RU172537U1 - Filtering device for cleaning liquids and gases from mechanical impurities - Google Patents

Abstract

The filtering device is designed to purify liquids and gases from mechanical impurities and can be used in chemical, petrochemical and other industries. A filter element is used, obtained from a filter material of a cylindrical shape by deforming it so that the material at the free end is connected tightly in the form of a cross and corrugations are formed on the surface of the filter element. The filter element is mounted on a ring fixed between the flanges of the housing and the supply pipe. A cross-shaped insert is located inside the filter element, and there is a cross-shaped clamp attached to the filter housing on the outside. The design allows the use of flexible materials with a smaller cell size. The technical result is an increase in productivity, a decrease in hydraulic resistance.

Description

The filtering device is designed to purify liquids and gases from mechanical impurities and can be used in chemical, petrochemical and other industries.

Known filters with conical filter elements, which are in some way fixed in the housing. For example, a cone-shaped rod filter according to the patent of the Russian Federation for utility model No. 159842 is known.

Such filters are often installed directly in pipelines. The advantage of conical filters is that they are able to work both on horizontal and vertical sections of pipelines. The fluid flow in such filters shifts trapped mechanical impurities to the top of the cone, the surface is cleaned, and the filter remains operational when a significant amount of sediment accumulates. The disadvantage of conical filters is that the cone has a relatively small filtration surface and a relatively small volume. A small filtration surface reduces performance and increases the filter's hydraulic resistance. The small volume at the top of the cone does not allow a large amount of sediment to accumulate, which reduces the time between cleanings. The small filtration surface limits the possibility of using filter materials with a smaller mesh size. Filter elements for filters operating on horizontal or inclined sections of pipelines must be rigid enough not to lose shape during operation. This also limits the possibility of using soft materials or requires the use of auxiliary devices to give rigidity.

The closest analogue (prototype) of the proposed filtering device is a cone filter according to patent No. 154005. The filter contains a conical filter element mounted on a ring, hermetically fixed between one of the flanges of the housing and the connecting flange of the supply pipe. The filter has the above disadvantages that are inherent in other cone filters.

The objective of the utility model is to create a device with the following technical result: increased productivity, reduced hydraulic resistance.

The claimed technical result is achieved in that in a filtering device for purifying liquids and gases from mechanical impurities, containing a filter element mounted on a ring hermetically fixed between the housing flange and the connecting flange of the supply pipe, according to a utility model, the filter element is obtained by deforming the filter material of a cylindrical shape so that the material at the free end is interconnected hermetically in the form of a cross and on the surface of the filter corrugations are formed on the element. A cross-shaped insert is located inside the filter element at its free end, on which a cross-shaped clip is attached to the filter housing on the outside of the filter element.

The technical result is achieved as follows.

The surface area of the cylinder is two times larger than the surface area of the cone with a generatrix length equal to the height of the cylinder. Therefore, the surface of the filter element obtained by deforming the filter material of a cylindrical shape so that the material at the free end is connected tightly in the form of a cross and corrugations are formed on the surface of the filter element, larger than the surface of a cone of the same height. The volume of the filter element is also significantly larger. Thus, the proposed filter device without changing the overall dimensions will have a large filtration surface and a larger volume. By increasing the filtration surface, an increase in productivity and a decrease in the hydraulic resistance of the filter element are achieved. The relatively large volume of the filter element allows you to accumulate a large amount of sediment in the end part of the filter element, this allows you to increase the time between cleanings. The fact that a cross-shaped insert is located inside the free end of the filter element allows you to "push apart" the end part of the filter element, increase the volume of the end part, increase the amount of accumulated sediment and increase the time between cleanings. The fact that a cross-shaped clamp is installed on the cross-shaped insert outside the filter element allows you to fix the position of the cross-shaped insert in the filter element, to increase the strength and reliability of the connection of the ends of the filter element. The fact that the cross-shaped clamp is attached to the housing allows you to maintain the filter element in a taut state and to ensure the operability of the filter device in horizontal sections of the pipeline when using "soft" filter materials, such as polymer nets or fabrics.

In FIG. 1 shows a longitudinal section through a filter device; in FIG. 2 shows a filter element; in FIG. 3 shows the fastening of the free end of the filter element; in FIG. Figure 4 shows a cross clamp attached to a ring.

The filter device consists of a filter element 1, mounted on a ring 2, hermetically fixed between the flange 3 of the housing 4 and the connecting flange 5 of the supply pipe 6. The filter element 1 is obtained from the filter material of a cylindrical shape by deforming it, and the material at the free end is connected tightly Corrugations 7 are formed in the shape of a cross and on the surface of the filter element 7. A cross-shaped insert 8 is located inside the free end of the filter element 1. A cross-shaped clamp 9 is installed outside the filter element 1 to the same insert. 8 A cross-shaped clamp 9 is attached to the housing 4 by means of a ring 10 fixed in the housing 4.

The filtering device operates as follows. The liquid or gas coming from the pipeline passes through the filter element 1. Mechanical impurities are retained by the filter element 1 and sediment accumulates in the end part of the filter element 1. The fact that the filter element 1 has a larger filtration surface and a larger volume compared to a conical filter element of the same height , allows you to increase filter performance, reduce hydraulic resistance, increase the time between cleanings, as well as use filter materials with a smaller cell. The cross-shaped insert 8, allows you to "push apart" the end part of the filter element 1, increase the volume of the end part, increase the amount of accumulated sediment and, accordingly, increase the time between cleanings. A cross-shaped clamp 9 mounted on a cross-shaped insert 8 outside the filter element 1, allows you to fix the position of the cross-shaped insert 8 in the filter element 1, to increase the strength and reliability of the connection of the ends of the filter element. The fact that the cross-shaped clamp 9 is attached to the housing 4 by means of a ring 10 fixed in the housing 4, allows you to keep the filter element 1 in tension. This allows the manufacture of filter element 1 to use "soft", easily bendable materials.

Claims (4)

1. A filter device for cleaning liquids and gases from mechanical impurities, comprising a filter element mounted on a ring sealed between the housing flange and the connecting flange of the supply pipe, characterized in that the filter element is obtained by deforming the filter material of a cylindrical shape so that the material at the free end it is connected hermetically in the form of a cross and corrugations are formed on the surface of the filter element. 2. The filtering device according to claim 1, characterized in that a cross-shaped insert is located inside the filtering element at its free end. 3. The filtering device according to claim 2, characterized in that a cross-shaped clamp is installed on the cross-shaped insert on the outside of the filtering element. 4. The filtering device according to claim 3, characterized in that the cross-shaped clamp is attached to the filter housing.

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