RU76966U1 - FILTER SLOT DIAL - Google Patents

Abstract

The utility model relates to the mining industry. The task of creating a utility model is to increase the strength of the filter element, and to reduce the mudding of the well filter. The solution of these problems was achieved in a downhole filter with a filtering element made of rings due to the implementation of at least one groove on the housing. The grooves are made in a spiral. 1 sec п.-кт ф-л, 15 manager subsection, ill. - fifteen

Description

The utility model relates to the mining industry, namely to oil and gas production and can be used in the development of oil and gas wells.

Known downhole filter according to A. St. USSR No. 1645470, containing a perforated pipe on which a wire filter element with protrusions is laid. The protrusions placed quite often on the wire provide a constant gap between the rows.

The disadvantage of the filter is the possibility of deformation of the wire during transportation of the filter or its installation in the well. This can lead to a local increase in the gap between the rows of wire and the passage at the wellhead of large particles of foreign impurities.

Known gravel downhole filter for St. RF for utility model No. 3830, containing a perforated pipe with a sleeve and nipple parts and a filter element in the form of a filter mesh and a protective casing. The mesh size of the filter element is 0.15 ... 0.25 mm.

Disadvantage: the filter is not suitable for the production of viscous oil for two reasons: the small size of the mesh of the filter mesh and the overlap of the filter mesh at the joints on top of each other, which leads to an additional reduction in the cross-section at the location of the layers of the filter mesh.

A well-known filter for water intake, dewatering and hydrogeological wells according to A. St. USSR No. 192125, containing ring elements with supporting platforms, forming radially inlet channels, while the ring elements are bolted together in several places.

The disadvantages of this design are:

- large dimensions and weight of the filter, due to the fact that the outer diameter of the annular elements with this arrangement should be 1.5 ... 2.0 of the diameter of the casing, because on the ring elements, it is necessary to place fixing bolts around the circumference,

- low strength compared to filters in which a perforated pipe is used as a power frame, because the cross section of the pipe, taking into account the perforation, will always be larger than the cross section of several bolts.

- low manufacturing and assembly difficulties due to increased requirements for the exact alignment of bolt holes,

- the possibility of deformation of the filter by filtering elements during descent into directional and horizontal wells due to low rigidity and the absence of a power frame.

In addition, according to filter A. St. USSR No. 192125 is not intended to be used in the oil and gas industry. The impossibility of using such filters in the oil and gas industry is due, first of all, to the large diameter of the filter, and secondly, to its low strength. Thus, this filter has a different purpose.

Known well filter designed for oil or gas according to the patent of the Russian Federation for the invention No. 2254420, a prototype containing mounted on a perforated pipe that acts as a frame, ring elements. Ring elements are installed with gaps acting as filter channels. The description does not indicate by what means the installation of ring elements with gaps between them is achieved. In addition, there is no drainage layer between the perforated pipe and the annular elements, therefore, such a filter will have a low flow rate of the produced product and will quickly become clogged by foreign particles.

The disadvantage of slotted well filters is the low strength and the ability to pass through the filter element of large particles having a non-circular shape, and the disadvantage of mesh filters is the rapid colmatation of the filter element associated with the cross-sectional profile of the wire mesh cell.

The task of creating a utility model: increasing the strength of the filter element, reducing the clogging of the downhole filter and increasing the degree of purification of the produced product from non-circular impurities.

The solution of these problems was achieved in a slotted type filter containing a perforated pipe with nipple and sleeve parts, which concentrically has a filter element made of separate rings, in that at least one groove is made on the outer surface of the pipe, located in a spiral, performing the function of supplying the produced product to the holes of the perforated pipe. The grooves are made intersecting with the right and left direction of the spiral. The grooves are triangular, rectangular, or semicircular. The rings of the filter element are installed between the two stops. One of the stops is made in the form of a threaded ring mounted with the possibility of axial movement on the sleeve fixed motionless on the perforated pipe. The rings of the filter element are made with grooves on the end surfaces, grouped into packages installed between the intermediate rings. The ends of the rings of the filter element are made conical. The grooves on the end surface of the ring are made intersecting. The grooves on the end surface of the ring are made radial.

The grooves are made tangentially. The grooves on the opposite ends of the adjacent rings are made in the opposite direction. The groove profile is rectangular or triangular. The profile of the grooves is made semicircular. The grooves on the rings of the filter elements are made by the method of electrochemical or electroerosive processing, or by etching in an acid solution with the protection of unreversible surfaces. The rings of the filter element are made of stainless steel or plastic.

The proposed technical solution has novelty and industrial applicability, i.e., all the criteria of a utility model.

The novelty of the technical solution is confirmed by patent research. Industrial applicability is due to the fact that non-deficient materials and known technologies are used in the manufacture of the filter.

The essence of the utility model is illustrated in figure 1 ... 15, where:

- figure 1 - shows the filter slotted type-assembled,

- figure 2 - shows a slotted slotted filter with intermediate rings,

- figure 3 is a view of a perforated pipe without a filter element, which shows the grooves located in a spiral,

- figure 4 is a view of a perforated pipe without a filter element, where the grooves are made in the form of a spiral directed in one direction,

- figure 5 is a view of a perforated pipe without a filter element with intersecting grooves having a right and left direction of the spiral,

- figure 6 - shows a view for the first embodiment of the filter element,

- Fig.7 is a view B for the second embodiment of the filter element,

- Fig. 8 is a view of a first embodiment of a filter element ring,

- figure 9 is a view of a second variant of the ring of the filter element,

- figure 10 is a view of a third variant of the ring of the filter element,

- figure 11 is a section bb,

- Fig.12 shows a section bb,

- Fig.13 - also shows a section bb,

- in Fig.14 shows a variant of the rings with grooves 6 made on both sides,

- on Fig - section "GG".

The proposed design of the filter slotted type-setting (figure 1 ... 15) contains a perforated pipe 1 with holes "D", the nipple and coupling parts, respectively 2 and 3, a filter element 4 mounted concentrically perforated pipe 1. On the outer surface of the perforated pipe 1 made at least one groove "E" located in a spiral, which serves as a supply of the produced product to the holes of the perforated pipe 1. The profile of the grooves "E" can be either triangular, or rectangular or semicircular.

The filtering element 4 is made of rings 5 in contact with each other at the ends and having grooves 6 on one or both ends. The rings 5 are sandwiched between the stops 7. One of the stops 7 is made in the form of a threaded ring 8, mounted with the possibility of axial movement on the sleeve 9, fixed motionless on the perforated pipe 1.

With a large length of the filter between the stops 7 can be installed intermediate rings 10, which can be fixed by welding 11 (figure 2). The intermediate rings 10 must have a diameter larger than the diameter of the filter element Df, this will protect the filter element 4 from damage and clogging during transportation. In the holes "D" can be installed shear plugs 12. Grooves "E" can be made in a spiral in one direction (figure 4) or made intersecting with the right and left direction of the spiral (figure 5).

At the ends of the "Zh" of the rings 5, grooves 6 are made having a variable cross section increasing from the outer surface of the filter "I" to its axis O1-O2, i.e. h2> hl (Fig. 6). The ends "G" of the rings 5 can be made conical (Fig.7). The grooves 6 can be made radially (Fig. 8) or tangentially (Fig. 9), or crosswise (Fig. 10).

The grooves 6 at the opposite ends of the adjacent rings 5 can be made in the opposite direction (Fig.14). The thickness of the rings 5 is 1.0 ... 10.0 mm. The outer diameter of the rings 5 of the filter element Df is made less than or equal to the diameter of the coupling Dm, which eliminates the possibility of damage to the filter element 4 during transportation and when lowering into the well.

The profile of the recesses of the grooves 6 can be made triangular (Fig.11) or radius (Fig.12) or rectangular (Fig.13). Rings 5 are made of stainless steel or plastic. For metal rings 5, kanaki 6 can be made by electrochemical or electroerosive treatment. The depth of the grooves h1 determines the degree of filtration of the downhole filter and can be equal to 0.1 ... 1.0 mm. The width of the grooves is approximately equal to their depth.

After installing the downhole filter in the well in plugs 12 (FIGS. 2 and 7), plugs 12 are cut off.

During operation, the produced product containing extraneous impurities passes through the grooves 6 on the rings 5, along the grooves "E" located in a spiral, the produced product spreads along the perforated pipe 1, passes through the holes "D" into the filter. Due to the fact that the size of the grooves 6 of the rings 5 of the filter element 4 is at the inlet of 0.1 ... 1.0 mm, larger particles are filtered out and do not get to the pumping equipment and valves installed at the wellhead, which prevents their premature wear . An increase in the depth of the grooves from the side surface from the axis of the filter reduces the likelihood of clogging.

Particles having a size smaller than the width of the groove 6 pass into it and do not clog, because it expands further downstream. Large particles fall down outside the filter along its outer surface “AND”.

The application of the utility model will allow to obtain a number of advantages in comparison with the previously used well filters, namely:

1. To increase the strength of the filter element

2. To reduce the mud filtering

3. To increase the degree of purification of the produced product from impurities.

4. Provide minimal hydraulic resistance to the passage of viscous oil and thereby increase oil production.

5. Simplify the design of the filter.

6. Provide high technology filter.

7. Reduce filter weight by simplifying the design.

8. Reduce filter manufacturing costs.

9. To reduce the economic costs of well development.

Claims (16)

1. Slit-type slotted filter containing a perforated pipe with nipple and coupling parts, which concentrically has a filter element made of separate rings, characterized in that at least one groove located in a spiral is made on the outer surface of the pipe, which serves as a supply produced product to the holes of the perforated pipe. 2. The filter according to claim 1, characterized in that the grooves are made intersecting with the right and left directions of the spiral. 3. The filter according to claim 1 or 2, characterized in that the grooves are triangular, rectangular or semicircular. 4. The filter according to claim 1 or 2, characterized in that the rings of the filter element are installed between two stops. 5. The filter according to claim 4, characterized in that one of the stops is made in the form of a threaded ring mounted with the possibility of axial movement on a sleeve fixed motionless on a perforated pipe. 6. The filter according to claim 1 or 2, characterized in that the rings of the filter element are made with grooves on the end surfaces, grouped into packages installed between the intermediate rings. 7. The filter according to claim 1 or 2, characterized in that the ends of the rings of the filter element are conical. 8. The filter according to claim 1 or 2, characterized in that the grooves on the end surface of the ring are made intersecting. 9. The type well filter according to claim 1 or 2, characterized in that the grooves on the end surface of the ring are made radial. 10. The filter according to claim 1 or 2, characterized in that the grooves are made tangentially. 11. The filter according to claim 8, characterized in that the grooves on the opposite ends of the adjacent rings are made in the opposite direction. 12. The filter according to claim 1 or 2, characterized in that the groove profile is rectangular or triangular. 13. The filter according to claim 1 or 2, characterized in that the groove profile is made semicircular. 14. The filter according to claim 1 or 2, characterized in that the grooves on the rings of the filter elements are made by electrochemical or electroerosive processing or by etching in an acid solution with the protection of untreated surfaces. 15. The filter according to claim 1 or 2, characterized in that the rings of the filter element are made of stainless steel. 16. The filter according to claim 1 or 2, characterized in that the rings of the filter element are made of plastic.