation fluid, the filter can contain two or three filter layers.

As the well is in operation and the filter is in operation, the arch created in front of the outer filtering layer of coarse sand grains removed from the reservoir itself begins to work as a natural filter, preventing the movement of smaller sand fractions through it. In this case, the volume of the natural filter increases due to the involvement of deep layers of the bottomhole zone in the filtration process. Gradually, the movement of particles slows down and then stops. This strengthens the initially loose productive layer, increases its rock-holding capacity and prevents its destruction. Reducing sand production extends the service life of not only the well filter, but also all underground equipment, thus increasing the turnaround time of wells and the efficiency of the formation fluid withdrawal. The use of these filters is especially advisable at the secondary stages of field development.

Claims (8)

1. A slotted filter containing a perforated pipe with through holes, covered by a filter block, characterized in that the filter block consists of filter elements installed concentrically to the perforated pipe, made in the form of a cylindrical spiral from a high-precision V-shaped profile, creating a rigid screen with annular slits with a size of 50 microns and more, with a slit width tolerance of up to 15 microns, fixed by welding on supporting elements, with an outer filtering surface with varying degrees of filtration, and each subsequent filter element from outer to inner has a decreasing gap between the turns of the cylindrical spiral, which allows you to retain larger particles in the outer layers, and smaller ones in the inner ones. 2. A slotted filter according to claim 1, characterized in that the through holes can be located along the perforated pipe. 3. A slotted filter according to claim 1, characterized in that the through holes can be located across the perforated pipe. 4. A slotted filter according to claim 1, characterized in that the through holes on the perforated pipe can be staggered. 5. A slotted filter according to claim 1, characterized in that the through holes on the perforated pipe can be arranged in a spiral. 6. A slotted filter according to claim 1, characterized in that the diameter of the through holes of the perforated pipe can be selected the same for all sections of the pipe. 7. A slotted filter according to claim 1, characterized in that the diameter of the through holes in different sections of the perforated pipe may not be the same. 8. A slotted filter according to claim 1, characterized in that the inner surface of the filter elements can be pre-treated with paraffin.

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