RU78261U1 - WELL FILTER PROTECTIVE CASING (OPTIONS) - Google Patents

Abstract

The utility model relates to the oil and gas industry and can be used in well filters for the extraction of liquids and gases from the bowels of the earth.

The task of creating a useful model is to prevent rock from entering the filter element when the downhole filter device is lowered into the well.

The solution of these problems was achieved in the first version of the protective casing of the downhole filter, made of a metal sheet with holes in it, in that the metal sheet is made along the axis of the casing of the notch, and the sheet elements are drawn near the notches into the casing with the formation of tangential holes. Perforations can be made in pairs, and tangential holes - through.

The solution of these problems was achieved in the second version of the protective casing of the downhole filter, made of a metal sheet with perforations in it, characterized in that the openings contain folding elements made with the possibility of preventing rock from getting inside when the downhole filter is lowered into the well. The holes are round, rectangular or triangular in shape. Folding elements are made along the entire perimeter of the holes, or not along the entire perimeter of the holes. The folding elements are bent and oriented along the axis or perpendicular to the axis of the protective casing.

The solution of these problems was achieved in the third version of the protective casing of the downhole filter, made of a metal sheet with holes in it, characterized in that the metal sheet has recesses and radial holes are made in them. The recesses are directed inward towards the axis of the casing or outward from the axis of the casing. The recesses are round or rectangular. The holes are round or rectangular.

3 sec P.-that f-ly, 14 head. subsection, ill. fourteen.

Description

The utility model relates to the oil and gas industry and can be used in the extraction of liquids and gases from the bowels of the casing or production string.

Known downhole filter, which is a steel pipe with holes on which a profiled wire is wound (Gavrilko V.M. Filters for boreholes. M., "Nedra", 1985, p.7-9).

The main disadvantage of this design is the change in the inter-turn gaps when installing the filter in the well, the lack of protection of the filter mesh from mechanical stress during transportation and installation of the filter, which negatively affects the quality of filtration.

Known downhole filter, consisting of a supporting tubular perforated frame and a fibrous filter coating made in the form of individual plates of wire non-woven material, rigidly lapped by welding and soldering on a tubular frame of the filter against perforations (ed. USSR Certificate No. 941548, MKI 3 ЕВВ 43/08, publ. 1982).

The main disadvantage of this design is the presence of welded zones, which over time activates the processes of metal corrosion. The snug fit of the filter element to the perforated pipe significantly reduces the filtration zone, which is limited by the area of the hole in the pipe. There is no protection of the filter element from mechanical influences during transportation and installation of the filter.

Known downhole filter device according to St. RF for utility model No. 16758, prototype. This downhole filter device comprises a perforated pipe, a sleeve and a nipple, a filter device protected by a protective casing with round holes and a drainage layer located between the filter element by the pipe. The protective cover prevents damage to the filter element when it is lowered into the well.

The disadvantages of this filter are the low throughput of the filter, due to the fact that the area of the holes in the protective casing is small. Increasing the diameter of the holes and their number will lead to a greater likelihood of damage to the filter element or getting into the rocks when it is lowered into the well, as well as to weaken the protective casing.

Known downhole filter according to the patent for utility model No. 66416, prototype. This casing is made of steel sheet with holes.

The disadvantage is the possibility of rock entering the filter element when the downhole filter is lowered into the well.

Objectives of creating a utility model: increasing the filter capacity while preventing rock from entering the filter element when lowering the filter device into the well.

The solution of these problems was achieved in the first version of the protective casing of the downhole filter made of a metal sheet with holes in it, in that the metal sheet is made along the axis of the casing of the notch, and the sheet elements are drawn near the notches with the formation of tangential holes. Perforations can be made in pairs, and holes - through.

The solution of these problems was achieved in the second version of the protective casing of the downhole filter, made of a metal sheet with holes in it, due to the fact that the grooves are made in the metal sheet and the holes are made in them. The recesses are directed inward towards the axis of the casing or outward from the axis of the casing. The recesses are round or rectangular. The holes are round or rectangular.

The solution of these problems was achieved in the third version of the protective casing of the downhole filter, made of a metal sheet with perforations in it, due to the fact that the openings contain folding elements that are designed to prevent rock from getting inside when the downhole filter is lowered into the well. The holes are round, rectangular or triangular in shape. Folding elements are made along the entire perimeter of the holes, or not along the entire perimeter of the holes. The folding elements are bent and oriented along the axis or perpendicular to the axis of the protective casing.

The essence of the utility model is illustrated in the drawings of figures 1 ... 14:

- figure 1 presents the downhole filter,

- figure 2 shows the protective casing of the downhole filter with tangential holes of a rectangular shape,

- figure 3 shows a fragment of the casing with through tangential holes,

- figure 4 shows a view for the first embodiment,

- figure 5 shows a fragment of the casing with through holes tangential holes,

- figure 6 and 7 presents a second variant of the protective casing,

- Fig.8 shows a fragment of the casing for the third option with rectangular holes,

- figure 9 presents a fragment of the casing with holes of a triangular shape,

- figure 10 shows a fragment of the casing with rectangular holes and flanging around the perimeter,

- figure 11 presents a fragment of the casing with holes of a triangular shape and flanging around the perimeter,

- Fig.12 shows a fragment of the casing with a folding element, made not along the entire perimeter of the hole, parallel to the axis of the filter,

- Fig.13 shows a fragment of the casing with a folding element, made not along the entire perimeter of the hole, perpendicular to the axis of the filter,

- on Fig presents a fragment of the casing with a folding element, made not around the entire perimeter of the hole, parallel and perpendicular to the axis of the filter.

Well filter (figure 1) contains a perforated pipe 1 with holes "B" and the filter element 2.

The filter element 2 is mounted on the perforated pipe 1 concentrically to it. The filter element 2 can be of any design: mesh, slotted, typesetting, ceramic, gravel, as well as combined in any combination.

A protective casing 3 with holes “B” and folding elements 4 is installed outside. The protective casing 3 is made of a cylindrical shape from a metal sheet, for example, steel or aluminum.

The first variant of the protective casing (Fig. 2 ... 5) contains longitudinal grooves “G”, and the folding elements 4 between the pairs of grooves “G” are elongated inward (stamping) and through holes “B” are formed (Fig. 3 and four). If the grooves "G" are made unpaired (Fig. 5), then through holes "B" are formed. In the particular case of the hole "B" can be performed tangentially.

According to the second variant of the protective casing of the downhole filter (Fig.6 and 7), it contains stamping 5, on which holes "B" are made. Vyshtampovki 5 are directed inward towards the axis of the filter. Vyshtampovki 5 can be of any other shape: rectangular - Fig.6 or round - Fig.7, and also have holes "In" rectangular, round or any other shape.

According to the third variant (Fig. 8 ... 14) on the casing 3, folding elements (flanges) 4 are made, directed inwardly to the casing 3 or outward. The holes "B" can be of any shape, for example, rectangular - Fig.8, 10, 12 and 13, triangular (Fig.9 and 11) or complex shape (Fig.14).

Holes "B" can be made with bends 4 made along the entire perimeter (Fig.10 and 11) or not around the perimeter of the holes (Fig.12 ... 14). In this case, the folding elements 4 can be placed parallel to the axis of the filter (Fig. 12), or perpendicularly (Fig. 13) or simultaneously perpendicularly and in parallel (Fig. 14). The folding elements 4 are designed to prevent the ingress of rock during the descent of the downhole filter into the well.

The folding elements 4 can be bent both inward and outward from the surface of the protective casing. Bent inward towards the perforated pipe 1 to a height of "H" folding elements 4 form a drainage layer "D" (figure 1) with a strictly regulated thickness.

Well filter with a protective casing 3 (Fig.1 ... 14) works as follows.

Through holes "B" in the protective casing 3, the liquid (water or oil) enters the filtration.

The protective casing 3 prevents the ingress of large mechanical impurities on the surface of the filter element, protecting it from deformation and damage during installation and transportation and providing a significantly longer filter life.

The protective casing 3 can be made of stainless steel with a thickness of from 0.6 to 1.2 mm. The size of the cells in the perforated sheet (casing) is determined based on the operating conditions of the filter (particle size distribution of the soil).

The protective casing 3 of the expanded metal sheet has a mesh size of 3-60 mm, and the total area of the openings of the protective screen is at least 30% of the total area of the protective casing 3.

Due to the large area of holes "B" of the protective casing 3, free flow of liquid to the filter element with a low resistance coefficient is ensured.

When lowering the filter into the well, the bent folding elements 4 are directed downward (Fig. 1), therefore, the rock does not fall into the filter element 2 and it is not clogged by the rock.

Between the protective casing 3 and the filter element 2, a drainage layer “D” is formed by using folding elements 4 or recesses 5 having a bending height H, bent inward towards the perforated pipe 1. The drainage layer “G” allows more evenly distributed product flows along pipe 1 and increase the throughput of the downhole filter.

Application of the utility model allowed:

1. Create a filter that has a large throughput and has good filtering and operational properties through the use of slotted holes with a large area and the effective use of a drainage layer that is formed automatically when the well filter is assembled.

2. To prevent clogging of the filter when it is lowered into the well.

3. To prevent damage to the filter element during transportation of downhole filters.

4. Simplify the design of the filter.

5. Reduce the cost of the filter.

6. Automate and mechanize filter production.

7. Ensure long-term operation of the filter without clogging.

The well filter of the proposed design has passed bench and industrial tests and has shown high filtering ability and reliability in operation.

Claims (17)

1. The protective casing of the downhole filter, made of a metal sheet with holes in it, characterized in that the metal sheet is made of grooves and the elements of the sheet are drawn near the grooves with the formation of holes. 2. The protective casing according to claim 1, characterized in that the notches are made in pairs, and the holes are through. 3. The protective casing of the downhole filter, made of a metal sheet with holes in it, characterized in that the metal in the metal sheet is plastically deformed to form depressions, and radial holes are made in them. 4. The protective casing according to claim 3, characterized in that the recesses are directed inward towards the axis of the casing. 5. The protective casing according to claim 3, characterized in that the recesses are directed outward from the axis of the casing. 6. The protective casing according to claim 4 or 5, characterized in that the recesses are round. 7. The protective casing according to claim 4 or 5, characterized in that the recesses are made in a rectangular shape. 8. The protective casing according to claim 4 or 5, characterized in that the holes are made round. 9. The protective casing according to claim 4 or 5, characterized in that the holes are made in a rectangular shape. 10. The protective casing of the downhole filter, made of a metal sheet with a hole in it, characterized in that the openings contain folding elements configured to prevent rock from getting inside when the downhole filter is lowered into the well. 11. The protective casing of claim 10, characterized in that the holes are made round. 12. The protective casing of claim 10, wherein the holes are made in a rectangular shape. 13. The protective casing of claim 10, wherein the holes are triangular. 14. The protective casing according to any one of paragraphs.10-13, characterized in that the folding elements are made around the perimeter of the holes. 15. A protective casing according to any one of paragraphs.10-13, characterized in that the folding elements are not made around the perimeter of the holes. 16. The protective casing according to PP.10-13, characterized in that the folding elements are bent and oriented along the axis of the protective casing. 17. The protective casing according to PP.10-13, characterized in that the folding elements are bent and oriented perpendicular to the axis of the protective casing.