RU1768231C - Magnetic filter - Google Patents

Abstract

The invention relates to filtering devices for purifying liquids and gases from magnetizable particles, and allows to increase the efficiency of 3-cleaning of the filtered medium, to increase the operating time of the filter before regeneration. Inside the filter housing, magnets of the same pole are mounted on the magnet carrier rod to the same poles to each other, on the end surfaces of which are mounted magnetic disk cores. Additionally, a perforated cylindrical shell of a low coercive force ferromagnetic material is installed coaxially with the filter sleeve. In addition, the perforated shell can be made of magnetically flexible mesh in several layers, and the magnetic cores are made perforated. 6 c.p. 3-yl: & / Gy

Description

The invention relates to filtering devices for purifying liquids and gases from magnetizable particles, in particular for purifying air from a solid component of a welding aerosol,

The aim of the invention is to increase the cleaning efficiency of the filtered medium, increasing the filter operating time before regeneration.

Figure 1 shows a General view of a magnetic filter; in Fig.2 - a fragment with perforated disk magnetic circuits and airtight bushings; in Fig.Z is a fragment with perforated disk magnetic circuits in a plate shape.

The magnetic filter consists of a housing 1 with an inlet pipe, a cover 2 with an output pipe, a filter sleeve 3 and a coaxially mounted perforated shell 4. magnets 5 mounted on a magnet-holder rod 6, disk magnet wires 7 covering magnets 5, a compression spring 8 is installed between the base 9 and the end face of the magnet holder 6. The magnets 5, with disk magnetic circuits located on them 7. are installed with a gap from one another using spacer sleeves 10, and airtight sleeves 11 are installed between the disk agnitoprovodami 7 belonging to each of the magnets 5.

The filter works as follows. The medium to be cleaned is introduced into the filter cavity through the inlet pipe in the housing 1. The passage through the perforated shell 4, part of the magnetized particles, will be deposited on it under the influence of magnetic forces, collected in threadlike aggregates 12 and grow until they are connected to the filter sleeve 3. The remaining particles passing through the perforated shell 4 will settle on the filter sleeve 3 and become coagulation centers, i.e. will be point concentrators of the magnetic field, as a result of which threadlike aggregates 12 will form, the growth of which will cease when they come into contact with the perforated shell 4.

Between the disk magnetic circuits 7, belonging to one magnet 5, there are sections on the surface of the filter sleeve 3, where the magnetic lines of force 13 will be located along the surface of the filter sleeve 3. The settled particles in these sections become magnetic circuits, through which some of the magnetic field energy generated by the ring magnets 5,

To prevent the formation of these magnetic cores from magnetic particles, airtight sleeves 11 are mounted.

In order to reduce the surface where magnetic lines of force are located along the surface of the filter sleeve, the disk-shaped magnetic circuits 7 are mounted with the curved edges inward.

0 Purified gas entering the internal cavity of the filter sleeve 3 through perforation in the magnet holder 6 and bushings 10, perforation of the disk magnetic circuits 7, through the outlet pipe in the cover

5 2 is removed from the filter.

A spring 8 and a base 9 serve to tension the filter sleeve 3.

Filter regeneration is carried out manually by removing cover 2, removing

0 magnet holder 6 with magnets 5 and further cleaning of the sleeve 3 and the shell 4.

After regeneration of the filter, the cleaning efficiency does not decrease, since the surface of the filter cartridge always

5, particles will remain, which will subsequently be magnetic field concentrators and coagulation centers.

The arrangement of magnets with the same poles to each other facilitates the penetration of the magnetic field beyond the filter sleeve to the perforated shell, which is a magnetic field concentrator, which allows a large gradient to be obtained in the particle deposition zone

5 magnetic field and increases the efficiency of particle deposition.

Particles that do not have magnetic properties are held up by a filter sleeve and filamentous aggregates forming a magnetic pile.

The presence of a perforated shell made of a ferromagnetic material with a low coercive force and which is an additional magnetic circuit,

5 facilitates the orientation of the magnetic field in a direction perpendicular to the surface of the filter cartridge and the concentration of the magnetic field in the gap between the cartridge and the sheath,

0 Disk magnetic cores located on the end surfaces of the magnets transmit the magnetic flux from the magnets to the surface of the filter cartridge with minimal losses, and

5 means, create the maximum concentration of the magnetic field in the zone of deposition of particles,

Under the influence of a magnetic field concentrated in the deposition zone, magnetized particles are deposited.

enlarge and turn into filamentary aggregates that are located in the direction of the magnetic field lines, i.e. perpendicular to the surface of the cartridge, which reduces clogging of the filter cartridge and increases the operating time of the filter before regeneration. The growth of filamentous aggregates from captured particles continues until the gap formed between the perforated casing and the filter cartridge is filled.

The growth of filamentous aggregates occurs not only from the surface of the filter cartridge to the perforated shell, but also in the opposite direction, which significantly reduces the hydraulic resistance of the filter.

The implementation of the perforated shell of a material with a low coercive force makes it easy to carry out the regeneration of the filter after removing the magnetic system from the filter housing.

Improving the capture of non-magnetic particles is accomplished by using a filter sleeve from the fabrics of a knitted fabric, such as lavsan.

The perforated shell can be made of magnetically flexible steel mesh in one or several layers, which increases the concentration of the magnetic field in the particle capture zone.

To increase the actively working surface of the filter sleeve, the magnetic wires are made in a plate shape.

In order to completely exclude poorly working deposition surfaces from operation and to reduce magnetic energy losses, an airtight sleeve made of a non-magnetic material and in contact with the inner surface of the filter sleeve is installed between the magnetic circuits belonging to one magnet. In order to improve the passage of the cleaned medium, the magnetic cores may be perforated.

Claims (7)

SUMMARY OF THE INVENTION 1. A magnetic filter comprising a housing with inlet and outlet nozzles, with a magnetic SMS 5 inside of it of ring magnets mounted with a gap from one another on a tubular magnet holder and enclosed in a filter sleeve made of non-magnetic material, aligned with 0 ring magnets, characterized in that, in order to increase the cleaning efficiency of the filtered medium, increase the filter’s operating time. Before regeneration, the magnets are mounted with the same field 5 to each other, equipped with disk magnetic circuits, the diameter of which is equal to the inner diameter of the filter sleeve mounted on end surfaces of the magnets, the filter being provided with 0 perforated cylindrical shell of ferromagnetic material with a low coercive force, mounted coaxially with the magnets and located with a gap between the filter sleeve and the housing. 5 2. The filter according to claim 1, with the exception that the filter sleeve is made of woven fabric material, for example, lavsan. 3. A filter according to claim 1, characterized in that the perforated shell is made of a magnetically flexible steel mesh. 4. The filter according to claims 1 and 3, with the fact that the perforated shell is multilayer. 5 5. The filter according to claim 1, with the fact that the disk magnetic circuits are made in a disk shape. 6. The filter according to claim 1, about t and h and y u and with the fact that it is equipped with airtight 0 a sleeve of non-magnetic material mounted between the disk magnetic circuits of each magnet, the outer diameter of the sleeve being equal to the inner diameter of the filter sleeve. 5 7. The filter according to claim 1, with the exception that the magnetic cores are perforated. Phage 2 fig.Z thirteen