RU2734972C1 - Filtering element and method of its manufacturing - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: invention relates to machine building, particularly, to filtering elements used in filters for cleaning liquid and gaseous media. Invention relates to a filtering element made in the form of a solid of revolution with a concentric hole and made of a permeable material, which is a pressed metal wire billet, in which end faces are made congruent to each other in form of zigzag-like locks, and to form cylindrical wire workpiece metal sleeve mesh is used. Invention also relates to a method for manufacturing a filter element.

EFFECT: high efficiency of the filter element owing to tightness of its connection with other filter elements and parts.

11 cl, 5 dwg

Description

The invention relates to the field of mechanical engineering, in particular to filter elements used in the composition of filters for purifying liquid and gaseous media.

A well-known filter of a borehole pump containing a cylindrical body made of a segment of a perforated pipe and a filtering system located outside the cylindrical body. The filtering system is made of filtering elements in the form of a tubular element made of a permeable material made of a spiral wire "metal rubber" and is installed on a centralizer, which is located in an annular cavity between the body and the filtering system and the filter is additionally equipped with an adjusting washer. According to an embodiment, the centralizer is made of rings in the form of a tee or an I-beam in cross-section, the rings are installed between adjacent filtering elements with coverage of their ends (according to patent RU89188, class F03D 29/00, publ. 27.11.2009).

The disadvantage of this filter is that the filter elements are interconnected by metal rings in the form of a tee or an I-beam, which does not provide a tight connection between the filter elements, and also reduces the filtration area.

Known wire filter, which contains a filtering part made in the form of a body of revolution and consisting of a wire wound in the form of spirals, stacked in rows, offset relative to each other in the plane of the filter axis and in the plane perpendicular to it, and subjected to pressing with the possibility of forming a multilayer porous structure the filtering part. The filtering part is made in the form of a ring with a cylindrical generatrix. The wire filter is additionally equipped with shells coaxial with the filtering part, covering each of both ends of the filtering part and made in the form of rings with a cylindrical generatrix parallel to the cylindrical generatrix of the filtering part ring, and a U-shaped section in a plane passing along the axis of rotation of the filtering part, open with sides of the ends of the filtering part with the possibility of deepening the latter into the inside of the shell rings. The connection of both shells with the ends of the filtering part recessed in them along the cylindrical surfaces of the junction is made rigid with the formation of a single piece and sealing the ends of the filtering part (according to patent RU2470695, class B01D 39/12, publ. 27.12.2012).

The disadvantage of this filter is that when the filter elements are interconnected, their tight connection is not ensured, since the contact point of the metal shells is not sealed in any way, and the shells also reduce the filtration area.

The closest technical solution is a filter element in the form of a body of revolution, for example, a cylinder with a central hole, made of a wire spiral or spiral sections stretched to a pitch equal to the diameter of the spiral, wound on a technological central rod with crossing at approximately 90 ° in adjacent layers to form spherical, or barrel-shaped, or cylindrical billet subjected to cold pressing. The filter element can be made in the following versions: with flat ends, with one flat end and one conical end made in the form of an internal or external truncated cone with the same cone angle α, with conical ends with the same cone angle α - one made in the form of an internal truncated cone, and others - in the form of an external truncated cone (according to patent RU2553302, class B01D 29/11, B21F 27/18, publ. 10.06.2015).

The disadvantage of this design is insufficient sealing at the junction of the ends of the filter elements between themselves and the filter elements in which they are used. To increase the tightness of the joints, the filter elements are pressed against each other, but the pressing force cannot be too large, since this will increase the filtration fineness and the hydraulic resistance of the filter. Therefore, this method is not effective for sealing the joints of the filter elements. Also, it should be noted that when the filter elements with conical ends are compressed, the filter elements will be deformed in the radial direction.

The technical result to be achieved by the present invention is to increase the efficiency of the filter element by ensuring the tightness of its connection with other filter elements and parts.

The specified technical result is achieved in that the filter element is made in the form of a body of revolution with a concentric hole and is made of a permeable material that is a pressed metal wire blank, and is characterized in that the ends are congruent to each other in the form of zigzag locks.

In addition, the locks can be made with abutting end surfaces, with one lock being made in the form of a cylindrical protrusion, and the other lock in the form of a cylindrical groove.

In addition, the locks can be made with stop end surfaces, with one lock being made in the form of an external cone, and the other lock in the form of an inner cone.

In addition, the stop end surfaces can be perpendicular to the axis of the filter element, made at an angle to the axis and be parallel to each other.

In addition, a metal tubular mesh or a metal spiral wire can be used to form a cylindrical wire blank.

The described filter element is manufactured by a method that consists in pressing a wire blank in a shape that repeats the shape of the filter element, and is characterized in that a metal sleeve mesh is used as a wire blank.

In addition, corrugated metal tubing can be used.

In addition, the diameter of the bag mesh can be less than the diameter of the filter element and larger than the diameter of the hole in it.

In addition, a spiral metal wire can be additionally used to form a cylindrical wire billet, the ratio of wire and metal tubular mesh is not more than 1:10.

For the purposes of this application, the concepts of mesh sleeve, mesh sleeve, mesh sleeve nozzle are assumed to be identical.

The invention is illustrated by the following drawings:

FIG. 1 - filter element with locks in the form of a cylindrical protrusion and groove, longitudinal section;

FIG. 2 - filter element with locks in the form of external and internal cones, longitudinal section;

FIG. 3 - filter element with angled end surfaces, longitudinal section;

FIG. 4 - connection of filter elements between themselves and adjacent parts;

FIG. 5 - filter element, an example of implementation.

The filter element (Fig. 1) is a body of revolution 1 with a concentric hole 2. The ends of the filter element are made in the form of congruent locks 3 and 4. Lock 3 is a cylindrical groove 5 with persistent end surfaces 6 and 7, and lock 4 is a cylindrical protrusion 8 with with stop end surfaces 9 and 10.

FIG. 2 shows a filter element with locks in the form of an internal cone 11 with stop end surfaces 6 and 7 and an external cone 12 with stop end surfaces 9 and 10.

FIG. 3 shows a filter element with stop end surfaces 6 and 9, 7 and 10, made at an angle β ₁ and β ₂ to the axis of the filter element. The angles β ₁ and β ₂ can be equal to each other.

To implement the described connection, it is necessary to accurately measure the filter element locks. The traditionally used methods of manufacturing filter elements from pressed spiral wire, although they allow the proposed filter elements to be manufactured, as practice has shown, do not allow achieving the required accuracy. The required manufacturing precision can be achieved by using a tubular mesh as a wire blank. The mesh is placed in a shape that repeats the shape of the filter element, and pressed with the force necessary to provide the required filtration fineness. It is possible to use a combined wire blank made of both a tubular mesh and a spiral wire. But at the same time, in order to ensure the accuracy of the locks, the ratio of the wire and the metal hose mesh should be no more than 1:10.

Application.

FIG. 4 shows the connection of filter elements 13 and 14 with each other and adjacent parts 15 and 16. Parts 15 and 16 have a lock structure similar to that of locks 3 and 4, respectively. When connected to each other, the outer cone 12 of the lock 4 enters the inner cone 11 of the lock 3, the end surfaces 6, 7 are pressed against the end surfaces 9, 10, respectively.

Making zigzag locks congruent to each other allows to achieve a tight tight connection of filter elements to each other and other parts without deforming them.

Thus, the solutions used in the invention improve the efficiency of the filter element by ensuring the tightness of its connection with other filter elements and parts and ensure the achievement of the technical result.

Claims (11)

1. A filter element made in the form of a body of revolution with a concentric hole and made of a permeable material that is a pressed metal wire blank, and characterized in that the ends are congruent to each other in the form of zigzag locks, and a metal sleeve is used to form a cylindrical wire blank grid. 2. The filter element according to claim 1, characterized in that the locks are made with stop end surfaces, one lock being made in the form of a cylindrical protrusion, and the other lock in the form of a cylindrical groove. 3. The filter element according to claim 1, characterized in that the locks are made with stop end surfaces, one lock is made in the form of an external cone, and the other lock is in the form of an internal cone. 4. The filter element according to claims 2 and 3, characterized in that the stop end surfaces are perpendicular to the axis of the filter element. 5. The filter element according to claims 2 and 3, characterized in that the stop end surfaces are made at an angle to the axis of the filter element. 6. The filter element according to claim 5, characterized in that the abutment end surfaces are parallel to each other. 7. The filter element according to claim 1, characterized in that a spiral metal wire is additionally used to form a cylindrical wire blank, the ratio of the wire to the metal sleeve mesh is not more than 1:10. 8. A method for manufacturing a filter element according to claim 1, comprising pressing a wire blank into a shape that repeats the shape of a filter element, and characterized in that a metal sleeve mesh is used to form a cylindrical wire blank. 9. A manufacturing method according to claim 8, characterized in that a corrugated metal tubular mesh is used. 10. A manufacturing method according to claim 8 or 9, characterized in that the diameter of the bag mesh is less than the diameter of the filter element and greater than the diameter of the hole in it. 11. A manufacturing method according to claim 8 or 9, characterized in that a spiral metal wire is additionally used to form a cylindrical wire billet, the ratio of the wire to the metal tubular mesh is not more than 1:10.

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