RU48184U1 - MAGNETIC FILTER DEPOSITOR - Google Patents

Abstract

The problem to be solved is to increase the degree of purification of the processed fluid, i.e. increase in mass of removed particles of pollution. The magnetic filter precipitator contains a housing with a purge pipe and a cover, as well as with inlet and outlet pipes located radially on opposite sides of the housing. The housing has an intermediate sieve bottom and a liner composed of vertically oriented partitions. The insert consists of a longitudinal partition oriented along the axis of the outlet pipe, as well as two pairs of partitions, each of which consists of two partitions located opposite each other and oriented perpendicular to the longitudinal partition. The pairs are located mirrorwise relative to the longitudinal partition. Permanent magnets are fixed on the said partitions, while on the pairs of opposed partitions the magnets are fixed on opposite surfaces opposite each other, and on the longitudinal partition the magnets are located on the side of the outlet pipe on its both surfaces by coaxial pairs. The insert has a vertically oriented plate perpendicular to the longitudinal partition and separating its part with magnets from pairs of opposed partitions. The device differs from the prototype in that neighboring magnets are secured by opposite poles on each partition. The magnets on the longitudinal partition located opposite each other are closed to the partition by opposite poles, and on each pair of opposed partitions the magnets located opposite each other are also oriented to each other by opposite poles.

Description

The invention relates to devices for purifying liquids, in particular water, using a magnetic field. A useful model may find application in the construction of a magnetic sludge trap designed to hold contaminants contained in water in the form of a solid phase and suspensions (magnetic sludge).

As a prototype of the selected magnetic filter precipitator (sludge trap) [Certificate for useful model of the Russian Federation No. 12122, publ. December 16, 1999]. The device has a housing closed by a lid. The housing is equipped with inlet and outlet nozzles located radially along one axis. In the lower part of the casing there is an intermediate sieve bottom, in the bottom part there is a purge pipe. In the internal volume of the casing there is an insert composed of vertically oriented partitions. One of the partitions located near the outlet pipe is longitudinal with respect to the axis of the inlet and outlet pipe. The insert also has two pairs of transverse partitions located near the inlet pipe. These partitions are oriented perpendicular to the longitudinal partition. Each pair consists of two partitions located oppositely to each other, with the pairs being mirrored relative to the longitudinal partitions. Permanent magnets are fixed on the said partitions. On pairs of opposed partitions, the magnets are mounted on opposite surfaces opposite each other, and on the longitudinal partition, the magnets are located on the side of the outlet pipe on its both surfaces by coaxial pairs. The insert also has a vertically oriented partition (plate) without magnets. This plate is perpendicular to the longitudinal partition and separates it from the pairs of transverse partitions. When the processed fluid passes through the filter, the solid particles of the sludge settle on the permanent magnets and create agglomerates, which, when a certain mass is reached, separate and fall to the bottom and are removed through the purge pipe. The main disadvantage of the prototype is the lack of

given orientation of magnets. With arbitrary orientation of the magnets, the filter does not clean efficiently.

The utility model is based on the task of increasing the degree of purification of the processed fluid, i.e. increase in mass of removed particles of pollution.

The problem is solved as follows.

The magnetic filter precipitator contains a housing with a purge pipe and a cover, as well as with inlet and outlet pipes located radially on opposite sides of the housing. The housing has an intermediate sieve bottom and a liner composed of vertically oriented partitions. The insert consists of a longitudinal partition oriented along the axis of the outlet pipe, as well as two pairs of partitions, each of which consists of two partitions located opposite each other and oriented perpendicular to the longitudinal partition. The pairs are located mirrorwise relative to the longitudinal partition. Permanent magnets are fixed on the said partitions, while on the pairs of opposed partitions the magnets are fixed on opposite surfaces opposite each other, and on the longitudinal partition the magnets are located on the side of the outlet pipe on its both surfaces by coaxial pairs. The insert has a vertically oriented plate perpendicular to the longitudinal partition and separating its part with magnets from pairs of opposed partitions. The device differs from the prototype in that neighboring magnets are secured by opposite poles on each partition. The magnets on the longitudinal partition located opposite each other are closed to the partition by opposite poles, and on each pair of opposed partitions the magnets located opposite each other are also oriented to each other by opposite poles.

The utility model is illustrated by the Figures in which: Figure 1 is a longitudinal section through a precipitating filter. Figure 2 - cross section aa, Figure 3 - arrangement of magnets (longitudinal), Figure 4 - arrangement of magnets (transverse).

The magnetic filter-precipitator has a cylindrical housing 1, which is connected to the cover 2 by means of a flange connection. The housing is equipped with an inlet pipe 3 and an outlet pipe 4 for entering and exiting the liquid to be cleaned, as well as a purge pipe 5 for collecting impurities settled on the bottom. The inlet and outlet nozzles are located radially in the upper part of the housing diametrically opposite on the same axis. However, a variant is possible when the nozzles are made at different heights (their axes are parallel) A filter 6 is installed at the inlet of the outlet 4. An intermediate screen bottom 7 is fixed to the bottom of the body. An insert composed of vertically oriented partitions is installed above the screen bottom of the body . The longitudinal partition 8 is oriented along the axis of the outlet pipe (along the common axis of the inlet and outlet pipe). The insert also includes transverse partitions 9. These partitions are two pairs, each of which consists of two partitions located opposite to each other and oriented perpendicular to the longitudinal partition, with the pairs being mirrored relative to the longitudinal partition 8. Partitions 9, located closer to the inlet pipe is connected to the longitudinal partition, and the partitions opposite to them reach the walls of the body, forming part of the labyrinth for the passage of the processed fluid. Permanent magnets 10 are fixed on each partition 8.9 — one vertical row on the partition. The distance between adjacent magnets in the row is the same and neighboring magnets are fixed on the partition by opposite poles. At the same time, on pairs of opposed partitions 9, magnets 10 are mounted on opposite surfaces opposite each other. On the longitudinal partition 8, the magnets 10 are located on the side of the outlet pipe on its both surfaces in coaxial pairs, i.e. magnets on opposite sides of the partition are fixed in pairs at the same height. Coaxial magnets (located at the same level) on the longitudinal partition 8 are closed to the partition by opposite poles, and on each pair of opposed partitions 9 the magnets located opposite each other are also oriented to each other by opposite poles. The liner has

also another transverse partition without magnets. This is a vertically oriented plate 11, perpendicular to the longitudinal partition 8 and separating its part with magnets from pairs of transverse partitions. Thus, partitions 8, 9 and plate 11 form a labyrinth for the passage of the processed fluid.

The device operates as follows. When liquid enters the labyrinth channels between the partitions of the body, it decelerates. Part of the suspended particles when damping speed under the influence of gravity settle on the intermediate sieve bottom 7 or sink to the bottom of the housing. Smaller particles with paramagnetic properties are magnetized by fields of permanent magnets, settle on their surface and create agglomerates, which, due to mass growth, periodically separate from the magnets and fall to the bottom. The design of the labyrinth channels and the organization of magnetic fields described above can increase the degree of purification of the processed fluid, i.e. increase the mass of removed particles of pollution by 5-10%.

The exhaust pipe is additionally protected by a mesh filter 6 with a developed active surface, which is able to capture non-magnetic particles of contamination.

Claims (1)

A magnetic filter precipitator, comprising a housing closed by a lid, having a purge pipe in the bottom part, and also in the upper part of the inlet and outlet pipes located radially on opposite sides of the housing, in the housing there is an intermediate screen plate and an insert composed of vertically oriented partitions, among of which a longitudinal partition oriented along the axis of the outlet pipe, as well as two pairs of partitions located on the side of the inlet pipe, each of the pairs consists of two partitions, p arranged opposite to each other and oriented perpendicular to the longitudinal partition, the pairs are mirrored relative to the longitudinal partition, permanent magnets are fixed on the said partitions, while the magnets are mounted on opposite pairs of opposed partitions on opposite surfaces, and the magnets are located on the longitudinal partition from the side of the outlet pipe on its both surfaces with coaxial pairs, the liner also has a vertically oriented face y, perpendicular to the longitudinal partition and separating the part of the longitudinal partition on which the magnets are mounted from pairs of opposed partitions, characterized in that adjacent magnets are secured by opposite poles on each partition, coaxial magnets on the longitudinal partition are closed by opposite poles, and on each pair oppositely placed baffles magnets located opposite each other are oriented to each other by opposite poles as well.